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i EFFECTS OF HEAT TREATMENT AND ALLOYING ELEMENTS ON CHARACTERISTICS OF AUSTEMPERED DUCTILE IRON Submitted By:
ii MUHAMMAD ASHRAF SHEIKH 2001-PhD-Met-02 Department of Metallurgical and Materials Engineering UNIVERSITY OF ENGINEERING AND TECHNOLOGY LAHORE – PAKISTAN 2008
iii EFFECTS OF HEAT TREATMENT AND ALLOYING ELEMENTS ON CHARACTERISTICS OF AUSTEMPERED DUCTILE IRON A thesis submitted to the University of Engineering and Technology, Lahore as a partial fulfillment for the degree of Doctor of Philosophy in Metallurgical and Materials Engineering Approved on ___12-01-2008____ Internal Examiner: Signature: _______________________ (Supervisor) Name: Professor Dr Javed Iqbal External Examiner: Signature:________________________ Name: Professor Dr M. Saleem Shuja Rector, University of Lahore. Chairman of the Department: Signature: ________________________ Name: Prof. Qasim Hassan Zaidi Dean - Faculty of Chemical Signature: ________________________ Min. & Met. Engg. Name: Prof. Dr. Faiz ul Hasan Department of Metallurgical and Materials Engineering UNIVERSITY OF ENGINEERING AND TECHNOLOGY
iv LAHORE-PAKISTAN 2008
v This thesis was evaluated by the following Examiners: External Examiners: From Abroad: Dr. Ramin Raiszadeh, Metallurgy Department, Engineering School, Shahid Bahonar University Of Kerman Kerman, Iran. Dr. Derya Dispinar, Metallurgy and Materials Engineering, University of Istanbul, Turkey From Pakistan: Professor Dr. M. Saleem Shuja Rector, University of Lahore. Internal Examiner: Professor Dr Javed Iqbal Department Metallurgical and Materials Engineering. University of Engineering and Technology, Lahore.
vi “Glory to You: of knowledge we have none, save what You have taught us; in truth it is You Who are perfect in knowledge and wisdom.” (Al-Quran 2:32)
vii Dedication to my mother, my wife and children
viii ACKNOWLEDGEMENTS I am highly grateful to my supervisor, Professor Dr. Javed Iqbal for his guidance, encouragement and supervision given throughout this work. I feel great obligation to Professor Dr. John Campbell, Head IRC Department and Dr. T. U. Din, Research Associate University of Birmingham, UK for giving me permission to do my experimental work in the department, for their co-operation and valuable guidance. My special thanks to Lt. General (R) Muhammad Akram Khan, the Vice Chancellor, University of Engineering and Technology, Lahore, for his continued support and encouragement throughout this research work. I also wish to acknowledge the financial support of the Higher Education Commission, Islamabad. I am also grateful to the Director General Research, Dr. K. E. Durrani, Dean, Professor Dr. Faiz ul Hasan, Chairman, Prof. Qasim Hassan Zaidi, Director Post Graduate Studies, Prof. Dr. M. Ajmal Chishti for their help and cooperation during my research work. I would like to acknowledge the support of Mr. Munir Ahmad, M.D. and Mr. Izhar Ahmad of Pakistan Standards and Quality Control Authority, Lahore, Dr. Shahzad Alam and Mr. Junaid of PCSIR Laboratories, Lahore and Mr. M. Sadiq Qureshi of Flames International for helping me in testing of the samples. My sincere thanks and appreciation are also due to M/S ADI Treatments, U.K. for the heat treatment of some of the samples. I would like to thank Mr. Adrian and Mr. Michael of Casting Research Group, University of Birmingham , UK and Mr. Rashid Ahmad of Star Agro Engineering & Foundry, Lahore; for making the melts and Mr. Furqan Ahmad & Mr. Asif Rafiq of University of Engineering & Technology, Lahore for their help in metallography. I would like to acknowledge the assistance of Mr. Muhammad Saeed, Mr. Manzoor Ahmad and Mrs Azra Haroon of University of Engineering & Technology, Lahore. I wish to thank all my colleagues and staff of various laboratories for their help specially Mr. Shahzad Ali and Mr. Abdul Qayyum for their assistance. Finally I take this opportunity to express my gratitude to my family, specially my wife for her encouragement and support. M. ASHRAF SHEIKH
ix ABSTRACT The effect of three variables on ductile iron has been investigated in this study. The first variable was the effect of austempering time on ductile iron. The second variable was the effect of austenitizing temperature and the third major variable was the effect of alloying additions on ductile iron. The alloying elements selected for this purpose were copper, nickel, a combination of copper and nickel and lanthanum. The initial study was conducted on unalloyed ductile iron castings. The effect of austempering time was examined by varying austempering time in the range of 30 minutes to 90 minutes, while keeping austenitization temperature and austempering temperature constant. It was found that with the increase of austempering time, the tensile strength increased significantly. However, at 90 minutes the tensile strength decreased. The optimum temperature was found to be 60 minutes. The second variable was the effect of austenitization temperature on ductile iron. Based on the result of the first experiment, the austempering was carried out for 90 minutes. The austempering temperatures were kept at 270 o C and 370 o C. The austenitization temperature was varied from 850 o C to 925 o C. The study revealed that tensile strength increased at 900 o C but it decreased at 925o C. The third major variable involving the effect of alloying additions on ductile iron, was studied by adding copper with three different values i.e. 0.5 wt. %, 1.0 wt. % and 1.5 wt. %. The fourth melt was without the addition of copper. It was found that with the increase of copper the tensile strength continued to increase up to 1.5 wt. %. The second alloying addition was nickel. One melt was made without nickel while the remaining three melts were made with the addition of 1.0 wt. %, 2.0 wt. % and 3.0%
x nickel. The tensile strength increased correspondingly with the increase in the addition of nickel to 3.0 wt. %. The effect of a combination of copper and nickel on ductile iron was also examined. The effect of the last alloying element which was studied was lanthanum. Four melts were made for this study. The first melt was without the addition of lanthanum while the remaining three had 0.006 wt.%, 0.02 wt.% and 0.03 wt.% lanthanum. The results indicated that the tensile strength increased with the increase of lanthanum content with and without austempering. Furthermore, the highest nodule count was obtained with 0.03 wt.% lanthanum while the nodularity remained almost unchanged. Thus, it was observed that the addition of alloying elements results in an increase of tensile strength. The optimum austempering time was 90 minutes and the optimum austenitizing temperature was found to be 900 o C.
xi TABLE OF CONTENTS Description Page Acknowledgement Abstract Table of Contents List of tables List of figures Chapter–1 INTRODUCTION 1 Chapter–2 LITERATURE REVIEW 2 2.1 Ductile Iron 4 2.1.1 History of Ductile Iron 4 2.1.2 Production of Ductile Iron 5 2.1.2.1 Raw Materials 5 2.1.2.2 Control of the Composition of Ductile Iron 5 2.1.2.3 Charge Materials 8 2.1.2.4 Desulphurization 9 2.1.2.5 Spheroidizing Treatment Alloys 10 2.1.2.6 Melting Techniques for the Production of Ductile Iron 10 2.1.2.7 Spheroidizing Treatment 11 2.1.2.8 Amount of Magnesium Required 13 2.1.2.9 Inoculation 15 2.1.3 Formation of Carbides in Ductile Iron 17 2.1.4 Pouring 18 2.1.5 Importance of Ductile Iron 18 2.2 Austempered Ductile Iron (ADI) 20 2.2.1 Austempering 20 2.2.2 Introduction to Austempered Ductile Iron 20
xii 2.2.3 Production of Austempered Ductile Iron 21 2.2.3.1 Composition of ADI 22 2.2.3.2 Effects of Alloying Elements 22 2.2.3.3 Production of Austempered Ductile Iron 27 2.2.3.4 Heat Treatment Considerations 29 2.2.4 Specifications of Austempered Ductile Iron 30 2.2.5 Cost Benefits of Austempered Ductile Iron 31 2.2.6 Properties Of Austempered Ductile Iron 32 2.2.7 Disadvantages of Austempered Ductile Iron 33 2.2.8 Application of Austempered Ductile Iron 33 Chapter–3 EXPERIMENTAL WORK 36 Research Methodology 36 3.1 Production of Ductile Iron 39 3.1.1 Ductile Iron without and with Copper, Nickel and Copper-Nickel Together 39 3.1.2 Ductile Iron Prepared without Lanthanum 42 3.1.3 Ductile Iron Produced with Lanthanum 42 3.1.4 Moulding Method 44 3.1.5 Melting Technique 45 3.1.6 Spheroidizing Treatment 45 3.1.7 Inoculant 45 3.1.8 Chemical Analysis 46 3.1.9 Filtration of Ductile Iron 47 3.2 Microstructure 47 3.3 Salts Used 47 3.4 Equipments Used 48 3.4.1 Melting Furnaces 48 3.4.2 Heat Treatment Furnaces 48 3.4.3 Microscopes Used 49 3.4.4 Tensile Testing Machines 50
xiii Chapter – 4 RESULTS AND DISCUSSION 51 4.1 Effect of Austempering Time on Ductile Iron 51 4.2 Effect of Austenitizing Temperature on Ductile Iron 55 4.3 Effect of Alloying Elements on Ductile Iron 58 4.3.1 Effect of Copper on the Tensile Strength of Ductile Iron 59 4.3.2 Effect of Nickel on Tensile Strength of Ductile Iron 63 4.3.3 Effect of a combination of Copper and Nickel on Ductile Iron 67 4.3.4 Effect of Lanthanum on Ductile Iron 71 4.3.4.1 Effect of Lanthanum on Nodule Count and Nodularity of Ductile Iron 72 4.3.4.2 Effect of Heat treatment with Lanthanum on Tensile Strength 78 4.3.4.3 Effect of Heat treatment on Microstructure of Ductile Iron 81 Chapter-5 CONCLUSIONS 88 FUTURE WORK 90 REFERENCES 91 Appendix 1 The bismuth-cerium phase diagram 98 Appendix 2 The lanthanum-bismuth phase diagram 99
xiv LIST OF TABLES Table No. Description Page 2.1 Composition of Grey Iron for Low Grade 3 2.2 Composition of Grey Iron for H igh Grade 3 2.3 Composition of Ferro-Silicon-Magnesium Alloy 10 2.4 Chemical Composition of Ni-base alloy Containing Magnesium in wt.% 12 2.5 Chemical Composition of Inoculants 16 2.6 Typical Composition of Ductile Iron for Austempered Ductile Iron 22 2.7 Composition of a Typical Alloy of Cerium 27 2.8 Austempered Ductile Iron ASTM A897-90 (ASTM 897 M-90) 30 2.9 British Standards Specification for ADI EN 1564:1997 31 3.1 Chemical Composition of Pig Iron in wt % 39 3.2 Chemical Composition of Mild Steel in wt % 39 3.3 Chemical Composition of Ferro-Silicon-Magnesium in wt % 40 3.4 Chemical Composition of Ductile Iron Produced with Copper in wt % 40 3.5 Chemical Composition of Ductile Iron Produced with nickel in wt % 41 3.6 Chemical Composition of Ductile Iron Produced with Copper & Nickel together in wt %. 42 3.7 Chemical Composition of Ductile Iron without Lanthanum in wt. % 42 3.8 Chemical Composition of Sorel Metal in wt. % 43 3.9 Chemical Composition of Swedish Iron in wt. % 43
xv 3.10 Chemical Analysis of Ductile Iron Alloyed with Lanthanum 46 4.1 Effect of Time on the Tensile Strength of Ductile Iron 52 4.2 Effect of Austenitizing Temperature on Tensile Strength of Ductile Iron 55 4.3 Effect of Copper on Tensile Strength of Ductile Iron 59 4.4 Effect of Nickel on Tensile Strength of Ductile Iron 63 4.5 Effect of Copper and Nickel together on Tensile Strength of Ductile Iron 68 4.6 Effect of Lanthanum on Nodule count and Nodularity on Ductile Iron 73 4.7 Dimensions of the Tensile Specimen (mm) 78 4.8 Effect of Lanthanum on the Tensile Strength of Ductile Iron 79
xvi LIST OF FIGURES Fig. No. Descriptions Page 2.1 Schematic diagram of a typical austempering heat treatment cycle 27 2.2 Schematic arrangement of the austempering process 29 3.1 Test bar mould (Dimension in mm) 44 4.1 Effect of time on tensile strength of ductile iron austenitized at 900o C and austempered at 270o C. 52 4.2 Effect of time on tensile strength of ductile iron austenitized at 900o C and austempered at 370o C. 53 4.3 Effect of austenitizing temperature on the tensile strength of ductile iron austempered at 270o C. 56 4.4 Effect of austenitizing temperature on the tensile strength of ductile iron austempered at 370o C. 57 4.5 Effect of copper on tensile strength without any heat treatment 61 4.6 Effect of copper on tensile strength when austenitized at 900o C and austempered at 270 o C. 61 4.7 Effect of copper on tensile strength when austenitized at 900 o C and austempered at 370 o C. 62 4.8 Effect of nickel on tensile strength without any heat treatment 65 4.9 Effect of nickel on tensile strength when austenitized at 900 o C and austempered at 270 o C 66 4.10 Effect of nickel on tensile strength when austenitized at 900 o C and austempered at 370 o C 66 4.11 Effect of copper and nickel without heat treatment. 70 4.12 Effect of copper and nickel together on tensile strength of ductile Iron when austenitized at 900 o C and austempered at 270 o C. 70 4.13 Effect of copper and nickel on tensile strength when austenitized at 900o C and austempered at 370 o C 71
xvii 4.14 Effect of lanthanum on the nodule count of ductile iron 74 4.15 Micrographs of ductile iron with 0.00%, 0.006 %, 0.02 and 0.03 % Lanthanum 75 4.16 Effect of lanthanum on nodule count of ductile iron 76 4.17 Effect of lanthanum on nodularity of ductile iron 77 4.18 Schematic diagram of tensile test sample 78 4.19 Micrographs of ductile iron austenitized at 900o C and austempered at 370o C for one hour with (a) 0.0 % La (b) 0.006 % La (c) 0.02 % La (d) 0.03 % La. 82 4.20 Micrographs of ductile iron austenitized at 900o C and austempered at 270o C for one hour with (a) 0.0 % La (b) 0.006 % La (c) 0.02 % La (d) 0.03 % La. 83 4.21 SEM photograph of ductile iron austenitized at 900o C and austempered at 370o C 84 4.22 SEM photograph of ductile iron austenitized at 900o C and austempered at 370o C 84 4.23 SEM photograph of ductile iron austenitized at 900o C and austempered at 270o C 85
xviii Chapter - 1 INTRODUCTION The increasing interest in energy saving has led to the development of lightweight materials to reduce the weight of existing materials without compromising their properties. In the automotive industries, attempts have been made to replace cast iron and steel components with aluminum and austempered ductile iron. Austempered ductile iron (ADI) is a ductile iron that has undergone a special isothermal heat treatment called austempering. Unlike conventional “as-cast” irons, its properties are achieved by specific heat treatment. Therefore, the only prerequisite for good ADI is a good quality ductile iron. ADI offers superior combination of properties because it can be cast, like any other member of the ductile iron family. It offers all production advantages of conventional ductile iron castings. Subsequently it is subjected to the austempering process to produce mechanical properties that are superior to conventional ductile iron, many cast and forged steels. The mechanical properties of ductile iron and austempered ductile iron (ADI) are determined by the metal matrix. In conventional ductile iron it is controlled by the mixture of pearlite and ferrite. However the properties of ADI are due to its unique matrix of acicular ferrite and carbon stabilized austenite called ausferrite.
xix It is a well known that an appropriate amount of rare earth is often used in ductile iron production in order to counteract the deleterious effects of subversive elements, e.g. titanium, bismuth and others. It is believed that the rare earths combine chemically with the subversive elements to effectively remove them from the system although reactions between titanium and rare earths have not, as yet, been identified [1]. However, an excessive amount of rare earth elements is known to promote the formation of chunky graphite [2-4]. While doing a preliminary survey on the production of ductile iron in Pakistan, it was noticed that only a few foundries were producing ductile iron castings of a reasonably good quality. Austempered ductile iron, however, was not being produced at all in any foundry in Pakistan. Research in this area was also found to be limited to a couple of research papers on ADI. Realizing the importance of ADI and its use in automobile and in other sectors in western countries, this researcher thought it necessary to explore the production of ADI locally. ADI was therefore produced at laboratory scale in Pakistan using raw materials available locally. In the present work, the effect of alloying elements (copper, nickel, a combination of copper and nickel and lanthanum) as well as the effect of changing different parameters of heat treatment i.e. time and temperature on ductile iron were studied.
xx CHAPTER - 2 LITERATURE REVIEW The term, cast iron, identifies a large family of ferrous alloys. Cast irons are primarily alloys of iron that contain more than 2.0 wt. % carbon. It also contains 1.0 to 3.0 wt. % silicon. The different properties of castings can be achieved by changing carbon content, silicon content, by alloying with various elements, and by varying melting, casting and heat treatment practice. Cast irons, as the name implies, are indeed to be cast to shape rather than formed in solid state. Cast irons have low melting temperatures and are very fluid when molten and have undergone slight to moderate shrinkage during solidification. However, cast irons have relatively low impact resistance and ductility, which limits their use. [5]. This must be taken into account when designing castings to withstand service stresses. Irons of the composition given below in table 2.1 and table 2.2 satisfy a low and high grade specification of grey cast iron in a medium size, uniform sections sand castings [6]. Table 2.1 (G 150) Composition of Grey Iron for Low Grade C % Si % Mn % S % P % 3.1-3.4 2.5-2.8 0.5-0.7 0.15 0.9 Table 2.2 (G 350) Composition of Grey Iron for High Grade C % Si % Mn % S % 3.1 max 1.4-1.6 0.6-0.75 0.12
xxi The properties of flake iron depend on size, amount, distribution of graphite flakes and matrix structure. 2.1 DUCTILE IRON Ductile iron derives its name from the fact that, in the as-cast form, it exhibits measurable ductility. By contrast, neither white iron nor grey iron exhibits significant ductility in a standard tensile specimen [5]. Ductile iron is defined as a high carbon containing, iron-base alloy in which graphite is present in a compact, spheroidal shape [7]. Ductile iron is also known as nodular iron or spheroidal graphite iron. Unlike grey iron that contains graphite flakes; the ductile iron has as- cast structure containing graphite particles in the form of small rounded spheroidal nodules in the matrix. Therefore, ductile iron has much higher strength than grey iron and a considerable degree of ductility. 2.1.1 History of Ductile Iron Foundry men continued to search for an ideal cast iron an as cast “grey iron” with mechanical properties equal or superior to malleable iron. In 1943, Keith Dwight Mills made a ladle addition of Magnesium (as copper-magnesium alloy) to cast iron in the International Nickel Company Research Laboratory. The solidified castings contained no flakes but nearly perfect spheres of graphite [8]. Five years later, at 1948 AFS Convention, Henton Morrogh of British Cast Iron Research Association announced the successful production of spheroidal graphite in hyper eutectic grey iron by addition of small amount of cerium [8].
xxii At the same time Morrogh from the International Nickel Company, presented a paper which revealed the development of magnesium as graphite spheroidizer. On October 25, 1949, patent 2,486,760 was granted to the International Nickel Company, assigned to Keith D. Mills [8], Albert P. Gegnebin and Norman B. Pilling. This was the official birth of ductile iron. 2.1.2 Production of Ductile Iron Ductile iron can be produced by treating low sulphur liquid cast iron with an additive usually containing magnesium and then inoculated just before or during casting with a silicon-containing alloy. 2.1.2.1 Raw Materials To produce ductile iron with the best combination of strength and toughness, raw materials must be chosen which have lower than 0.02 wt.% sulphur and are low in trace elements. Low manganese content is also needed to achieve as-cast ductility. Higher strength grades of ductile iron can also be made with common grades of constructional steel scrap, pig iron and foundry returns, but certain trace elements e.g. lead, antimony and titanium are usually kept as low as possible to achieve good graphite structure. 2.1.2.2 Control of the Composition of Ductile Iron Composition of Ductile Iron The composition of unalloyed ductile iron is similar to that of grey iron with respect to carbon and silicon contents. Carbon contents of unalloyed ductile iron ranges from 3.0 wt.% to 4.0 wt.% and silicon content from 1.6 wt.% to 2.8 wt.%. The sulphur and phosphorus levels of high quality ductile iron, however, must be kept very low at
xxiii 0.03 wt.% S maximum and 0.1 wt.% P maximum, which are ten times lower than the maximum levels for grey cast iron. Other impurities must also be kept low because they interfere with formation of graphite nodules in ductile iron [9]. All the elements in the composition of ductile iron should be controlled. The following are the important elements in the production of ductile iron [10]. Total Carbon The optimum range of carbon is usually 3.4 to 3.8 wt.% depending on the silicon content. Above this range there is a danger of graphite floatation, especially in heavy sections. Silicon Silicon enters ductile iron from raw materials, including cast iron scrap, pig iron, ferro-alloys and to small extent from silicon-containing alloys during inoculation. The preferred range is about 2.0 to 2.8 wt.%. Lower silicon levels lead to high ductility in heat-treated iron but there is danger of carbides in thin section. High silicon helps to avoid carbides in thin sections. It also increases hardness and tensile strength. Carbon Equivalent The carbon, silicon and phosphorus contents can be considered together as a Carbon Equivalent Value. This is a useful guide to foundry behavior. There are several Carbon Equivalent formulas and they are useful in assessing the casting properties. The formula that is commonly used is as follows: CE = C% + 1/3(%Si + %P) [10]
xxiv If the value CE is equal to 4.3wt.%, the iron will be wholly of eutectic composition. When CE is lower than 4.3, there will be a proportion of dendrites; if CE is higher than 4.3 wt.% there will be primary graphite nodules in the structure. Manganese The main source of manganese is steel scrap used in the charge. Manganese should be limited in order to obtain maximum ductility. In as- cast ferrite iron, it should be 0.2 wt. % or less. Manganese produces to undesirable micro segregation especially in heavy section. It encourages the formation of grain- boundary carbides which promote low ductility, low toughness and persistent pearlite. Magnesium The magnesium content which is required to produce spheroidal graphite usually ranges from 0.04 to 0.06 wt.%. If the initial sulphur content is below 0.015 wt.%, lower magnesium content in the range of 0.035 to 0.04 wt.% may be satisfactory. Compacted graphite structure with inferior properties may be produced if magnesium is low, while too high magnesium content may promote dross defects and carbide formation. Minor Elements Promoting Non-spheroidal Graphite Lead, antimony, bismuth and titanium are undesirable elements that may be introduced in trace amount with raw materials in the charge. Their effects can be neutralized by cerium addition as reported by I. C. Hughes [10]. Aluminium The presence of even trace amount of aluminium in ductile iron may promote surface pinhole- porosity and dross formation. The common source of aluminium is
xxv contaminants in steel and cast-iron scrap. Another source is aluminium containing inoculants so use of inoculants of low aluminium is advisable. Aluminium as low as 0.01 wt.% may cause pinholes in ductile iron. Phosphorus Phosphorus is normally kept below 0.05% because it promotes unsoundness and lowers ductility. Minor Elements Promoting Carbides Chromium, vanadium and boron are carbide promoters. They are controlled by a careful selection of metallic raw materials for melting 2.1.2.3 Charge Materials The metallic charge for ductile iron base consists mainly of: Pig iron, steel scrap, return ductile iron scrap and ferroalloys [7] Pig Iron The ideal pig iron for ductile iron charge is pure iron- carbon alloy, which is not available. It is believed that sorel metal is the best charge. In sorel metal the manganese content is very low i.e. 0.009 wt.% and its content of elements which either promote carbides or interfere with spheroidization of graphite is low. Steel Scrap Steel scrap is an important component of ductile iron charge. Chemical composition and physical shape are to be considered. The physical shape includes dimensions and specific surface. All melting equipment has its limitations as to maximum size. The cupola furnace also has a minimum size limitation.
xxvi Even though very small pieces may be charged into electric induction or arc furnaces (such as thin plate chippings) these have very large specific surface areas which rust rapidly. Even though rust is not believed to cause metallurgical deterioration, it certainly increases slag quantity, acidity and corrosiveness. Whenever possible, such scrap should be used in a balanced condition. Despite these difficulties, steel scrap will remain in use because it is normally less expensive than pig iron and also available in plentiful supply [7]. Ductile Iron Scrap Only scrap of ductile iron of known quality should be used. Ferro Alloys When Ferro alloys are needed in the charge, the chemical composition of the alloys should be known. 2.1.2.4 Desulphurization A variety of compounds are capable of removing sulphur from molten iron. Even manganese desulphurizes but it is an expensive material [7]. More practical desulphurizing agents are [7]: Caustic Soda NaOH Soda Ash Na2CO3 Burnt Lime CaCO3 Calcium Carbide CaC2 Calcium Cyanide CaCN2
xxvii Of these, caustic soda is rarely used because of the health hazard. Lime stone is first reduced to CaO before use. CaCN2 should be ruled out because it increases base iron nitrogen content with the result of a danger of nitrogen gas defects in the castings. In the tradition of ferrous metallurgy, CaO is the most established of desulphurizing compounds. In ductile iron practice, it is used in basic cupola and electric arc furnace. Limestone (CaCO3) is injected into large ladles resulting in both economical and excellent desulphurization. 2.1.2.5 Spherodizing Treatment Alloys There are two main alloys in use, nickel magnesium (NiMg) and ferro-silicon- magnesium (FSM). Ferro-silicon-magnesium alloy is commonly used. It should have the composition shown in table 2.3. Table 2.3 Composition of Ferro-silicon-magnesium Alloy Mg % Si % Ca % Ce % Fe % 4-6 45-50 1 max 0.5 balance 2.1.2.6 Melting Techniques for the Production of Ductile Iron Any furnace which is used for melting of ductile iron must be capable of producing an iron of correct composition at correct temperature. The need to maintain these factors consistently is most important.
xxviii Types of Furnaces Various furnaces are available for the production of ductile iron e.g. fuel fired furnace, electric arc furnace, induction furnace and cupola. Optimum economy and quality is achieved through cupola-induction furnace duplexing, but this optimum is obtainable for large volume production only. Externally water-cooled cupola furnaces are being used for large scale operations. Water-cooling causes too much heat losses in small cupolas. The main reason for their popularity is the fact that these can operate continuously for several days [7]. Electric Melting Electric melting is simple, clean and reliable. It also offers the greatest flexibility for melting irons of different grades. Electric arc furnaces are far less popular than induction furnaces. An additional disadvantage of electric arc melting is its noise pollution. Electric induction furnaces are most common. High frequencies units are usually used for laboratory scale production. In commercial production either 50 or 60 HZ frequencies are being used; the lower the frequency, the better the stirring action and thus, homogenization. 2.1.2.7 Spheroidizing Treatment One of greatest practical difficulties is the required amount of magnesium into the melt with the necessary degree of consistency. Magnesium boils at 1120o C and when plunged into cast iron at 1400o C, Magnesium metal melts and vaporizes instantaneously, escaping with violence and carrying some of the cast iron with it. Different alloys are
xxix used to overcome this difficulty. An alloy of nickel and magnesium (5 or 15 % Mg) is efficient as it sinks in molten iron and the reaction is relatively quiet , especially with 5 wt.% alloy. However it is expensive and simultaneously addition of nickel is not always welcomed [11]. Following are four most generally used nickel base magnesium alloys shown in the table 2.4 [7]. Table 2.4: Chemical composition of Ni-base alloy containing magnesium in wt.% Mg % Ni % Si % C % Fe % Ni-Mg 1 15 83 --- 2.0 --- Ni-Mg 2 15 50 30 --- Bal Ni-Mg 3 4.5 93 --- 1.5 --- Ni-Mg 4 4.5 60 --- 2.5 Bal A range of magnesium-ferro-silicon alloys are available containing 3 to 15 wt.% magnesium with approximately 45 % silicon [11]. Although various methods are employed for introducing magnesium into molten metal, the universally accepted procedure is the sandwich method. Because of the relatively low density, ferrosilicon- magnesium alloys tend to float on the surface of the liquid iron and react inefficiently. Accordingly, the alloy is placed in the bottom of the treatment ladle, preferably in a „pocket‟ moulded in the bottom of the ladle, and covered with steel plate. Before use, the ladle should be heated to a temperature of red heat.
xxx After placing the ferrosilicon-magnesium alloy in the pocket and covering the alloy with the plate, the ladle is positioned so that liquid metal stream does not impinge directly on the magnesium alloy/sandwich. This allows the metal to flow back over the sandwich, which due to presence of cover, delays the reaction of magnesium alloy until a sufficient depth of alloy is built up in the ladle, and it also prevents the alloy floating to the surface of the liquid iron. The ladle should be filled as quickly as possible. This improves the magnesium recovery. The magnesium recovery depends on metal temperature, the quantity of metal treated and the design of the ladle. 2.1.2.8 Amount of Magnesium Required In practice it is normal to allow for minimum residual magnesium content of 0.035 to 0.04 wt.%, plus the amount of magnesium required to neutralize the sulfur in the iron. The amount of magnesium alloy required depends on two factors: a) The temperature of metal, the higher the temperature, the lower the recovery of magnesium. b) Sulphur content of the base iron to be treated; the higher the sulphur content, the greater is the amount of magnesium to be added. Calculation of Magnesium: Different formulas are used to calculate the amount of magnesium required. The commonly used formula is [7]: Mg to add (%) = %SBase 01.0%erycovreMg %requiredcontentMg   
xxxi Fading of Magnesium There is a gradual decrease in nodularity and an increase in carbide formation, as treated iron is held for some time. The results from different research centers indicated that fading is rather complicated phenomenon. The simplest component is loss of magnesium content through oxidation or combining with sulphur. Stephen [7] described the following corresponding reactions: Mg + O = MgO or Mg + S = MgS Considering the relative stabilities of the above two compounds, a more likely reaction is: Mg + S + O = MgO + S If the source of oxygen is an oxide or silica as an oxide, the corresponding reactions are: 2Mg + SiO2 = Si + 2MgO and 2MgS + SiO2 = Si + 2MgO +2S It is well established that fading rate is influenced by: a) Initial Magnesium content; the higher the magnesium content the faster the fading b) Temperature; the higher the temperature the faster the fading c) Slag handling; the faster the slag is removed, the better for magnesium recovery.
xxxii d) Furnace lining; the worst is silica, the best is magnesia. 2.1.2.9 Inoculation The metallurgical meaning of the word “inoculation” is to provide the melt with seeds or “nuclei” on to which the solid phases grow during freezing. In some cases these nuclei result from adding fines of the same phase which is freezing. If the fines do not completely dissolve before solidification starts, they provide convenient sites for crystal growth. In other cases particles of material other than the one to freeze can perform the same act i.e. heterogeneous nucleation. The inoculation of ductile irons produces heterogeneous nuclei for the graphite spheroids. Neither their material nature nor mechanism of their action is factually known [7]. The Effects of Inoculations The principle effects of ductile iron inoculation can be described as follows [12]. The inoculation process:  Promotes the formation of small and uniformly dispersed graphite in grey iron and increase the nodule count in ductile iron.  Minimizes the formation of primary iron carbides. These carbides create hard edges on iron castings that make machining difficult, which is a contributing factor to tool breaking.
xxxiii  Reduces the non-uniform properties within a casting of varying section sizes. Thinner sections solidify at a faster rate than thicker sections. As a result, the properties such as tensile strength of these sections will be different. Inoculation provides more uniform properties within the casting by reducing the solidification rate in thinner sections.  Improves the tensile strength, impact strength, toughness, wear resistance and machinability of the casting. Inoculants Almost every material inoculates to some degree. For effective and well controlled inoculation, ferro-silicon of controlled chemical composition are usually used. Active inoculating elements are: Ca, Al, Ba, Sr, and some others. The chemical composition of commonly used inoculants is given in table 2.5 [7]. Table: 2.5 Chemical Composition of Inoculants Si % Ca % Al % Ba % Fe % 75 1.5 1.0 --- Bal 63 2.0 1.0 5 Bal The inoculants contain relatively little aluminium because aluminium promotes hydrogen pinholes defects, particularly in thin sections [7]. The sizing of the inoculant is usually ½ inches (13 mm) maximum. Since fines do not inoculate effectively, a minimum size limit of 1/6 inches (1.5 mm) is advisable [7].
xxxiv The inoculant should be stored in closed containers. Its effectiveness deteriorates with time when exposed to open air. Methods of Inoculation Cast iron may be inoculated by several methods [12].  Ladle Inoculation Iron is inoculated by adding inoculant to the metal as it is transferred from the furnace to the pouring ladle. The turbulence quickly dissolves the inoculant and evenly disperses it throughout the molten bath.  In-stream Inoculation In many automatic pouring operations, inoculation is done in-the-stream  In-mould Inoculation Inoculants may also be added as a preformed insert placed in the pouring basin of a mould or as granulated inoculant placed in the gating system. In-stream and in-the-mould inoculation techniques offer little inoculation fade, and generally require less inoculant material to provide the desired results. 2.1.3 Formation of Carbides in Ductile Iron: The attainment of mechanical properties in cast ductile iron depends primarily upon the microstructure developed during solidification and solid-state transformation. A recent trend in vehicle component has been towards higher strength and lighter weight to save both materials and energy. Reducing the weight of ductile iron castings by producing thin-wall parts is an important method for saving energy and material. In thin
xxxv castings the cooling rate is fast so carbides are formed if special practice and procedure are not adopted. The general reasons for the carbide formation are as under [13]. 1. High solidification cooling rate 2. Carbide-formation elements in the charge 3. Low CE and / or Si content 4. Excessive Mg content 5. Inadequate and poor inoculation (low nodule count) 6. High superheat 2.1.4 Pouring Pouring of ductile iron should be done quickly while keeping the pouring basin full through the pour. A majority of ductile iron castings are hand-poured even in highly mechanized foundries. It must be recognized that hand-pouring is a demanding job and the pourer is exposed to some hazard. For this reason and, for potential economic and quality benefits, much effort is being invested in designing pouring machines [7]. 2.1.5 Importance of Ductile Iron Ductile iron is a very useful invention. It offers the design engineers the option of choosing high ductility, more than 18% elongation, or high strength exceeding 825 MPa. Ductile iron, when compared to steel and malleable iron castings offers cost savings [14]. Like most commercial cast metals, steel and malleable irons decrease in volume during solidification, and as a result, require attached reservoirs (feeders or risers) of liquid metal to compensate shrinkage. The formation of graphite during solidification
xxxvi causes an internal expansion of ductile iron as it solidifies. As a result, it may be cast free of significant shrinkage defects with feeders that are much smaller than those used in malleable iron and steel. This reduced requirement for feed metal increases productivity of ductile iron and reduces its material and energy requirements resulting in substantial cost savings. The use of most common grades of ductile iron “as-cast” eliminates heat treatment cost, offering a further advantage. Ductile iron castings are used for many structural applications, particularly those requiring strength and toughness combined with good machinability and low cost. A ductile iron casting can be poured and shipped the same day. As-cast ductile iron castings are consistent in dimensions and weight because there is no distortion or growth due to heat treatment. Ductile iron is finding increasing applications in automobile parts e.g. crankshafts, piston rings and cylinder liners. The use of ductile iron in these applications provides increased strength and permits weight savings. In agricultural and earth-moving application, brackets, sprockets wheels and track components of improved strength are made of ductile iron. General engineering applications include hydraulic cylinders, mandrels, machine frames, switch gears, rolling mill rolls, tunnel segments, bar stock, street furniture and railway rail-clip supports
xxxvii 2.2 AUSTEMPERED DUCTILE IRON (ADI) 2.2.1 Austempering To achieve the full potential of ductile iron, austempering heat treatment is adopted. It is possible to achieve much higher ranges of tensile strength and elongation by adopting austempering treatment for ductile iron. For austempering treatment, a defect free casting should be chosen. Any lapse in quality control of starting material will result in inferior end product. The process is simple. The first stage consists of soaking the castings at austenitizing temperature of 850-950o C. The austenitized castings are then quickly transferred to a liquid bath (salt bath) maintained at temperature range of 235- 425o C. The transformation is allowed to proceed for a period of up to four hours when austenite transforms to bainite. The castings are finally cooled to room temperature after transformation. By adopting austempering heat treatment process instead of conventional hardening and tempering treatment for ductile iron, the chances of cracking and distortion are reduced. Thus, it becomes possible to carry out rough and final machining before heat treatment. It is possible to achieve various combinations of high strength, high hardness, limited ductility or lower strength, lower hardness, high ductility by varying the temperature of austempering. 2.2.2 Introduction to Austempered Ductile Iron: Austempered ductile iron (ADI) is a ductile iron that has undergone a special, isothermal heat treatment called austempering. Unlike conventional “as-cast” irons, its properties are achieved by heat treatment, not by specific addition. Therefore the only prerequisite for a good ADI is a quality ductile iron [15]
xxxviii ADI offers superior combination of properties because it can be cast like any other member of the ductile iron family. It offers all production advantages of conventional ductile iron castings. Subsequently, it is subjected to the austempering process to produce mechanical properties that are superior to conventional ductile iron, cast and forged aluminium and many cast and forged steels. The metal matrix determines the mechanical properties of ductile iron and ADI. The matrix in conventional ductile iron is controlled by a mixture of pearlite and ferrite. The properties of ADI are due to its unique matrix of acicular ferrite and carbon- stabilized austenite, called ausferrite. Austempering was commercially applied to austempered ductile iron in 1972. A small hallow crankshaft cast by Wagner Casting Company of Decatur, Illinois was machined and installed in a Tecumser products type AE compressor. Meanwhile General Motors successfully implemented ADI rings and pinion gears and constant velocity joints on its production trucks and automobiles [15]. From its infancy in 1972 until today, the application of ADI has grown worldwide. Its annual growth is estimated at 15%. Its combination of high strength- to- weight ratio, wear resistance and low cost have made it a “high-tech” material. Researchers are continuously studying its new parameters [15]. 2.2.3 Production of Austempered Ductile Iron The mechanical properties offered by ADI make it an attractive material for demanding applications. Austempered ductile iron castings must be produced free from surface defects, free from carbides, porosity, inclusions and having a consistent chemical composition .
xxxix 2.2.3.1 Composition of ADI In many cases, the composition of an ADI casting differs a little from that of a conventional ductile iron casting. When selecting the composition, consideration should be given to the elements that adversely affect casting quality e.g. formation of carbides and inclusions. A typical composition of ductile iron casting used for making austempered ductile iron is given in the table 2.6 [16]. Table 2.6 Typical Composition of Ductile Iron for Austempered Ductile Iron C % Si % Mn % Cu % Ni % Mo % 3.5-3.7 2.5-2.7 0.25-0.31 0.05-0.8 0.01-0.8 If required 0.25 max There are three important points to consider when selecting the chemical composition of ADI [17]. 1) The iron should be sufficiently alloyed to avoid transformation of pearlite but not over alloyed. 2) The micro structure should be free from intercellular carbides and phosphides. 3) The tendency for chemical segregation should be minimized for the sake of uniformity in the cast component. 2.2.3.2 Effects of Alloying Elements Alloying elements are generally used in ductile iron to increase its hardenability. Only the minimum amount of alloys required should be used. Excessive alloying only
xl increases the cost and difficulty producing quality ductile iron necessary for ADI. The following are major alloying elements which are used for austempered ductile iron [16]. Carbon Increasing carbon in the range of 3 to 4 wt. % increases the tensile strength but has negligible effect on elongation and hardness. Carbon should be controlled within the range of 3.6 to 3.8 wt.%. Silicon Silicon is one of the most important elements in austempered ductile iron (ADI) as it promotes graphite formation, decreases the solubility of carbon in austenite and inhibits the formation of bainite carbide. Increasing the silicon content increases the impact strength of ADI. Silicon should be controlled closely within the range of 2.4 to 2.8 wt. % Manganese Manganese can be both beneficial and harmful as an alloying element. It strongly increases hardenability, but during solidification, it segregates to cell boundaries where it forms carbides and retards austempering reaction. It is advisable to restrict the manganese level to less than 0.3 wt.% Copper It increases hardenability and ductility at austempering temperature below 350 o C. It may be added up to 0.8 wt.%
xli Nickel Nickel increases hardenability of ductile iron .It increases ductility and fracture toughness at austempering temperature below than 350 o C. It may be added up to 2.0 wt.%. Molybdenum It may be added in heavy section castings to prevent the formation of pearlite. Tensile strength and ductility decreases as the molybdenum is increased beyond that amount which is required for hardenability. This is because of segregation of molybdenum to cell boundaries and formation of carbides. It should not be added more than 0.2 wt. % Phosphorus Phosphorus forms the very brittle structure known as steadite in ductile iron as well as in grey cast iron since phosphorus adversely affects toughness and ductility, a maximum of 0.05 per cent is usually specified [18] Sulphur The most important effect of sulphur in ductile iron is to increase the amount of magnesium required to achieve spheroidal graphite. The level of sulphur in the iron prior to magnesium treatment is a function of the melting practice used. Sulphur content after treatment is usually 0.015 per cent [18]. Very little work has been carried out to study the effect of sulphur. Generally sulphur is considered to be an impurity. Patty Sim, [19] a foundryman was using autopour at his foundry. His target was 0.013 per cent sulphur in the furnace bath. According to him lower sulphur target could cause carbides in the finished castings.
xlii The influence of sulpher on the machinability of grey cast was studied by Adriana et al. [20]. They found that sulpher addition in grey iron from 0.065 to 0.18 wt.% did not produce significant alternation on mechanical properties or on microstructure. From their study viable use of a higher sulpher percentage on grey cast iron production, without the detrimental effects of mechanical properties, microstructure and machinability were obtained. Rare Earth Elements The addition of rare earth elements has significant effects on the properties of ductile iron [15]. Following are the most common rare earth elements which are used in ductile iron. 1. Cerium Cerium is a powerful desulphuriser. When sulphur content of a cast iron exceeds about 0.02 wt. % the cerium reduces sulphur content. Cerium combines with sulphur even in the presence of manganese. Cerium sulphide is formed and it rises to the surface of the molten metal. The higher the sulphur content of the molten metal the greater will be the amount of cerium required. As cerium is a relatively expensive material, so sulphur content of iron to be treated should at the lowest level. Cerium may be added to cast iron in a variety of alloys i.e. pure cerium, iron-cerium, nickel-cerium, copper- cerium, silicon-cerium, manganese-cerium, and aluminium-cerium. All dissolve quite easily in molten cast iron. On account of its ready commercial availability and relatively low cost, a cerium alloy known as mischmetal is most frequently employed. Mischmetal contains approximately 50% of cerium. Chemical analysis of a typical cerium alloy [11] is given the table 2.7.
xliii Table 2.7 Composition of a Typical alloy of Cerium Ce % La % Nd % Other rare earths Fe % 45-53 22-25 15-17 8-10 5 max An important point to be observed is that the mischmetal should not be finally divided in the form of powder, as loss by oxidation may occur. Morrogh [21] and Wallance et al. [22] have reported that a very small addition of cerium as mischmetal has a controlling effect on the deleterious elements such as lead, arsenic, antimony, titanium, and tin. McCluhan [23] has shown that an optimum addition of cerium as mischmetal to laboratory magnesium-ferro-silicon (MgFeSi) results in ductile cast irons with high graphite nodule counts and low levels of carbide formation. 2. Lanthanum Very little work has been done on the effect of lanthanum on the properties of the ductile iron. When lanthanum is added to ductile iron as a lone rare earth element in the nodulizing alloy, mixed results have been reported. Horie et al [24] claimed that nodule count increases and carbides are reduced when the La: S ratio is between 2.5 and 6.0. However, Stefanescu et al. [25] found that nodule count steadily decreases as the lanthanum content in MgFeSi increases. Very little work has been done on the effect of rare earth elements on the microstructure and the properties of ductile iron. It would be of considerable interest to determine whether the addition of lanthanum is significant in affecting nodule count and nodularity
xliv 2.2.3.3 Production of Austempered Ductile Iron: Austempered ductile iron is produced by an isothermal heat treatment known as austempering. It consists of the following steps and it can be represented schematically as shown in Figure 2.1 [17]. 1) Heating the casting to the austenitizing temperature in the range of 850 o C to 950 o C 2) Holding the part at austenitizing temperature for a time sufficient to get the entire part to the required temperature and to saturate the austenite with carbon. 3) Quenching the part rapidly enough to avoid formation of pearlite to austempering temperature in the range 235 o C to 400 o C 4) Austempering the casting at the desired temperature for a time sufficient to produce matrix of ausferrite. 5) Finally cooling the casting to room temperature. Figure 2.1 Schematic diagram of a typical austempering heat treatment cycle [17]
xlv Austenitizing The austenitizing temperature controls the carbon content of austenite that affects the structure and properties of austempered castings. High austenitizing temperature increases the carbon content of austenite, which effect the hardenability. It makes the transformation problematic and reduces the mechanical properties after austempering. The higher carbon of austenite requires a longer time to transform. Austenitizing temperature should be minimum required to heat the entire part to the desired austenitizing temperature and to saturate the austenite with equilibrium level of carbon. Austenitizing time is affected by chemical composition, austenitizing temperature, casting section size and type [16]. Austempering Cooling from austenitizing temperature must be completed rapidly to avoid the formation of pearlite. If pearlite is formed, the strength, elongation and toughness will be reduced. Austempering temperature is one of the major determinants of mechanical properties of ADI castings. Higher austempering temperature (350 o C to 400 o C produces ADI with lower strength and hardness but high elongation and fracture toughness. Higher austempering temperature produces coarse ausferrite matrix. For production of ADI with higher strength and greater wear resistance but lower fracture toughness and lower elongation, austempering temperature below 350 o C should be employed.
xlvi When austempering temperature is selected, the austempering time should be chosen to give a stable structure of ausferrite. Shorter austempering time will give rise to insufficient diffusion of carbon to austenite to stabilize it and martensite may form when cooling to room temperature. This type of structure would give higher hardness and lower ductility. Excessive austempering time can result in decomposition of ausferrite into ferrite and carbides, so austempering time selection should be appropriate [16]. 2.2.3.4 Heat Treatment Considerations It is important that the heat treatment operation is closely controlled to ensure the production of castings with consistent and satisfactory mechanical properties. A schematic representation of batch austempering heat treatment process is shown in figure 2.2 [17]. Figure 2.2 Schematic arrangement of the austempering process [17]
xlvii 2.2.4 Specifications of Austempered Ductile Iron The ASTM specification A 897 is now most commonly accepted for austempered ductile iron. The five grades specified are detailed in table 2.8 below. They are readily differentiated by their hardness. Tensile, yield and elongation values are also specified as shown in table 2.8 [26]. Table 2.8 Austempered Ductile Iron ASTM A897-90 (ASTM 897 M-90)[26] Grade Min. Tensile Min. Yield Elongation BHN Psi. N/m2 Psi. N/mm2 % Range 1 125,000 850 80,000 550 10 269-321 2 150,000 1050 100,000 700 7 302-363 3 175,000 1200 125,000 850 4 341-444 4 200,000 1400 155,000 1200 1 388-477 5 230,000 1600 185,000 1300 - 444-555 The British Standards Specification for austempered ductile iron is also used mostly in Europe. The four grades are detailed in table 2.9. They are differentiated by their tensile, proof stress and elongation. The standard EN 1564:1997 is shown in table 2.9 [26].
xlviii Table 2.9 British Standards Specification for ADI EN 1564:1997 [26] Material Symbol Number Tensile Strength N/mm2 (Min.) 0.2 % Proof Strength N/mm2 (Min.) Elongation % EN-GJS-800-8 EN-JS 1100 800 500 8 EN-GJS-1000-5 EN-JS 1110 1000 700 5 EN-GJS-1200-2 EN-JS 1120 1200 850 2 EN-GJS-1400-1 EN-JS 1130 1400 1100 1 2.2.5 Cost Benefits of Austempered Ductile Iron: The price of austempered ductile iron is lower than per kilogram of steel. ADI parts can be produced at a cost less than for steel forging. There are many factors which favour the replacement of steel forging with austempered ductile iron [27]. Excellent castability It can be cast into complex shapes. Ductile iron has a very high yield. Low Machining Cost ADI requires less starting material and less metal removal. Prior to austempering, ductile iron exhibits better machinability than the steels. Both ductile iron and ADI produce dense, discontinuous chips that are easily handled. Heat treatment Savings Austempering generally costs less than carburizing or induction hardening, and produces a higher degree of uniformity.
xlix Low Energy Cost Producing a typical austempered ductile iron castings consumes 50% less energy than steel casting and 80 % less energy than steel forging for the producing of the similar product. 2.2.6 Properties Of Austempered Ductile Iron Austempered Ductile iron has the following properties [16,27] Strength It has strength equal to or greater than steel Toughness It has toughness better than ductile iron and equal to or better than cast or forged steel. Weight Austempered ductile iron has 10 % less weight than steel due to the presence of graphite nodules. Fatigue Strength Austempered ductile iron has equal to or better fatigue strength than forged steel, which increases with machining after heat treatment Damping Austempered ductile iron has five times better damping property than steel. The parts made of this material make less noise.
l 2.2.7 Disadvantages of Austempered Ductile Iron: There are certain disadvantages of austempered ductile iron. These should be considered before replacing steel parts with ADI. These are as follows [28]. 1) Welding is not recommended for austempered ductile iron. 2) Lower hardness grades can be machined after heat treatment, but higher hardness grades must be machined before heat treatment. 2.2.8 Application of Austempered Ductile Iron: The development of austempered ductile iron (ADI) has given the design engineers a new group of cast ferrous materials. ADI provides an exceptional combination of mechanical properties equivalent to cast and forged steel. Dr. Richard Harding [29] overviewed the wide range of application of austempered ductile iron. Gears One of the earliest applications of ADI was for the manufacture of gears. Pioneers in this field were:  General Motors, USA for rear axle hypoid pinion and ring gears for cars  Chinese foundries, who used similar gears for light and medium trucks [30]  Kymi Kymmence, Finland, for various applications including general engineering gear boxes, rolling mill drives, and large segmented ring gears for cement mills, rotary kilns and forestry machines [31,32]
li Crankshafts One of large potential markets of austempered ductile iron is crankshafts for high-powered diesel engines [29]. Crankshafts for air-conditioning and refrigerator application have been produced by companies such as Wagner Casting Co. USA and Sulzer Brothers, Switzerland [33] Transmissions There are following examples for the transmissions [29].  A large number of tripot housings have been used by General Motors, USA, in front- wheel drive units.  Differential spiders manufactured by Kymi Kymmene, Finland. Suspensions The austempered ductile iron suspensions have been used in the industry. The example includes war shoe restraints made by Advance Cast Products, USA , for use in suspension units of lorry tractor units [29]. Railway Engineering A variety of austempered ductile iron components have been used in European and American railway applications e.g. Axle boxes produced by SKF, Sweden, for railway vehicles and pick up arms for railway track maintenance machines, produced by Sulzer Brothers, Switzerland [26,33] Bracket Trailer The Australian trucking industry had interesting challenges in terms of hauling freight over rough and isolated distances that can be exceptionally long. Different
lii experiments were carried out with different materials. They failed the on-road test. Ultimately a ductile iron casting was designed and austempered to ASTM Grade 2 ADI. The bracket was 900mm long and 1200 mm high, with a weight of 105 kg. These ADI brackets successfully traveled over 322,000 km without any problem [34]. Agricultural Applications Due to its high strength-to-weight ratio as well as its increased wear resistance, austempered ductile iron is well suited for agricultural applications from suspension to ground-engaging components [35] Defence The defence industry has been relatively slow to adopt ADI, however some of the applications include track links, armor and various hardware for trucks and armored vehicles [16].
liii CHAPTER - 3 EXPERIMENTAL WORK RESEARCH METHODOLOGY During the present research an attempt was made to observe the tensile strength of ductile iron by the addition of copper, nickel, a combination of copper and nickel and lanthanum. Different heats with and without copper, nickel and a combination of copper and nickel were made to find out the effect of these alloying elements on ductile iron. Samples for this study consisted of tensile test bars having different compositions of ductile iron with and without the alloying additions. Test bars from one melt without lanthanum were produced in the Casting Laboratory of the University of Birmingham, UK. Test bars with varying composition of lanthanum from three melts were produced to observe the effect of the addition of lanthanum. Different experiments were conducted for studying the effect of alloying elements and effect of heat treatment on ductile iron.  To find out the optimum austempering time, ductile iron samples were heat treated at fixed austenitizing temperature at 900 o C and austempering temperature at 270 o C and 370 o C. The austempering time was varied from half an hour, one hour and one and a half hour to determine the most suitable austempering time.
liv  To ascertain the suitable austenitizing temperature, the austempering temperature at 270 o C and 370 o C and austempering time for one hour was fixed. Austenitizing temperature of 850 o C, 900 o C and 925 o C was maintained for one hour to find out the best austenitizing temperature for these samples.  Addition of Copper Four heats were made to find out the effect of copper on the tensile strength of ductile iron. Copper content was varied from nil to 1.5 wt. %.  Addition of Nickel Different heats were produced to examine the effect of nickel on ductile iron. The melts were made with the addition of 1.0 wt. %, 2.0 wt. % and 3.0 wt. % of nickel.  Addition of a combination of Copper and Nickel Different melts with a combination of copper and nickel were made to examine the effect of both of alloying elements together.  Addition of Lanthanum Four melts were made for this purpose. One melt was made without lanthanum while three melts with varying compositions of lanthanum were made. Three aspects of the composition of lanthanum were investigated i.e. nodule count, nodularity and tensile strength with and without heat treatment. Different properties of ductile iron were studied taking into consideration the following:  Change of tensile strength with the change of austempering time.
lv  The change of tensile strength with the change of austenitizing temperature.  The change in nodule count and nodularity with the change in the amount of lanthanum.  The change of tensile strength with the change of austempering temperature in low and high temperature ranges.  The change of tensile strength with the change of lanthanum, copper and nickel content Limitations of Study Two major constraints were experienced during the experimental design stage. One was that the ferro-lanthanum alloying element was not available in the local market and the other was the non availability of relevant technical literature. The difficulties were overcome by conducting some of the experiments at the University of Birmingham, UK. Aim of Study The aim of the experimental work was to study the effects of copper, nickel, a combination of copper and nickel and lanthanum and to study the heat treatment variables (time and temperature) on ductile iron. For this purposes ductile iron castings were produced with and without copper, nickel, a combination of copper and nickel and lanthanum. The results were compared to find out the best austempering time, austenitization temperature and the percentage of alloying addition to get the maximum tensile strength.
lvi 3.1 PRODUCTION OF DUCTILE IRON 3.1.1 Ductile Iron without and with Copper, Nickel and Copper- Nickel Together Ductile iron was made using local materials and local facilities. The melting was carried out in a commercial electro-induction foundry furnace. The materials used were pig iron from Pakistan Steel, mild steel from the local market and ductile iron returns of the foundry. In order to get the required composition, ferro-alloys were added to the melt. After melting, the metal was poured into a ladle with two pockets at the bottom. In one pocket ferro-silicon-magnesium alloy and inoculant ( ferro-silicon) were placed while the other was kept empty. The following raw materials for the production of ductile iron were used. Pig Iron Pig iron from Pakistan Steel was used for making ductile iron. The composition of the iron is given in table 3.1 Table 3.1 Chemical Composition of Pig iron in wt % C Si Mn P S Fe 4.1 0.83 0.6 0.025 0.021 Balance Mild Steel Mild steel with the following composition mentioned in table 3.2 was used. Table 3.2 Chemical Composition of Mild Steel in wt % C Si Mn Fe 0.2 0.3 0.4 Balance
lvii Ferro-silicon-magnesium Ferro-silicon-magnesium used for the spheroidization with the composition shown in table 3.3. Table 3.3 Chemical Composition of Ferro-silicon-magnesium in wt % Si Mg Ca Al Fe 42 5.5 1.2 1.0 Balance The melt was poured from about 1450 o C into a standard Y block sand mould. Tensile specimens of 15 mm diameter 250 mm long were machined from the castings. Chemical Composition of Heats Produced  The chemical analysis of ductile iron produced without and with copper addition is mentioned in the table 3.4. Four heats were made to find out the effect of copper on ductile iron. The details of heats are as follows: Heat No. C0 without any copper Heat No. C10 with 1.0 % copper Heat No. C5 with 0.5 % copper Heat No. C15 with 1.5 % copper Table 3.4 Chemical Composition of Ductile Iron Produced with copper in wt % Elements Heat No C0 Heat No C5 Heat No C10 Heat No C15 C 3.6 3.5 3.7 3.9 Si 2.7 2.9 2.6 2.7 Mn 0.1 0.2 0.1 0.2 Cu 0.0 0.5 1.0 1.5 S 0.07 0.09 0.08 0.09 P 0.02 0.03 0.02 0.02
lviii  The chemical analysis of ductile iron produced without nickel and with nickel addition is mentioned in the table 3.5. The details of heats prepared to find out the effect of nickel are mentioned below: Heat No. N0 without any nickel Heat No. N1 with 1.0 % nickel Heat No. N2 with 2.0 % nickel Heat No. N3 with 3.0 % nickel Table 3.5 Chemical Composition of Ductile Iron Produced with Nickel in wt % Elements Heat No N0 Heat No N1 Heat No N2 Heat No N3 C 3.6 3.7 3.7 3.8 Si 2.7 2.8 2.7 2.7 Mn 0.1 0.2 0.2 0.2 Nickel 0.0 1.0 2.0 3.0 S 0.08 0.09 0.08 0.08 P 0.02 0.02 0.02 0.02  The chemical analysis of ductile iron produced without and with a combination of copper and nickel contents is mentioned in the table 3.6. The details of heats prepared to find out the effect of copper and nickel together are mentioned below: Heat No. CN0 without any copper and nickel Heat No. CN1 with 0.5 wt % copper and 1.0 wt.% nickel Heat No. CN2 with 1.0 wt. % copper and 2.0 wt.% nickel Heat No. CN3 with 1.5 wt. % copper and 3.0 wt. % nickel
lix Table 3.6 Chemical Composition of Ductile Iron Produced with Copper & Nickel Together in wt %. Elements Heat No CN0 Heat No CN1 Heat No CN2 Heat No CN3 C 3.8 3.7 3.6 3.8 Si 2.9 2.7 2.8 2.9 Mn 0.2 0.1 0.1 0.2 Nickel 0.0 1.0 2.0 3.0 Copper 0.0 0.5 1.0 1.5 S 0.07 0.09 0.08 0.08 P 0.03 0.02 0.02 0.02 3.1.2 Ductile Iron Prepared without Lanthanum Ductile iron samples were prepared at the University of Birmingham, U K. The furnace used was medium frequency induction furnace of capacity 28 kg. The material used was sorel metal, mild steel and ferroalloys. The investigation for optimum austempering time and austenitizing temperature was carried out on the samples of this melt. The composition of ductile iron produced is given in the table 3.7. Table 3.7 Chemical Composition of Ductile Iron in wt. % C Si Ni S P Mg 3.5% 2.5% 0.019% 0.05% 0.005% 0.05% 3.1.3 Ductile Iron Produced with Lanthanum Four melts were made with and without the addition of lanthanum i.e. 0.00 wt.%, 0.006 wt.%, 0.02 wt.% and 0.03 wt.% at the University of Birmingham, UK. For
lx this purpose, the following charge materials were used. A good quality of charge was selected for the melting. The composition of the charge was as follows: Sorel Metal Sorel Metal of Grade RTF 10 was used. The composition is given the table 3.8. Table 3.8 Chemical Composition of Sorel Metal in wt. % C Si Mn S P 4.33 0.134 0.014 0.005% 0.017 Ferro-silicon 75(Base) Ferro-silicon with 75 wt. % of silicon was used. Ferro-silicon-magnesium Ferro-silicon-magnesium with Si = 45.45 wt.% and Mg =4.72wt.% was used for graphitization Swedish Iron Swedish iron was used for the production of ductile iron . The composition of the iron is given the table 3.9 Table 3.9 Chemical Composition of Swedish Iron in wt. % C Si Mn S P 0.01 0.03 0.18 0.004 0.011
lxi 3.1.4 Moulding Method A vertically-parted sand mould was used. Fig.3.1 [36] shows the dimension of the mould. The mould constituted three parts, a pouring basin, a runner and a series of ten test bar cavities. Ten cavities were used for the castings. The sand moulds were made from local silica sand from Kings Lynn AFS grade 60 bonded with Ashland pepset resin. For making the mould, silica sand with pepset 1505 with catalyst pepset 2590 were used. The pattern was sprayed with silicon-free release agent, from Blayson company, for easy removal of mould. Fig.3.1 16mm diameter test bar mould (Dimension in mm)
lxii 3.1.5 Melting Technique The charge materials were melted in INDUCTOTHERM medium frequency Induction furnace of 28 kg capacity for making melts with and without lanthanum. To achieve a good and reliable result, care was taken to maintain a good melting practice throughout the experimental work. In each experiment 24 kg melt was used. Ductile iron samples alloyed with copper, nickel and copper & nickel together were produced from a 100 kg high frequency induction furnace installed at a commercial foundry. 3.1.6 Spheroidizing Treatment The Sandwich method was employed for spheroidizing. After melting, the metal was poured into a ladle with two pockets at the bottom. In one pocket ferro- silicon 75 (base) and ferro-silicon- magnesium were placed while the other pocket was kept empty. The alloys were covered with 1/8 inches thick plate to delay the reaction and to avoid vaporization of alloying elements. 3.1.7 Inoculant Ferro-silicon inoculant was used for the production of ductile iron samples alloyed with copper, nickel and a combination of copper and nickel. The ductile iron samples were inoculated for melts alloyed with lanthanum by traditional ladle inoculation method. The inoculant was added to the metal as it was transferred from the furnace to the pouring ladle. The turbulence quickly dissolved the inoculant. For the first three melts ferro-silicon was used as an inoculant. It proved to be unsuccessful in removing the carbides in the castings. Later, for the remaining four melts, it was replaced with super-seed.
lxiii 3.1.8 Chemical Analysis Standard coin samples were chilled cast for chemical analysis for every melt. The samples were taken from the middle of casting. The chemical analysis of samples of ductile iron is given in the table 3.10. Table 3.10 Chemical Analysis of Ductile Iron Alloyed with Lanthanum Elements Melt Number MELT 1 MELT 2 MELT 3 MELT 4 C 3.71 3.45 3.40 3.41 Si 2.45 2.75 2.63 2.68 Mn 0.111 0.105 0.107 0.106 P 0.016 0.022 0.021 0.022 S 0.008 0.006 0.008 0.008 Cr 0.027 0.028 0.026 0.028 Mo 0.002 0.001 0.001 0.001 Ni 0.029 0.028 0.029 0.029 Al 0.019 0.018 0.017 0.016 Cu 0.016 0.015 0.016 0.015 Mg 0.064 0.071 0.058 0.060 Sn 0.001 0.001 0.001 0.001 Ti 0.005 0.005 0.005 0.006 V 0.008 0.008 0.007 0.008 La 0.000 0.006 0.020 0.030 Fe Bal. Bal. Bal. Bal.
lxiv 3.1.9 Filtration of Ductile Iron The ductile iron produced at the University of Birmingham was filtered with a Sedex ceramic foam filter having 10 pores per inch to get slag free samples for the study. A ceramic filter was used for every melt to produce high quality ductile iron. It was placed at the bottom of the sprue, as shown in Figure 3.1. The dross (slag) is relatively high in ductile iron. Oxides are the principal constituents of slag/dross in cast iron and come from furnace refractories, ladle lining, moulds, and the oxidation of dissolved magnesium and silicon during the melting and pouring. The use of ceramic filter means that the running system can be used for its primary purpose of metal delivery to the cavity of the casting, whilst cleanliness is controlled by filter, to give inclusion-free casting and to improve yield [37]. 3.2 MICROSTRUCTURE Two samples from each melt were taken, one from the middle and the other from the bottom. These samples were sectioned from the test bars. Later these were mounted in thermoplastic and marked for identification. Conventional metallographic preparation techniques were used. The microstructural study was carried out using Leica optical microscope and Olympus microscope. The nodule count and nodularity of the samples was carried out using an image analyzer installed at the university of Birmingham, UK. 3.3 SALTS USED The salts used for austempering were purchased from the local market. Different companies are selling their salts with their own fabricated names.
lxv 3.4 EQUIPMENTS USED 3.4.1 Melting Furnaces Different furnaces were used for the melting of metal during the present work. These are listed below. 1. Gas Fired Furnace: The gas fired furnace of capacity 60 kg was used to produce the ductile iron for the initial heats. It was fitted with a blower. Natural gas was fed to the furnace for the melting of the metal. 2. Induction Furnaces: Two furnaces were used for the melting of iron. The Inductotherm medium frequency induction furnace of capacity 28 kg was used. It was installed at the University of Birmingham, UK. The second furnace was a high frequency induction furnace of capacity 100 kg installed at a commercial foundry, Lahore (Pakistan). 3.4.2 Heat Treatment Furnaces Different types of furnaces were used for the heat treatment of tensile samples. The majority of samples were heat treated at the University of Engineering and Technology, Lahore (Pakistan) and some of the samples were heat treated by ADI Treatment, UK. The details of furnaces are given below. Muffle Furnace The austenitizing heat treatment of the samples were carried out in a muffle furnace installed at Materials Research Laboratory, Research Centre University of Engineering and Technology, Lahore ( Pakistan ). The samples were austenitized in
lxvi Carbolite Furnace, Type GPC 13/36 with 9000 watts and its maximum temperature limit was 1300 o C . Vertical tube furnace The tensile samples were austempered in salt bath placed in a vertical furnace fitted at Research Centre of University of Engineering & Technology, Lahore (Pakistan). The samples were austempered in salt bath using Carbolite Furnace Type VCF 12/10 with 3000 watts and its maximum temperature limit was 1200o C. Quench Austempered Furnace The heat treatment of some of the tensile samples was carried out by ADI Treatment Ltd., UK as the heat treatment facilities were not available at the time of experimentation at the University Birmingham, UK. The ADI Treatment Ltd., were kind enough to carry out the heat treatment at their premises. The organization is ISO 9000: 2000 certified. It is equipped with most modern furnaces using controlled atmosphere belt. ADI Treatment Ltd. had installed the world‟s largest sealed quench austempering furnace facility which provides controlled atmosphere heat treatment. The patented design incorporated a controlled atmosphere bath with recirculating roof fans, radiant tubes, intermediate purge transfer chamber, and vestibule austempering quench tank. 3.4.3 Microscopes Used For microstructural study the following microscopes and image analyzer were used. Optical Microscopes Leica optical microscope was used for microstructural study which was installed at the University of Birmingham, UK. It was fitted with a camera. The second
lxvii microscope which was used was Olympus Inverted Metallurgical Microscope PME-3- 312B installed at the Research Centre of the University of Engineering and Technology, Lahore. The specimens for the microscope were prepared by using conventional method. For etching the samples 4 % nital was used. Scanning Electron Microscope Hitachi S-3000H scanning electron microscope was used for the microstructure study. The microscope is fitted at Research Centre of the University of Engineering & Technology, Lahore, (Pakistan) Image Analyzer To find out the nodularity and nodule count, the image analyzer was used fitted at Interdisciplinary of Research Centre, University of Birmingham, UK 3.4.4 Tensile Testing Machines The tensile samples alloyed with lanthanum were tested using Instron Universal Testing Machine Model 1195, capacity 100 kn, installed in the laboratory of Pakistan Quality & Standards Control Authority, Lahore. The machine uses interchangeable load cell to detect the load on the sample under test. The load is measured by an electrical sensing device which produces signals corresponding to load variations. The second tensile testing machine was Universal Tensile Testing Machine Shimadzu UH-F-500 KNA that was used for the testing of samples alloyed with copper, nickel and a combination of copper and nickel. This machine was installed at Civil Engineering Department of University of Engineering and Technology, Lahore.
lxviii Chapter - 4 RESULTS AND DISCUSSION Different variables have been studied during the present research. The first variable was the effect of austempering time on ductile iron. The second variable was the effect of austenitizing temperature on the ductile iron. The third major variable was the effect of alloying additions on the ductile iron. The alloying elements selected for this purpose were copper, nickel, a combination of copper and nickel and lanthanum. 4.1 EFFECT OF AUSTEMPERING TIME ON DUCTILE IRON To find out the effect of time on austempering time on tensile strength of ductile iron temperature, the tensile samples were austenitized at 900o C for one hour and then austempered at 270o C and 370o C for three different length of time i.e. half an hour, one hour and one and a half hours. The results are shown in Table 4.1. It can be seen from the table 4.1 that the average tensile strength was 968.9 N/mm2 , when the samples were austenitized at 900o C and austempered for ½ hour at 270o C but it became 1360.9 N/mm2 when the time was increased from half an hour to one hour. When the austempering time was further increased to 1 ½ hour, it was revealed that the tensile strength was decreased to 1312.3 N/mm2 at the same austempering temperature i.e. 270o C. However, the tensile strength of the samples which were austentized at 900o C and austempered for ½ hour at a temperature of 370o C was 811.8 N/mm2 . This value increased to 925.2 N/mm2 when the sample was autenitized at 900o C
lxix and the austempered at 370 o C for 1 hour. The austempering time was increased to 1 ½ hour. The tensile strength again decreased to 817.5 N/mm2 . Table 4.1: Effect of Time on the Tensile Strength of Ductile Iron No. Austenitizing Temp. o C Austempering Temp. o C Austempering Time (Hours) Elog. % UTS N/mm2 1 2 3 900 900 900 270 270 270 ½ 1 1 1/2 1.2 1.3 1.2 968.9 1360.9 1312.3 4 5 6 900 900 900 370 370 370 ½ 1 1 1/2 2.5 2.7 2.6 811.8 925.2 817.5 5 Without any treatment 4.0% 696.4 Figure 4.1 Effect of time on tensile strength of ductile iron austenitized at 900o C and austempered at 270o C.
lxx Figure 4.2 Effect of time on tensile strength of ductile iron austenitized at 900o C and austempered at 370o C. Figures 4.1 and 4.2 show that there was a gradual increase of tensile strengths when the samples were autenitized at 900o C and austempered at 270o C and 370o C. Tensile strength went on increasing up to one hour austempering time in both the cases. The tensile strength decreased when austempering time was further increased. The effect of time on austempering was studied by changing the time duration of austempering while other parameters i.e. austenitizing temperature was fixed at 900 o C and austempering temperatures were fixed at 270 o C and 370 o C. The austempering time was changed from half an hour to one and a half hour. The tensile strength went on increasing up to one hour but decreased at 1½ hour. It was observed that the optimum time for austempering was one hour. The second stage started after the austempering time was longer than one hour. In this stage, high carbon austenite decomposed to ferrite and carbide.
lxxi It was also pointed out by Y. Lin [38] that after completing the first stage, the microstructure of matrix in austempered ductile iron (ADI) contains acicular ferrite and carbon rich austenite, giving ADI the outstanding mechanical properties of high strength and good ductility. If the isothermal holding time is long enough to permit the reaction to reach the second stage, the carbon rich austenite will decompose into ferrite and carbide. Therefore, the austempering holding time should be controlled at the completion of the first stage and the reaction of second stage should be avoided [38-40]. The two temperatures selected for austempering were 270 o C and 370 o C. The tensile strength was 1360.9 N/mm2 when the samples were austenetized at 900 o C and austempered at 270 o C for one hour but it decreased to 925.2 N/mm2 when these were austempered at 370 o C for one hour. The main reason of this change in value was the formation of upper and lower bainite. Whenever the isothermal transformation of ductile cast iron takes place, a two- stage transformation is involved. In the first stage, austenite decomposes into ferrite and high carbon austenite. In the second stage, this high carbon austenite decomposes into ferrite and carbide. The formation of carbides is detrimental to mechanical properties, so it should be avoided. The second stage also embrittles the material which affects the mechanical properties. The second stage occurs due to long austempering time. Therefore the time should be optimum. This is the reason for keeping austempering time as the first variable to be studied in this study.
lxxii 4.2 EFFECT OF AUSTENITIZING TEMPERATURE ON DUCTILE IRON The samples prepared at the University Birmingham, UK, were subjected to different austenitizing temperatures to find out the best austenitizing temperature. The temperature ranged from 850 o C to 925 o C for a fixed austempering time i.e. one hour . The samples were then austempered at 270 o C and 370 o C for one hour which was found to be the optimum austempering time according to the findings of the effect of time on austempering. The results are shown in table 4.2. Table 4.2 Effect of Austenitizing Temperature on Tensile Strength of Ductile Iron Sample No Austenitizing Temperatures C Austempering Temperatures C Tensile Strength N/mm2 1 850 270 1142.47 2 900 270 1313.32 3 925 270 1205.95 4 850 370 991.19 5 900 370 1117.84 6 925 370 1010.46 The samples were austenitized for one hour at 850 o C and austempered at 270 o C the tensile strength was 1142.47 N/mm2 . When the austenitizing temperature was increased to 900 o C the tensile strength increased to 1313.32 N/mm2 and on further increasing the austenitizing temperature to 925o C, the tensile strength decreased to 1205.95 N/mm 2 .
lxxiii Afterwards, austenitizing temperatures were kept the same i.e. 850 o C, 900 o C and 950 o C but the austempering temperature was increased to the upper limit temperature i.e. 370 o C to find out its effect on the tensile strength. The tensile strength showed the same pattern as in the previous experiment. When the samples were austempered at temperature 850 o C and austempered at 370o C their tensile strength was 991.19 N/mm2 ; when the austenitizing temperature was increased to 900 o C, the tensile strength increased to 1117.84 N/mm2 , but it decreased to 1010.46 N/mm2 by austenitizing at 925o C. Figure 4.3 Effect of austenitizing temperature on the tensile strength of ductile iron austempered at 270o C.
lxxiv
lxxv Figure 4.4 Effect of austenitizing temperature on the tensile strength of ductile iron austempered at 370o C. Figure 4.3 and 4.4 show that there is a gradual increase of tensile strength upto 900o C (austenitizing temperature) i.e. 1313.3 and 1117.8 N/sq-mm when the samples were austempered at 270o C and 370o C respectively. When austenitizing temperature was increased to 925o C and austempered at 270o C and 370o C the values decreased to 1205.9 and 1010.4 N/sq-mm respectively. It was observed that the higher austenitizing temperatures are not good for austempering. J R Keough [16] also pointed out that higher austenitizing temperature made transformation problematic during austempering and reduced mechanical properties after austempering. Similarly P. Shanmugan [41] found that lower austenitizing temperatures are better for fatigue strength. Susal K. et al. [42] also investigated the influence of
lxxvi austenitizing temperature on ductile iron. They found that yield strength went on increasing up to 898 o C and the strength decreased at 927 o C. They found that the yield strength was 1228.7 MPa when the samples were austenitized at 871 o C and austempered at 302 o C. When the temperature was increased to 898 o C, the yield strength increased to 1246.6 MPa .But when the austentizing temperature was further increased to 927 o C the yield strength decreased to1195.5 MPa under the same condition. The findings of the present study are supported by the experiments conducted by P.Shanmugan and Susal K.et al. 4.3 EFFECT OF ALLOYING ELEMENTS ON DUCTILE IRON Alloying additions are used for different purposes but mainly to increase mechanical properties especially to increase hardenability. Several alloying elements are used. Molybdenum is effective in increasing the hardenability [43]. There are some disadvantages in the use of larger molybdenum addition; these are relatively high cost and effect of this element also reduces ductility [44-46]. Manganese is a relatively cheap element but it tends to segregate in cast irons during solidification and additions exceeding 0.3 wt.% to austempered nodular irons reduce ductility as a result of embrittlement at cell boundaries [47]. However, Molybdenum has relatively small carbide- stabilizing effect and causes a large increase in hardenability, so it has been studied by several researchers [48-50]. In order to make austempered ductile iron with the required strength and ductility, alloying elements can be added to conventional ductile iron. These elements must play roles to avoid pearlite formation as well as stabilize austenite during austempering treatment. In that way ductile irons can produce a supersaturated austenite
lxxvii and therefore ausferrite phase can be achieved [51]. Molybdenum plays a significant role in increasing the hardenability of ductile iron [52]. A combination of nickel, copper and molybdenum was typically added to ductile iron [53-56]. 4.3.1 Effect of Copper on the Tensile Strength of Ductile Iron To find out effect of copper, four heats were made with 0.0 wt. %, 0.5 wt %, 1.0 wt. % and 1.5 wt. % by wt. in a commercial foundry. The tensile samples were machined from the castings. The samples were austenitized in a Carbolite muffle furnace at a temperature of 900 C for one hour and austempered at 270 o C and 370 o C for one hour. Then the tensile test was performed. The results are tabulated in table 4.3. Table 4.3 Effect of Copper on Tensile Strength of Ductile Iron Copper UTS N/mm2 0.0 wt % UTS N/mm2 0.5 wt % UTS N/mm2 1.0 wt % UTS N/mm2 1.5 wt % Without heat- treatment 495.3 517.6 581.7 705.7 Austempered at 270 o C 938.8 988.8 1096.1 1222.4 Austempered at 370 o C 698.0 816.7 828.3 911.6 The tensile strength of ductile iron samples was 495.3 N/mm2 without any addition of copper to the heat. When copper addition of 0.5 wt % was made in the ductile iron, the tensile strength increased to 517.6 N/mm2 . With the copper addition of 1.0 wt %, the tensile strength increased to 581.7 N/mm2 . When the copper addition was further
lxxviii increased to 1.5 wt %, the tensile strength again increased to 705.7 N/mm2 . Figure 4.5 shows the gradual increase of tensile strength with the increase of copper content without any heat treatment. The samples were then austenitized at 900 o C for one hour and austempered at 270 o C. The tensile strength of ductile iron samples was 938.8 N/mm2 without any addition of copper to the melt. With the copper addition of 0.5 wt % in the ductile iron the tensile strength increased to 988.8 N/mm2 . When the copper addition was increased to 1.0 wt %, the tensile strength was increased to 1096.1 N/mm2 . When the copper addition was further increased to 1.5 wt %, the tensile strength was also increased to 1222.4 N/mm2 . Now the austempering temperature was increased. After austenitizing at 900 o C for one hour, the samples were transferred quickly to salt bath maintained at 370 o C for a time period of one hour. The tensile strength of ductile iron samples was 698.0 N/mm2 without any addition of copper. With the copper addition of 0.5 wt % in the ductile iron the tensile strength increased to 816.7 N/mm2 . The copper addition was further increased to 1.0 wt %, the tensile strength also increased to 828.3 N/mm2 . When the copper addition was increased to 1.5 wt %, the tensile strength increased to 911.6 N/mm2 . (table 4.3). The graphical representation of increase of tensile strength when the samples were austempered at 370o C is shown in figure 4.6.
lxxix Fig. 4.5 Effect of copper on tensile strength without any heat treatment Figure 4.6 shows a similar increase of tensile strength with the increase of copper when the samples were austempered at 270 o C for one hour. Fig. 4.6 Effect of copper on tensile strength when austenitized at 900 o C and austempered at 270 o C.
lxxx Figure 4.7 shows the same pattern of increase of tensile strength when the samples were austenitized at 900 o C for one hour and austempered at 370 o C for one hour. Fig. 4.7 Effect of copper on tensile strength when austenitized at 900 o C and austempered at 370 o C for one hour. The present results are similar to the research conducted by Yoon-Jun Kim et al, [51]. In their study, the samples were alloyed with copper and molybdenum and austenitized at 910 o C for 90 minutes and subsequently austempered in salt bath. They found that copper and molybdenum addition played an effective role in the formation of ausferrite structure as well as an increment of mechanical properties such as tensile strength and hardeability. Another study by A.A. Cushway [43] revealed that copper addition up to 1.5 wt. percent increased the hardenability of nodular iron. He further found that the addition of copper above 1.5 percent resulted in no further increase in hardenability. In the present study the tensile strength also went on increasing up to 1.5 wt. percent of copper addition.
lxxxi Guerin et al [57] made alloying addition of copper, tin and a combination of manganese and copper to ductile iron. They found that the use of manganese (% Mn > 0.4 %) or tin (% Sn > 0.07 %) caused the formation of embritlling intercellular phases. The best mechanical properties were obtained with 1.48 wt. per cent of copper. They further found that manganese and tin were less effective than copper to harden and strengthen ductile iron. P.W. Sheton and A. A. Bonner [58] reported that when copper was added in quantities exceeding the limits of solid solubility in ferrous alloys (0.7 wt. %) it significantly improved its strength and toughness. These results are in agreement with the present study. 4.3.2 Effect of Nickel on Tensile Strength of Ductile Iron The effect of nickel on ductile iron was studied by preparing different heats with 1.0 wt.%, 2.0 wt.% and 3.0 wt. % nickel addition. The tensile samples were made from the castings made by the Y block pattern. Then these tensile samples were subjected to tensile test with and without heat treatment. The test results are tabulated in the table 4.4. Table 4.4 Effect of Nickel on Tensile Strength of Ductile Iron Nickel UTS N/ mm2 0.0 wt. % UTS N/ mm2 1.0 wt. % UTS N/ mm2 2.0 wt. % UTS N/ mm2 3.0 wt. % Without heat- treatment 495.3 552.4 575.3 628.2 Austempered at 270 C 938.8 970.5 979.7 1082.5 Austempered at 370 C 698.0 721.18 732.8 917.7
lxxxii The present results showed that there is a gradual increase in the tensile strength of ductile iron with the increase of nickel content without heat treatment. The tensile strength was 495.3 N/mm2 without any addition of nickel. By adding of 1.0 wt.% of nickel, the tensile strength increased to 552.4 N/mm2 (table 4.4). When 2.0 wt % nickel was added in the ductile iron, the tensile strength increased to 575.3 N/ mm2 . Further increasing of nickel content to 3.0 wt %, the tensile strength also increased to 628.2 N/mm2 . The ductile iron samples were then heat treated by austenitizing the samples at 900o C for one hour and austempered at 270 o C for one hour. The tensile strength of ductile iron samples was 938.8 N/ mm2 without any addition of nickel to the melt. With the nickel addition of 1.0 wt. % in the ductile iron, the tensile strength increased to 970.5 N/ mm2 . When the quantity of nickel was increased to 2.0 wt % in the ductile iron, the tensile strength again increased to 979.7 N/ mm2 . When the nickel addition was further increased to 3.0 wt. %, the tensile strength again increased to 1082.5 N/mm2 (table 4.4). Now the salt bath temperature was increased to 370 o C for austempering. After austenitizing at 900 o C for one hour, the samples were austempered for one hour. The tensile strength of ductile iron samples was 698.0 N/ mm2 without any addition of nickel. With the nickel addition of 1.0 wt % in the ductile iron the tensile strength increased to 721.1 N/ mm2 . When the 2.0 wt % nickel was added to the ductile iron, the tensile strength also increased to 732.8 N/ mm2 . When the nickel addition was further increased
lxxxiii to 3.0 wt. %, the tensile strength again showed the similar tendency and it increased to 917.7 N/ mm2 (table 4.4). The effect of nickel was studied by making melts with nil to 3 wt. % nickel. The addition of varying quantities of nickel to the ductile iron showed a positive effect of mechanical properties of ductile iron by increasing its tensile strength in a proportionate manner. The graphs shown in figures 4.8, 4.9 and 4.10 revealed the gradual increase of tensile strength with the increase of nickel content with and without any heat treatment. Figure 4.8 shows that with the increase of nickel quantity the tensile strength increased without any heat treatment. Fig. 4.8 Effect of nickel on tensile strength without any heat treatment When the samples are austenitized at 900 o C and austempered at 270 o C, the increase in tensile strength can be seen in figure 4.9.
lxxxiv Fig. 4.9 Effect of nickel on tensile strength when austenitized at 900 o C and austempered at 270 o C When the tensile samples were austenitized at 900 o C and austempered at 370o C, the tensile strength again increased. The slope in figure 4.10 is not as steep as in case of austempering at 270 o C in figure 4.9. Fig. 4.10 Effect of nickel on tensile strength when austenitized at 900 o C and austempered at 370 o C
lxxxv Cheng-Hsun Hsu et al [59] studied the mechanical properties of cobalt and nickel alloyed ductile irons. They found that the highest strength was achieved with the addition of 4.0 % nickel. They found that the tensile strength of unalloyed ductile iron was 463 MPa but when the ductile iron was alloyed with 4. 0 wt % nickel the tensile strength increased to 1025 MPa. In the present study, the highest strength of ductile iron produced in a commercial foundry using local raw materials without any heat treatment was 495.3 N/mm2 and with 3.0 wt % nickel, it increased to 628.2 N/ mm2 .There is tendency of increasing tensile strength in all the samples. The author could make nickel addition up to 3.0 wt. % only due to financial constraints. Both copper and nickel are austenite stabilizers, so they widen the austenite zone of phase diagram. As both copper and nickel are austenite stabilizers. Both copper and nickel move the nose of isothermal diagram to right, and make the transformation even easier as the cooling rate is lower. Both copper and nickel increase the hardenability; however the information of these two elements on the mechanical properties is limited. 4.3.3 Effect of a combination of Copper and Nickel on Ductile Iron In this study, ductile iron was alloyed in different combinations of copper and nickel. Three melts of ductile iron were made as given below 1. 0.5wt% copper and 1.0wt% nickel
lxxxvi 2. 1.0wt% copper and 2.0wt% nickel 3. 1.5wt% copper and 3.0wt% nickel. The tensile strength was compared with unalloyed ductile iron. The test results of tensile strength of unalloyed ductile iron and alloyed ductile iron with copper and nickel together without heat treatment and with heat treatment are shown the table 4.5 Table 4.5 Effect of Copper and Nickel together on Tensile Strength of Ductile Iron Copper Nickel UTS N/ mm2 0.0 wt % 0.0 wt % UTS N/ mm2 0.5 wt % 1.0 wt % UTS N/ mm2 1.0 wt % 2.0 wt % UTS N/ mm2 1.5 wt % 3.0 wt % Without heat- treatment 495.3 544.0 552.7 576.8 Austempered at 270 o C 938.8 1034.3 1055.3 1164.1 Austempered at 370 o C 698.0 715.7 738.7 787.3 The tensile strength of ductile iron samples without any addition of copper and nickel was 495.3 N/mm2 (without any heat treatment). When copper addition of 0.5 wt % along with 1.0 wt % nickel was made in the ductile iron the tensile strength increased to 544.4 N/mm2 . With the copper addition of 1.0 wt% and nickel 2.0 wt % in the ductile iron, the tensile strength increased to 552.7 N/mm2 . When the copper addition was further increased to 1.5 wt % in combination of 3.0 wt %nickel, the tensile strength again increased to 576.8 N/mm2 , (table 4.5).
lxxxvii The samples were then austenitized at 900 o C for one hour and austempered at 270 o C. The tensile strength of ductile iron samples was 938.8 N/mm2 without any addition of copper and nickel to the melt. With the copper addition of 0.5 wt % in combination of 1.0 wt % nickel in the ductile iron the tensile strength increased to 1034.3 N/mm2 , (table 4.5). When the copper addition was increased to 1.0 wt % with 2.0 wt % nickel in the ductile iron, the tensile strength increased slightly to 1055.3 N/mm2 . The copper addition was further increased to 1.5 wt % in combination of 3.0 wt %, the tensile strength showed a similar pattern and it increased to 1164.1 N/mm2 . When the samples were austenitized at 900 o C for one hour and the austempering temperature was increased to 370 o C, the tensile strength of ductile iron samples was 698.0 N/mm2 without any addition of copper and nickel. With the copper addition of 0.5wt % and 1.0 wt % nickel in the ductile iron the tensile strength increased to 715.7 N/mm2 . When the copper addition was further increased to 1.0 wt % along with 2.0 wt % nickel in the ductile iron, the tensile strength also increased to 738.7 N/mm2 . When the copper addition was further increased to 1.5 wt % in combination of 3.0 wt nickel, the tensile strength again increased to 787.3 N/mm2 (table 4.5). The samples with different combinations of copper and nickel were austenitized at 900 o C and austempered at 270 o C and 370 o C. The results showed the same pattern as with copper and nickel addition separately but there was not a significant increase in the tensile strength in combination of copper and nickel.
lxxxviii Fig. 4.11 Effect of copper and nickel without heat treatment. Figure 4.12 Effect of copper and nickel together on tensile strength of ductile iron when austenitized at 900 o C and austempered at 270 o C.
lxxxix Fig. 4.13 Effect of copper and nickel on tensile strength when austenitized at 900o C and austempered at 370 o C The above figures 4.11-4.13 show the gradual increase in tensile strength with the increase of a combined effect of copper and nickel. To achieve a good hardenabilty and tensile strength it is advisable to use comparatively cheap alloying addition i.e. copper rather using an expensive nickel alloy. Both copper and nickel can be used to increase the hardenability of ductile iron. More information on the effect of addition of copper or nickel is limited [43]. 4.3.4 Effect of Lanthanum on Ductile Iron Lanthanum and other rare earth metals (REM) have been utilized in molten metal processing in a number of ways. For ductile iron production, rare earth metals have been used to modify cast iron eutectic structures. In addition to use REM to neutralize
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ADI JU

  • 1. i EFFECTS OF HEAT TREATMENT AND ALLOYING ELEMENTS ON CHARACTERISTICS OF AUSTEMPERED DUCTILE IRON Submitted By:
  • 2. ii MUHAMMAD ASHRAF SHEIKH 2001-PhD-Met-02 Department of Metallurgical and Materials Engineering UNIVERSITY OF ENGINEERING AND TECHNOLOGY LAHORE – PAKISTAN 2008
  • 3. iii EFFECTS OF HEAT TREATMENT AND ALLOYING ELEMENTS ON CHARACTERISTICS OF AUSTEMPERED DUCTILE IRON A thesis submitted to the University of Engineering and Technology, Lahore as a partial fulfillment for the degree of Doctor of Philosophy in Metallurgical and Materials Engineering Approved on ___12-01-2008____ Internal Examiner: Signature: _______________________ (Supervisor) Name: Professor Dr Javed Iqbal External Examiner: Signature:________________________ Name: Professor Dr M. Saleem Shuja Rector, University of Lahore. Chairman of the Department: Signature: ________________________ Name: Prof. Qasim Hassan Zaidi Dean - Faculty of Chemical Signature: ________________________ Min. & Met. Engg. Name: Prof. Dr. Faiz ul Hasan Department of Metallurgical and Materials Engineering UNIVERSITY OF ENGINEERING AND TECHNOLOGY
  • 5. v This thesis was evaluated by the following Examiners: External Examiners: From Abroad: Dr. Ramin Raiszadeh, Metallurgy Department, Engineering School, Shahid Bahonar University Of Kerman Kerman, Iran. Dr. Derya Dispinar, Metallurgy and Materials Engineering, University of Istanbul, Turkey From Pakistan: Professor Dr. M. Saleem Shuja Rector, University of Lahore. Internal Examiner: Professor Dr Javed Iqbal Department Metallurgical and Materials Engineering. University of Engineering and Technology, Lahore.
  • 6. vi “Glory to You: of knowledge we have none, save what You have taught us; in truth it is You Who are perfect in knowledge and wisdom.” (Al-Quran 2:32)
  • 8. viii ACKNOWLEDGEMENTS I am highly grateful to my supervisor, Professor Dr. Javed Iqbal for his guidance, encouragement and supervision given throughout this work. I feel great obligation to Professor Dr. John Campbell, Head IRC Department and Dr. T. U. Din, Research Associate University of Birmingham, UK for giving me permission to do my experimental work in the department, for their co-operation and valuable guidance. My special thanks to Lt. General (R) Muhammad Akram Khan, the Vice Chancellor, University of Engineering and Technology, Lahore, for his continued support and encouragement throughout this research work. I also wish to acknowledge the financial support of the Higher Education Commission, Islamabad. I am also grateful to the Director General Research, Dr. K. E. Durrani, Dean, Professor Dr. Faiz ul Hasan, Chairman, Prof. Qasim Hassan Zaidi, Director Post Graduate Studies, Prof. Dr. M. Ajmal Chishti for their help and cooperation during my research work. I would like to acknowledge the support of Mr. Munir Ahmad, M.D. and Mr. Izhar Ahmad of Pakistan Standards and Quality Control Authority, Lahore, Dr. Shahzad Alam and Mr. Junaid of PCSIR Laboratories, Lahore and Mr. M. Sadiq Qureshi of Flames International for helping me in testing of the samples. My sincere thanks and appreciation are also due to M/S ADI Treatments, U.K. for the heat treatment of some of the samples. I would like to thank Mr. Adrian and Mr. Michael of Casting Research Group, University of Birmingham , UK and Mr. Rashid Ahmad of Star Agro Engineering & Foundry, Lahore; for making the melts and Mr. Furqan Ahmad & Mr. Asif Rafiq of University of Engineering & Technology, Lahore for their help in metallography. I would like to acknowledge the assistance of Mr. Muhammad Saeed, Mr. Manzoor Ahmad and Mrs Azra Haroon of University of Engineering & Technology, Lahore. I wish to thank all my colleagues and staff of various laboratories for their help specially Mr. Shahzad Ali and Mr. Abdul Qayyum for their assistance. Finally I take this opportunity to express my gratitude to my family, specially my wife for her encouragement and support. M. ASHRAF SHEIKH
  • 9. ix ABSTRACT The effect of three variables on ductile iron has been investigated in this study. The first variable was the effect of austempering time on ductile iron. The second variable was the effect of austenitizing temperature and the third major variable was the effect of alloying additions on ductile iron. The alloying elements selected for this purpose were copper, nickel, a combination of copper and nickel and lanthanum. The initial study was conducted on unalloyed ductile iron castings. The effect of austempering time was examined by varying austempering time in the range of 30 minutes to 90 minutes, while keeping austenitization temperature and austempering temperature constant. It was found that with the increase of austempering time, the tensile strength increased significantly. However, at 90 minutes the tensile strength decreased. The optimum temperature was found to be 60 minutes. The second variable was the effect of austenitization temperature on ductile iron. Based on the result of the first experiment, the austempering was carried out for 90 minutes. The austempering temperatures were kept at 270 o C and 370 o C. The austenitization temperature was varied from 850 o C to 925 o C. The study revealed that tensile strength increased at 900 o C but it decreased at 925o C. The third major variable involving the effect of alloying additions on ductile iron, was studied by adding copper with three different values i.e. 0.5 wt. %, 1.0 wt. % and 1.5 wt. %. The fourth melt was without the addition of copper. It was found that with the increase of copper the tensile strength continued to increase up to 1.5 wt. %. The second alloying addition was nickel. One melt was made without nickel while the remaining three melts were made with the addition of 1.0 wt. %, 2.0 wt. % and 3.0%
  • 10. x nickel. The tensile strength increased correspondingly with the increase in the addition of nickel to 3.0 wt. %. The effect of a combination of copper and nickel on ductile iron was also examined. The effect of the last alloying element which was studied was lanthanum. Four melts were made for this study. The first melt was without the addition of lanthanum while the remaining three had 0.006 wt.%, 0.02 wt.% and 0.03 wt.% lanthanum. The results indicated that the tensile strength increased with the increase of lanthanum content with and without austempering. Furthermore, the highest nodule count was obtained with 0.03 wt.% lanthanum while the nodularity remained almost unchanged. Thus, it was observed that the addition of alloying elements results in an increase of tensile strength. The optimum austempering time was 90 minutes and the optimum austenitizing temperature was found to be 900 o C.
  • 11. xi TABLE OF CONTENTS Description Page Acknowledgement Abstract Table of Contents List of tables List of figures Chapter–1 INTRODUCTION 1 Chapter–2 LITERATURE REVIEW 2 2.1 Ductile Iron 4 2.1.1 History of Ductile Iron 4 2.1.2 Production of Ductile Iron 5 2.1.2.1 Raw Materials 5 2.1.2.2 Control of the Composition of Ductile Iron 5 2.1.2.3 Charge Materials 8 2.1.2.4 Desulphurization 9 2.1.2.5 Spheroidizing Treatment Alloys 10 2.1.2.6 Melting Techniques for the Production of Ductile Iron 10 2.1.2.7 Spheroidizing Treatment 11 2.1.2.8 Amount of Magnesium Required 13 2.1.2.9 Inoculation 15 2.1.3 Formation of Carbides in Ductile Iron 17 2.1.4 Pouring 18 2.1.5 Importance of Ductile Iron 18 2.2 Austempered Ductile Iron (ADI) 20 2.2.1 Austempering 20 2.2.2 Introduction to Austempered Ductile Iron 20
  • 12. xii 2.2.3 Production of Austempered Ductile Iron 21 2.2.3.1 Composition of ADI 22 2.2.3.2 Effects of Alloying Elements 22 2.2.3.3 Production of Austempered Ductile Iron 27 2.2.3.4 Heat Treatment Considerations 29 2.2.4 Specifications of Austempered Ductile Iron 30 2.2.5 Cost Benefits of Austempered Ductile Iron 31 2.2.6 Properties Of Austempered Ductile Iron 32 2.2.7 Disadvantages of Austempered Ductile Iron 33 2.2.8 Application of Austempered Ductile Iron 33 Chapter–3 EXPERIMENTAL WORK 36 Research Methodology 36 3.1 Production of Ductile Iron 39 3.1.1 Ductile Iron without and with Copper, Nickel and Copper-Nickel Together 39 3.1.2 Ductile Iron Prepared without Lanthanum 42 3.1.3 Ductile Iron Produced with Lanthanum 42 3.1.4 Moulding Method 44 3.1.5 Melting Technique 45 3.1.6 Spheroidizing Treatment 45 3.1.7 Inoculant 45 3.1.8 Chemical Analysis 46 3.1.9 Filtration of Ductile Iron 47 3.2 Microstructure 47 3.3 Salts Used 47 3.4 Equipments Used 48 3.4.1 Melting Furnaces 48 3.4.2 Heat Treatment Furnaces 48 3.4.3 Microscopes Used 49 3.4.4 Tensile Testing Machines 50
  • 13. xiii Chapter – 4 RESULTS AND DISCUSSION 51 4.1 Effect of Austempering Time on Ductile Iron 51 4.2 Effect of Austenitizing Temperature on Ductile Iron 55 4.3 Effect of Alloying Elements on Ductile Iron 58 4.3.1 Effect of Copper on the Tensile Strength of Ductile Iron 59 4.3.2 Effect of Nickel on Tensile Strength of Ductile Iron 63 4.3.3 Effect of a combination of Copper and Nickel on Ductile Iron 67 4.3.4 Effect of Lanthanum on Ductile Iron 71 4.3.4.1 Effect of Lanthanum on Nodule Count and Nodularity of Ductile Iron 72 4.3.4.2 Effect of Heat treatment with Lanthanum on Tensile Strength 78 4.3.4.3 Effect of Heat treatment on Microstructure of Ductile Iron 81 Chapter-5 CONCLUSIONS 88 FUTURE WORK 90 REFERENCES 91 Appendix 1 The bismuth-cerium phase diagram 98 Appendix 2 The lanthanum-bismuth phase diagram 99
  • 14. xiv LIST OF TABLES Table No. Description Page 2.1 Composition of Grey Iron for Low Grade 3 2.2 Composition of Grey Iron for H igh Grade 3 2.3 Composition of Ferro-Silicon-Magnesium Alloy 10 2.4 Chemical Composition of Ni-base alloy Containing Magnesium in wt.% 12 2.5 Chemical Composition of Inoculants 16 2.6 Typical Composition of Ductile Iron for Austempered Ductile Iron 22 2.7 Composition of a Typical Alloy of Cerium 27 2.8 Austempered Ductile Iron ASTM A897-90 (ASTM 897 M-90) 30 2.9 British Standards Specification for ADI EN 1564:1997 31 3.1 Chemical Composition of Pig Iron in wt % 39 3.2 Chemical Composition of Mild Steel in wt % 39 3.3 Chemical Composition of Ferro-Silicon-Magnesium in wt % 40 3.4 Chemical Composition of Ductile Iron Produced with Copper in wt % 40 3.5 Chemical Composition of Ductile Iron Produced with nickel in wt % 41 3.6 Chemical Composition of Ductile Iron Produced with Copper & Nickel together in wt %. 42 3.7 Chemical Composition of Ductile Iron without Lanthanum in wt. % 42 3.8 Chemical Composition of Sorel Metal in wt. % 43 3.9 Chemical Composition of Swedish Iron in wt. % 43
  • 15. xv 3.10 Chemical Analysis of Ductile Iron Alloyed with Lanthanum 46 4.1 Effect of Time on the Tensile Strength of Ductile Iron 52 4.2 Effect of Austenitizing Temperature on Tensile Strength of Ductile Iron 55 4.3 Effect of Copper on Tensile Strength of Ductile Iron 59 4.4 Effect of Nickel on Tensile Strength of Ductile Iron 63 4.5 Effect of Copper and Nickel together on Tensile Strength of Ductile Iron 68 4.6 Effect of Lanthanum on Nodule count and Nodularity on Ductile Iron 73 4.7 Dimensions of the Tensile Specimen (mm) 78 4.8 Effect of Lanthanum on the Tensile Strength of Ductile Iron 79
  • 16. xvi LIST OF FIGURES Fig. No. Descriptions Page 2.1 Schematic diagram of a typical austempering heat treatment cycle 27 2.2 Schematic arrangement of the austempering process 29 3.1 Test bar mould (Dimension in mm) 44 4.1 Effect of time on tensile strength of ductile iron austenitized at 900o C and austempered at 270o C. 52 4.2 Effect of time on tensile strength of ductile iron austenitized at 900o C and austempered at 370o C. 53 4.3 Effect of austenitizing temperature on the tensile strength of ductile iron austempered at 270o C. 56 4.4 Effect of austenitizing temperature on the tensile strength of ductile iron austempered at 370o C. 57 4.5 Effect of copper on tensile strength without any heat treatment 61 4.6 Effect of copper on tensile strength when austenitized at 900o C and austempered at 270 o C. 61 4.7 Effect of copper on tensile strength when austenitized at 900 o C and austempered at 370 o C. 62 4.8 Effect of nickel on tensile strength without any heat treatment 65 4.9 Effect of nickel on tensile strength when austenitized at 900 o C and austempered at 270 o C 66 4.10 Effect of nickel on tensile strength when austenitized at 900 o C and austempered at 370 o C 66 4.11 Effect of copper and nickel without heat treatment. 70 4.12 Effect of copper and nickel together on tensile strength of ductile Iron when austenitized at 900 o C and austempered at 270 o C. 70 4.13 Effect of copper and nickel on tensile strength when austenitized at 900o C and austempered at 370 o C 71
  • 17. xvii 4.14 Effect of lanthanum on the nodule count of ductile iron 74 4.15 Micrographs of ductile iron with 0.00%, 0.006 %, 0.02 and 0.03 % Lanthanum 75 4.16 Effect of lanthanum on nodule count of ductile iron 76 4.17 Effect of lanthanum on nodularity of ductile iron 77 4.18 Schematic diagram of tensile test sample 78 4.19 Micrographs of ductile iron austenitized at 900o C and austempered at 370o C for one hour with (a) 0.0 % La (b) 0.006 % La (c) 0.02 % La (d) 0.03 % La. 82 4.20 Micrographs of ductile iron austenitized at 900o C and austempered at 270o C for one hour with (a) 0.0 % La (b) 0.006 % La (c) 0.02 % La (d) 0.03 % La. 83 4.21 SEM photograph of ductile iron austenitized at 900o C and austempered at 370o C 84 4.22 SEM photograph of ductile iron austenitized at 900o C and austempered at 370o C 84 4.23 SEM photograph of ductile iron austenitized at 900o C and austempered at 270o C 85
  • 18. xviii Chapter - 1 INTRODUCTION The increasing interest in energy saving has led to the development of lightweight materials to reduce the weight of existing materials without compromising their properties. In the automotive industries, attempts have been made to replace cast iron and steel components with aluminum and austempered ductile iron. Austempered ductile iron (ADI) is a ductile iron that has undergone a special isothermal heat treatment called austempering. Unlike conventional “as-cast” irons, its properties are achieved by specific heat treatment. Therefore, the only prerequisite for good ADI is a good quality ductile iron. ADI offers superior combination of properties because it can be cast, like any other member of the ductile iron family. It offers all production advantages of conventional ductile iron castings. Subsequently it is subjected to the austempering process to produce mechanical properties that are superior to conventional ductile iron, many cast and forged steels. The mechanical properties of ductile iron and austempered ductile iron (ADI) are determined by the metal matrix. In conventional ductile iron it is controlled by the mixture of pearlite and ferrite. However the properties of ADI are due to its unique matrix of acicular ferrite and carbon stabilized austenite called ausferrite.
  • 19. xix It is a well known that an appropriate amount of rare earth is often used in ductile iron production in order to counteract the deleterious effects of subversive elements, e.g. titanium, bismuth and others. It is believed that the rare earths combine chemically with the subversive elements to effectively remove them from the system although reactions between titanium and rare earths have not, as yet, been identified [1]. However, an excessive amount of rare earth elements is known to promote the formation of chunky graphite [2-4]. While doing a preliminary survey on the production of ductile iron in Pakistan, it was noticed that only a few foundries were producing ductile iron castings of a reasonably good quality. Austempered ductile iron, however, was not being produced at all in any foundry in Pakistan. Research in this area was also found to be limited to a couple of research papers on ADI. Realizing the importance of ADI and its use in automobile and in other sectors in western countries, this researcher thought it necessary to explore the production of ADI locally. ADI was therefore produced at laboratory scale in Pakistan using raw materials available locally. In the present work, the effect of alloying elements (copper, nickel, a combination of copper and nickel and lanthanum) as well as the effect of changing different parameters of heat treatment i.e. time and temperature on ductile iron were studied.
  • 20. xx CHAPTER - 2 LITERATURE REVIEW The term, cast iron, identifies a large family of ferrous alloys. Cast irons are primarily alloys of iron that contain more than 2.0 wt. % carbon. It also contains 1.0 to 3.0 wt. % silicon. The different properties of castings can be achieved by changing carbon content, silicon content, by alloying with various elements, and by varying melting, casting and heat treatment practice. Cast irons, as the name implies, are indeed to be cast to shape rather than formed in solid state. Cast irons have low melting temperatures and are very fluid when molten and have undergone slight to moderate shrinkage during solidification. However, cast irons have relatively low impact resistance and ductility, which limits their use. [5]. This must be taken into account when designing castings to withstand service stresses. Irons of the composition given below in table 2.1 and table 2.2 satisfy a low and high grade specification of grey cast iron in a medium size, uniform sections sand castings [6]. Table 2.1 (G 150) Composition of Grey Iron for Low Grade C % Si % Mn % S % P % 3.1-3.4 2.5-2.8 0.5-0.7 0.15 0.9 Table 2.2 (G 350) Composition of Grey Iron for High Grade C % Si % Mn % S % 3.1 max 1.4-1.6 0.6-0.75 0.12
  • 21. xxi The properties of flake iron depend on size, amount, distribution of graphite flakes and matrix structure. 2.1 DUCTILE IRON Ductile iron derives its name from the fact that, in the as-cast form, it exhibits measurable ductility. By contrast, neither white iron nor grey iron exhibits significant ductility in a standard tensile specimen [5]. Ductile iron is defined as a high carbon containing, iron-base alloy in which graphite is present in a compact, spheroidal shape [7]. Ductile iron is also known as nodular iron or spheroidal graphite iron. Unlike grey iron that contains graphite flakes; the ductile iron has as- cast structure containing graphite particles in the form of small rounded spheroidal nodules in the matrix. Therefore, ductile iron has much higher strength than grey iron and a considerable degree of ductility. 2.1.1 History of Ductile Iron Foundry men continued to search for an ideal cast iron an as cast “grey iron” with mechanical properties equal or superior to malleable iron. In 1943, Keith Dwight Mills made a ladle addition of Magnesium (as copper-magnesium alloy) to cast iron in the International Nickel Company Research Laboratory. The solidified castings contained no flakes but nearly perfect spheres of graphite [8]. Five years later, at 1948 AFS Convention, Henton Morrogh of British Cast Iron Research Association announced the successful production of spheroidal graphite in hyper eutectic grey iron by addition of small amount of cerium [8].
  • 22. xxii At the same time Morrogh from the International Nickel Company, presented a paper which revealed the development of magnesium as graphite spheroidizer. On October 25, 1949, patent 2,486,760 was granted to the International Nickel Company, assigned to Keith D. Mills [8], Albert P. Gegnebin and Norman B. Pilling. This was the official birth of ductile iron. 2.1.2 Production of Ductile Iron Ductile iron can be produced by treating low sulphur liquid cast iron with an additive usually containing magnesium and then inoculated just before or during casting with a silicon-containing alloy. 2.1.2.1 Raw Materials To produce ductile iron with the best combination of strength and toughness, raw materials must be chosen which have lower than 0.02 wt.% sulphur and are low in trace elements. Low manganese content is also needed to achieve as-cast ductility. Higher strength grades of ductile iron can also be made with common grades of constructional steel scrap, pig iron and foundry returns, but certain trace elements e.g. lead, antimony and titanium are usually kept as low as possible to achieve good graphite structure. 2.1.2.2 Control of the Composition of Ductile Iron Composition of Ductile Iron The composition of unalloyed ductile iron is similar to that of grey iron with respect to carbon and silicon contents. Carbon contents of unalloyed ductile iron ranges from 3.0 wt.% to 4.0 wt.% and silicon content from 1.6 wt.% to 2.8 wt.%. The sulphur and phosphorus levels of high quality ductile iron, however, must be kept very low at
  • 23. xxiii 0.03 wt.% S maximum and 0.1 wt.% P maximum, which are ten times lower than the maximum levels for grey cast iron. Other impurities must also be kept low because they interfere with formation of graphite nodules in ductile iron [9]. All the elements in the composition of ductile iron should be controlled. The following are the important elements in the production of ductile iron [10]. Total Carbon The optimum range of carbon is usually 3.4 to 3.8 wt.% depending on the silicon content. Above this range there is a danger of graphite floatation, especially in heavy sections. Silicon Silicon enters ductile iron from raw materials, including cast iron scrap, pig iron, ferro-alloys and to small extent from silicon-containing alloys during inoculation. The preferred range is about 2.0 to 2.8 wt.%. Lower silicon levels lead to high ductility in heat-treated iron but there is danger of carbides in thin section. High silicon helps to avoid carbides in thin sections. It also increases hardness and tensile strength. Carbon Equivalent The carbon, silicon and phosphorus contents can be considered together as a Carbon Equivalent Value. This is a useful guide to foundry behavior. There are several Carbon Equivalent formulas and they are useful in assessing the casting properties. The formula that is commonly used is as follows: CE = C% + 1/3(%Si + %P) [10]
  • 24. xxiv If the value CE is equal to 4.3wt.%, the iron will be wholly of eutectic composition. When CE is lower than 4.3, there will be a proportion of dendrites; if CE is higher than 4.3 wt.% there will be primary graphite nodules in the structure. Manganese The main source of manganese is steel scrap used in the charge. Manganese should be limited in order to obtain maximum ductility. In as- cast ferrite iron, it should be 0.2 wt. % or less. Manganese produces to undesirable micro segregation especially in heavy section. It encourages the formation of grain- boundary carbides which promote low ductility, low toughness and persistent pearlite. Magnesium The magnesium content which is required to produce spheroidal graphite usually ranges from 0.04 to 0.06 wt.%. If the initial sulphur content is below 0.015 wt.%, lower magnesium content in the range of 0.035 to 0.04 wt.% may be satisfactory. Compacted graphite structure with inferior properties may be produced if magnesium is low, while too high magnesium content may promote dross defects and carbide formation. Minor Elements Promoting Non-spheroidal Graphite Lead, antimony, bismuth and titanium are undesirable elements that may be introduced in trace amount with raw materials in the charge. Their effects can be neutralized by cerium addition as reported by I. C. Hughes [10]. Aluminium The presence of even trace amount of aluminium in ductile iron may promote surface pinhole- porosity and dross formation. The common source of aluminium is
  • 25. xxv contaminants in steel and cast-iron scrap. Another source is aluminium containing inoculants so use of inoculants of low aluminium is advisable. Aluminium as low as 0.01 wt.% may cause pinholes in ductile iron. Phosphorus Phosphorus is normally kept below 0.05% because it promotes unsoundness and lowers ductility. Minor Elements Promoting Carbides Chromium, vanadium and boron are carbide promoters. They are controlled by a careful selection of metallic raw materials for melting 2.1.2.3 Charge Materials The metallic charge for ductile iron base consists mainly of: Pig iron, steel scrap, return ductile iron scrap and ferroalloys [7] Pig Iron The ideal pig iron for ductile iron charge is pure iron- carbon alloy, which is not available. It is believed that sorel metal is the best charge. In sorel metal the manganese content is very low i.e. 0.009 wt.% and its content of elements which either promote carbides or interfere with spheroidization of graphite is low. Steel Scrap Steel scrap is an important component of ductile iron charge. Chemical composition and physical shape are to be considered. The physical shape includes dimensions and specific surface. All melting equipment has its limitations as to maximum size. The cupola furnace also has a minimum size limitation.
  • 26. xxvi Even though very small pieces may be charged into electric induction or arc furnaces (such as thin plate chippings) these have very large specific surface areas which rust rapidly. Even though rust is not believed to cause metallurgical deterioration, it certainly increases slag quantity, acidity and corrosiveness. Whenever possible, such scrap should be used in a balanced condition. Despite these difficulties, steel scrap will remain in use because it is normally less expensive than pig iron and also available in plentiful supply [7]. Ductile Iron Scrap Only scrap of ductile iron of known quality should be used. Ferro Alloys When Ferro alloys are needed in the charge, the chemical composition of the alloys should be known. 2.1.2.4 Desulphurization A variety of compounds are capable of removing sulphur from molten iron. Even manganese desulphurizes but it is an expensive material [7]. More practical desulphurizing agents are [7]: Caustic Soda NaOH Soda Ash Na2CO3 Burnt Lime CaCO3 Calcium Carbide CaC2 Calcium Cyanide CaCN2
  • 27. xxvii Of these, caustic soda is rarely used because of the health hazard. Lime stone is first reduced to CaO before use. CaCN2 should be ruled out because it increases base iron nitrogen content with the result of a danger of nitrogen gas defects in the castings. In the tradition of ferrous metallurgy, CaO is the most established of desulphurizing compounds. In ductile iron practice, it is used in basic cupola and electric arc furnace. Limestone (CaCO3) is injected into large ladles resulting in both economical and excellent desulphurization. 2.1.2.5 Spherodizing Treatment Alloys There are two main alloys in use, nickel magnesium (NiMg) and ferro-silicon- magnesium (FSM). Ferro-silicon-magnesium alloy is commonly used. It should have the composition shown in table 2.3. Table 2.3 Composition of Ferro-silicon-magnesium Alloy Mg % Si % Ca % Ce % Fe % 4-6 45-50 1 max 0.5 balance 2.1.2.6 Melting Techniques for the Production of Ductile Iron Any furnace which is used for melting of ductile iron must be capable of producing an iron of correct composition at correct temperature. The need to maintain these factors consistently is most important.
  • 28. xxviii Types of Furnaces Various furnaces are available for the production of ductile iron e.g. fuel fired furnace, electric arc furnace, induction furnace and cupola. Optimum economy and quality is achieved through cupola-induction furnace duplexing, but this optimum is obtainable for large volume production only. Externally water-cooled cupola furnaces are being used for large scale operations. Water-cooling causes too much heat losses in small cupolas. The main reason for their popularity is the fact that these can operate continuously for several days [7]. Electric Melting Electric melting is simple, clean and reliable. It also offers the greatest flexibility for melting irons of different grades. Electric arc furnaces are far less popular than induction furnaces. An additional disadvantage of electric arc melting is its noise pollution. Electric induction furnaces are most common. High frequencies units are usually used for laboratory scale production. In commercial production either 50 or 60 HZ frequencies are being used; the lower the frequency, the better the stirring action and thus, homogenization. 2.1.2.7 Spheroidizing Treatment One of greatest practical difficulties is the required amount of magnesium into the melt with the necessary degree of consistency. Magnesium boils at 1120o C and when plunged into cast iron at 1400o C, Magnesium metal melts and vaporizes instantaneously, escaping with violence and carrying some of the cast iron with it. Different alloys are
  • 29. xxix used to overcome this difficulty. An alloy of nickel and magnesium (5 or 15 % Mg) is efficient as it sinks in molten iron and the reaction is relatively quiet , especially with 5 wt.% alloy. However it is expensive and simultaneously addition of nickel is not always welcomed [11]. Following are four most generally used nickel base magnesium alloys shown in the table 2.4 [7]. Table 2.4: Chemical composition of Ni-base alloy containing magnesium in wt.% Mg % Ni % Si % C % Fe % Ni-Mg 1 15 83 --- 2.0 --- Ni-Mg 2 15 50 30 --- Bal Ni-Mg 3 4.5 93 --- 1.5 --- Ni-Mg 4 4.5 60 --- 2.5 Bal A range of magnesium-ferro-silicon alloys are available containing 3 to 15 wt.% magnesium with approximately 45 % silicon [11]. Although various methods are employed for introducing magnesium into molten metal, the universally accepted procedure is the sandwich method. Because of the relatively low density, ferrosilicon- magnesium alloys tend to float on the surface of the liquid iron and react inefficiently. Accordingly, the alloy is placed in the bottom of the treatment ladle, preferably in a „pocket‟ moulded in the bottom of the ladle, and covered with steel plate. Before use, the ladle should be heated to a temperature of red heat.
  • 30. xxx After placing the ferrosilicon-magnesium alloy in the pocket and covering the alloy with the plate, the ladle is positioned so that liquid metal stream does not impinge directly on the magnesium alloy/sandwich. This allows the metal to flow back over the sandwich, which due to presence of cover, delays the reaction of magnesium alloy until a sufficient depth of alloy is built up in the ladle, and it also prevents the alloy floating to the surface of the liquid iron. The ladle should be filled as quickly as possible. This improves the magnesium recovery. The magnesium recovery depends on metal temperature, the quantity of metal treated and the design of the ladle. 2.1.2.8 Amount of Magnesium Required In practice it is normal to allow for minimum residual magnesium content of 0.035 to 0.04 wt.%, plus the amount of magnesium required to neutralize the sulfur in the iron. The amount of magnesium alloy required depends on two factors: a) The temperature of metal, the higher the temperature, the lower the recovery of magnesium. b) Sulphur content of the base iron to be treated; the higher the sulphur content, the greater is the amount of magnesium to be added. Calculation of Magnesium: Different formulas are used to calculate the amount of magnesium required. The commonly used formula is [7]: Mg to add (%) = %SBase 01.0%erycovreMg %requiredcontentMg   
  • 31. xxxi Fading of Magnesium There is a gradual decrease in nodularity and an increase in carbide formation, as treated iron is held for some time. The results from different research centers indicated that fading is rather complicated phenomenon. The simplest component is loss of magnesium content through oxidation or combining with sulphur. Stephen [7] described the following corresponding reactions: Mg + O = MgO or Mg + S = MgS Considering the relative stabilities of the above two compounds, a more likely reaction is: Mg + S + O = MgO + S If the source of oxygen is an oxide or silica as an oxide, the corresponding reactions are: 2Mg + SiO2 = Si + 2MgO and 2MgS + SiO2 = Si + 2MgO +2S It is well established that fading rate is influenced by: a) Initial Magnesium content; the higher the magnesium content the faster the fading b) Temperature; the higher the temperature the faster the fading c) Slag handling; the faster the slag is removed, the better for magnesium recovery.
  • 32. xxxii d) Furnace lining; the worst is silica, the best is magnesia. 2.1.2.9 Inoculation The metallurgical meaning of the word “inoculation” is to provide the melt with seeds or “nuclei” on to which the solid phases grow during freezing. In some cases these nuclei result from adding fines of the same phase which is freezing. If the fines do not completely dissolve before solidification starts, they provide convenient sites for crystal growth. In other cases particles of material other than the one to freeze can perform the same act i.e. heterogeneous nucleation. The inoculation of ductile irons produces heterogeneous nuclei for the graphite spheroids. Neither their material nature nor mechanism of their action is factually known [7]. The Effects of Inoculations The principle effects of ductile iron inoculation can be described as follows [12]. The inoculation process:  Promotes the formation of small and uniformly dispersed graphite in grey iron and increase the nodule count in ductile iron.  Minimizes the formation of primary iron carbides. These carbides create hard edges on iron castings that make machining difficult, which is a contributing factor to tool breaking.
  • 33. xxxiii  Reduces the non-uniform properties within a casting of varying section sizes. Thinner sections solidify at a faster rate than thicker sections. As a result, the properties such as tensile strength of these sections will be different. Inoculation provides more uniform properties within the casting by reducing the solidification rate in thinner sections.  Improves the tensile strength, impact strength, toughness, wear resistance and machinability of the casting. Inoculants Almost every material inoculates to some degree. For effective and well controlled inoculation, ferro-silicon of controlled chemical composition are usually used. Active inoculating elements are: Ca, Al, Ba, Sr, and some others. The chemical composition of commonly used inoculants is given in table 2.5 [7]. Table: 2.5 Chemical Composition of Inoculants Si % Ca % Al % Ba % Fe % 75 1.5 1.0 --- Bal 63 2.0 1.0 5 Bal The inoculants contain relatively little aluminium because aluminium promotes hydrogen pinholes defects, particularly in thin sections [7]. The sizing of the inoculant is usually ½ inches (13 mm) maximum. Since fines do not inoculate effectively, a minimum size limit of 1/6 inches (1.5 mm) is advisable [7].
  • 34. xxxiv The inoculant should be stored in closed containers. Its effectiveness deteriorates with time when exposed to open air. Methods of Inoculation Cast iron may be inoculated by several methods [12].  Ladle Inoculation Iron is inoculated by adding inoculant to the metal as it is transferred from the furnace to the pouring ladle. The turbulence quickly dissolves the inoculant and evenly disperses it throughout the molten bath.  In-stream Inoculation In many automatic pouring operations, inoculation is done in-the-stream  In-mould Inoculation Inoculants may also be added as a preformed insert placed in the pouring basin of a mould or as granulated inoculant placed in the gating system. In-stream and in-the-mould inoculation techniques offer little inoculation fade, and generally require less inoculant material to provide the desired results. 2.1.3 Formation of Carbides in Ductile Iron: The attainment of mechanical properties in cast ductile iron depends primarily upon the microstructure developed during solidification and solid-state transformation. A recent trend in vehicle component has been towards higher strength and lighter weight to save both materials and energy. Reducing the weight of ductile iron castings by producing thin-wall parts is an important method for saving energy and material. In thin
  • 35. xxxv castings the cooling rate is fast so carbides are formed if special practice and procedure are not adopted. The general reasons for the carbide formation are as under [13]. 1. High solidification cooling rate 2. Carbide-formation elements in the charge 3. Low CE and / or Si content 4. Excessive Mg content 5. Inadequate and poor inoculation (low nodule count) 6. High superheat 2.1.4 Pouring Pouring of ductile iron should be done quickly while keeping the pouring basin full through the pour. A majority of ductile iron castings are hand-poured even in highly mechanized foundries. It must be recognized that hand-pouring is a demanding job and the pourer is exposed to some hazard. For this reason and, for potential economic and quality benefits, much effort is being invested in designing pouring machines [7]. 2.1.5 Importance of Ductile Iron Ductile iron is a very useful invention. It offers the design engineers the option of choosing high ductility, more than 18% elongation, or high strength exceeding 825 MPa. Ductile iron, when compared to steel and malleable iron castings offers cost savings [14]. Like most commercial cast metals, steel and malleable irons decrease in volume during solidification, and as a result, require attached reservoirs (feeders or risers) of liquid metal to compensate shrinkage. The formation of graphite during solidification
  • 36. xxxvi causes an internal expansion of ductile iron as it solidifies. As a result, it may be cast free of significant shrinkage defects with feeders that are much smaller than those used in malleable iron and steel. This reduced requirement for feed metal increases productivity of ductile iron and reduces its material and energy requirements resulting in substantial cost savings. The use of most common grades of ductile iron “as-cast” eliminates heat treatment cost, offering a further advantage. Ductile iron castings are used for many structural applications, particularly those requiring strength and toughness combined with good machinability and low cost. A ductile iron casting can be poured and shipped the same day. As-cast ductile iron castings are consistent in dimensions and weight because there is no distortion or growth due to heat treatment. Ductile iron is finding increasing applications in automobile parts e.g. crankshafts, piston rings and cylinder liners. The use of ductile iron in these applications provides increased strength and permits weight savings. In agricultural and earth-moving application, brackets, sprockets wheels and track components of improved strength are made of ductile iron. General engineering applications include hydraulic cylinders, mandrels, machine frames, switch gears, rolling mill rolls, tunnel segments, bar stock, street furniture and railway rail-clip supports
  • 37. xxxvii 2.2 AUSTEMPERED DUCTILE IRON (ADI) 2.2.1 Austempering To achieve the full potential of ductile iron, austempering heat treatment is adopted. It is possible to achieve much higher ranges of tensile strength and elongation by adopting austempering treatment for ductile iron. For austempering treatment, a defect free casting should be chosen. Any lapse in quality control of starting material will result in inferior end product. The process is simple. The first stage consists of soaking the castings at austenitizing temperature of 850-950o C. The austenitized castings are then quickly transferred to a liquid bath (salt bath) maintained at temperature range of 235- 425o C. The transformation is allowed to proceed for a period of up to four hours when austenite transforms to bainite. The castings are finally cooled to room temperature after transformation. By adopting austempering heat treatment process instead of conventional hardening and tempering treatment for ductile iron, the chances of cracking and distortion are reduced. Thus, it becomes possible to carry out rough and final machining before heat treatment. It is possible to achieve various combinations of high strength, high hardness, limited ductility or lower strength, lower hardness, high ductility by varying the temperature of austempering. 2.2.2 Introduction to Austempered Ductile Iron: Austempered ductile iron (ADI) is a ductile iron that has undergone a special, isothermal heat treatment called austempering. Unlike conventional “as-cast” irons, its properties are achieved by heat treatment, not by specific addition. Therefore the only prerequisite for a good ADI is a quality ductile iron [15]
  • 38. xxxviii ADI offers superior combination of properties because it can be cast like any other member of the ductile iron family. It offers all production advantages of conventional ductile iron castings. Subsequently, it is subjected to the austempering process to produce mechanical properties that are superior to conventional ductile iron, cast and forged aluminium and many cast and forged steels. The metal matrix determines the mechanical properties of ductile iron and ADI. The matrix in conventional ductile iron is controlled by a mixture of pearlite and ferrite. The properties of ADI are due to its unique matrix of acicular ferrite and carbon- stabilized austenite, called ausferrite. Austempering was commercially applied to austempered ductile iron in 1972. A small hallow crankshaft cast by Wagner Casting Company of Decatur, Illinois was machined and installed in a Tecumser products type AE compressor. Meanwhile General Motors successfully implemented ADI rings and pinion gears and constant velocity joints on its production trucks and automobiles [15]. From its infancy in 1972 until today, the application of ADI has grown worldwide. Its annual growth is estimated at 15%. Its combination of high strength- to- weight ratio, wear resistance and low cost have made it a “high-tech” material. Researchers are continuously studying its new parameters [15]. 2.2.3 Production of Austempered Ductile Iron The mechanical properties offered by ADI make it an attractive material for demanding applications. Austempered ductile iron castings must be produced free from surface defects, free from carbides, porosity, inclusions and having a consistent chemical composition .
  • 39. xxxix 2.2.3.1 Composition of ADI In many cases, the composition of an ADI casting differs a little from that of a conventional ductile iron casting. When selecting the composition, consideration should be given to the elements that adversely affect casting quality e.g. formation of carbides and inclusions. A typical composition of ductile iron casting used for making austempered ductile iron is given in the table 2.6 [16]. Table 2.6 Typical Composition of Ductile Iron for Austempered Ductile Iron C % Si % Mn % Cu % Ni % Mo % 3.5-3.7 2.5-2.7 0.25-0.31 0.05-0.8 0.01-0.8 If required 0.25 max There are three important points to consider when selecting the chemical composition of ADI [17]. 1) The iron should be sufficiently alloyed to avoid transformation of pearlite but not over alloyed. 2) The micro structure should be free from intercellular carbides and phosphides. 3) The tendency for chemical segregation should be minimized for the sake of uniformity in the cast component. 2.2.3.2 Effects of Alloying Elements Alloying elements are generally used in ductile iron to increase its hardenability. Only the minimum amount of alloys required should be used. Excessive alloying only
  • 40. xl increases the cost and difficulty producing quality ductile iron necessary for ADI. The following are major alloying elements which are used for austempered ductile iron [16]. Carbon Increasing carbon in the range of 3 to 4 wt. % increases the tensile strength but has negligible effect on elongation and hardness. Carbon should be controlled within the range of 3.6 to 3.8 wt.%. Silicon Silicon is one of the most important elements in austempered ductile iron (ADI) as it promotes graphite formation, decreases the solubility of carbon in austenite and inhibits the formation of bainite carbide. Increasing the silicon content increases the impact strength of ADI. Silicon should be controlled closely within the range of 2.4 to 2.8 wt. % Manganese Manganese can be both beneficial and harmful as an alloying element. It strongly increases hardenability, but during solidification, it segregates to cell boundaries where it forms carbides and retards austempering reaction. It is advisable to restrict the manganese level to less than 0.3 wt.% Copper It increases hardenability and ductility at austempering temperature below 350 o C. It may be added up to 0.8 wt.%
  • 41. xli Nickel Nickel increases hardenability of ductile iron .It increases ductility and fracture toughness at austempering temperature below than 350 o C. It may be added up to 2.0 wt.%. Molybdenum It may be added in heavy section castings to prevent the formation of pearlite. Tensile strength and ductility decreases as the molybdenum is increased beyond that amount which is required for hardenability. This is because of segregation of molybdenum to cell boundaries and formation of carbides. It should not be added more than 0.2 wt. % Phosphorus Phosphorus forms the very brittle structure known as steadite in ductile iron as well as in grey cast iron since phosphorus adversely affects toughness and ductility, a maximum of 0.05 per cent is usually specified [18] Sulphur The most important effect of sulphur in ductile iron is to increase the amount of magnesium required to achieve spheroidal graphite. The level of sulphur in the iron prior to magnesium treatment is a function of the melting practice used. Sulphur content after treatment is usually 0.015 per cent [18]. Very little work has been carried out to study the effect of sulphur. Generally sulphur is considered to be an impurity. Patty Sim, [19] a foundryman was using autopour at his foundry. His target was 0.013 per cent sulphur in the furnace bath. According to him lower sulphur target could cause carbides in the finished castings.
  • 42. xlii The influence of sulpher on the machinability of grey cast was studied by Adriana et al. [20]. They found that sulpher addition in grey iron from 0.065 to 0.18 wt.% did not produce significant alternation on mechanical properties or on microstructure. From their study viable use of a higher sulpher percentage on grey cast iron production, without the detrimental effects of mechanical properties, microstructure and machinability were obtained. Rare Earth Elements The addition of rare earth elements has significant effects on the properties of ductile iron [15]. Following are the most common rare earth elements which are used in ductile iron. 1. Cerium Cerium is a powerful desulphuriser. When sulphur content of a cast iron exceeds about 0.02 wt. % the cerium reduces sulphur content. Cerium combines with sulphur even in the presence of manganese. Cerium sulphide is formed and it rises to the surface of the molten metal. The higher the sulphur content of the molten metal the greater will be the amount of cerium required. As cerium is a relatively expensive material, so sulphur content of iron to be treated should at the lowest level. Cerium may be added to cast iron in a variety of alloys i.e. pure cerium, iron-cerium, nickel-cerium, copper- cerium, silicon-cerium, manganese-cerium, and aluminium-cerium. All dissolve quite easily in molten cast iron. On account of its ready commercial availability and relatively low cost, a cerium alloy known as mischmetal is most frequently employed. Mischmetal contains approximately 50% of cerium. Chemical analysis of a typical cerium alloy [11] is given the table 2.7.
  • 43. xliii Table 2.7 Composition of a Typical alloy of Cerium Ce % La % Nd % Other rare earths Fe % 45-53 22-25 15-17 8-10 5 max An important point to be observed is that the mischmetal should not be finally divided in the form of powder, as loss by oxidation may occur. Morrogh [21] and Wallance et al. [22] have reported that a very small addition of cerium as mischmetal has a controlling effect on the deleterious elements such as lead, arsenic, antimony, titanium, and tin. McCluhan [23] has shown that an optimum addition of cerium as mischmetal to laboratory magnesium-ferro-silicon (MgFeSi) results in ductile cast irons with high graphite nodule counts and low levels of carbide formation. 2. Lanthanum Very little work has been done on the effect of lanthanum on the properties of the ductile iron. When lanthanum is added to ductile iron as a lone rare earth element in the nodulizing alloy, mixed results have been reported. Horie et al [24] claimed that nodule count increases and carbides are reduced when the La: S ratio is between 2.5 and 6.0. However, Stefanescu et al. [25] found that nodule count steadily decreases as the lanthanum content in MgFeSi increases. Very little work has been done on the effect of rare earth elements on the microstructure and the properties of ductile iron. It would be of considerable interest to determine whether the addition of lanthanum is significant in affecting nodule count and nodularity
  • 44. xliv 2.2.3.3 Production of Austempered Ductile Iron: Austempered ductile iron is produced by an isothermal heat treatment known as austempering. It consists of the following steps and it can be represented schematically as shown in Figure 2.1 [17]. 1) Heating the casting to the austenitizing temperature in the range of 850 o C to 950 o C 2) Holding the part at austenitizing temperature for a time sufficient to get the entire part to the required temperature and to saturate the austenite with carbon. 3) Quenching the part rapidly enough to avoid formation of pearlite to austempering temperature in the range 235 o C to 400 o C 4) Austempering the casting at the desired temperature for a time sufficient to produce matrix of ausferrite. 5) Finally cooling the casting to room temperature. Figure 2.1 Schematic diagram of a typical austempering heat treatment cycle [17]
  • 45. xlv Austenitizing The austenitizing temperature controls the carbon content of austenite that affects the structure and properties of austempered castings. High austenitizing temperature increases the carbon content of austenite, which effect the hardenability. It makes the transformation problematic and reduces the mechanical properties after austempering. The higher carbon of austenite requires a longer time to transform. Austenitizing temperature should be minimum required to heat the entire part to the desired austenitizing temperature and to saturate the austenite with equilibrium level of carbon. Austenitizing time is affected by chemical composition, austenitizing temperature, casting section size and type [16]. Austempering Cooling from austenitizing temperature must be completed rapidly to avoid the formation of pearlite. If pearlite is formed, the strength, elongation and toughness will be reduced. Austempering temperature is one of the major determinants of mechanical properties of ADI castings. Higher austempering temperature (350 o C to 400 o C produces ADI with lower strength and hardness but high elongation and fracture toughness. Higher austempering temperature produces coarse ausferrite matrix. For production of ADI with higher strength and greater wear resistance but lower fracture toughness and lower elongation, austempering temperature below 350 o C should be employed.
  • 46. xlvi When austempering temperature is selected, the austempering time should be chosen to give a stable structure of ausferrite. Shorter austempering time will give rise to insufficient diffusion of carbon to austenite to stabilize it and martensite may form when cooling to room temperature. This type of structure would give higher hardness and lower ductility. Excessive austempering time can result in decomposition of ausferrite into ferrite and carbides, so austempering time selection should be appropriate [16]. 2.2.3.4 Heat Treatment Considerations It is important that the heat treatment operation is closely controlled to ensure the production of castings with consistent and satisfactory mechanical properties. A schematic representation of batch austempering heat treatment process is shown in figure 2.2 [17]. Figure 2.2 Schematic arrangement of the austempering process [17]
  • 47. xlvii 2.2.4 Specifications of Austempered Ductile Iron The ASTM specification A 897 is now most commonly accepted for austempered ductile iron. The five grades specified are detailed in table 2.8 below. They are readily differentiated by their hardness. Tensile, yield and elongation values are also specified as shown in table 2.8 [26]. Table 2.8 Austempered Ductile Iron ASTM A897-90 (ASTM 897 M-90)[26] Grade Min. Tensile Min. Yield Elongation BHN Psi. N/m2 Psi. N/mm2 % Range 1 125,000 850 80,000 550 10 269-321 2 150,000 1050 100,000 700 7 302-363 3 175,000 1200 125,000 850 4 341-444 4 200,000 1400 155,000 1200 1 388-477 5 230,000 1600 185,000 1300 - 444-555 The British Standards Specification for austempered ductile iron is also used mostly in Europe. The four grades are detailed in table 2.9. They are differentiated by their tensile, proof stress and elongation. The standard EN 1564:1997 is shown in table 2.9 [26].
  • 48. xlviii Table 2.9 British Standards Specification for ADI EN 1564:1997 [26] Material Symbol Number Tensile Strength N/mm2 (Min.) 0.2 % Proof Strength N/mm2 (Min.) Elongation % EN-GJS-800-8 EN-JS 1100 800 500 8 EN-GJS-1000-5 EN-JS 1110 1000 700 5 EN-GJS-1200-2 EN-JS 1120 1200 850 2 EN-GJS-1400-1 EN-JS 1130 1400 1100 1 2.2.5 Cost Benefits of Austempered Ductile Iron: The price of austempered ductile iron is lower than per kilogram of steel. ADI parts can be produced at a cost less than for steel forging. There are many factors which favour the replacement of steel forging with austempered ductile iron [27]. Excellent castability It can be cast into complex shapes. Ductile iron has a very high yield. Low Machining Cost ADI requires less starting material and less metal removal. Prior to austempering, ductile iron exhibits better machinability than the steels. Both ductile iron and ADI produce dense, discontinuous chips that are easily handled. Heat treatment Savings Austempering generally costs less than carburizing or induction hardening, and produces a higher degree of uniformity.
  • 49. xlix Low Energy Cost Producing a typical austempered ductile iron castings consumes 50% less energy than steel casting and 80 % less energy than steel forging for the producing of the similar product. 2.2.6 Properties Of Austempered Ductile Iron Austempered Ductile iron has the following properties [16,27] Strength It has strength equal to or greater than steel Toughness It has toughness better than ductile iron and equal to or better than cast or forged steel. Weight Austempered ductile iron has 10 % less weight than steel due to the presence of graphite nodules. Fatigue Strength Austempered ductile iron has equal to or better fatigue strength than forged steel, which increases with machining after heat treatment Damping Austempered ductile iron has five times better damping property than steel. The parts made of this material make less noise.
  • 50. l 2.2.7 Disadvantages of Austempered Ductile Iron: There are certain disadvantages of austempered ductile iron. These should be considered before replacing steel parts with ADI. These are as follows [28]. 1) Welding is not recommended for austempered ductile iron. 2) Lower hardness grades can be machined after heat treatment, but higher hardness grades must be machined before heat treatment. 2.2.8 Application of Austempered Ductile Iron: The development of austempered ductile iron (ADI) has given the design engineers a new group of cast ferrous materials. ADI provides an exceptional combination of mechanical properties equivalent to cast and forged steel. Dr. Richard Harding [29] overviewed the wide range of application of austempered ductile iron. Gears One of the earliest applications of ADI was for the manufacture of gears. Pioneers in this field were:  General Motors, USA for rear axle hypoid pinion and ring gears for cars  Chinese foundries, who used similar gears for light and medium trucks [30]  Kymi Kymmence, Finland, for various applications including general engineering gear boxes, rolling mill drives, and large segmented ring gears for cement mills, rotary kilns and forestry machines [31,32]
  • 51. li Crankshafts One of large potential markets of austempered ductile iron is crankshafts for high-powered diesel engines [29]. Crankshafts for air-conditioning and refrigerator application have been produced by companies such as Wagner Casting Co. USA and Sulzer Brothers, Switzerland [33] Transmissions There are following examples for the transmissions [29].  A large number of tripot housings have been used by General Motors, USA, in front- wheel drive units.  Differential spiders manufactured by Kymi Kymmene, Finland. Suspensions The austempered ductile iron suspensions have been used in the industry. The example includes war shoe restraints made by Advance Cast Products, USA , for use in suspension units of lorry tractor units [29]. Railway Engineering A variety of austempered ductile iron components have been used in European and American railway applications e.g. Axle boxes produced by SKF, Sweden, for railway vehicles and pick up arms for railway track maintenance machines, produced by Sulzer Brothers, Switzerland [26,33] Bracket Trailer The Australian trucking industry had interesting challenges in terms of hauling freight over rough and isolated distances that can be exceptionally long. Different
  • 52. lii experiments were carried out with different materials. They failed the on-road test. Ultimately a ductile iron casting was designed and austempered to ASTM Grade 2 ADI. The bracket was 900mm long and 1200 mm high, with a weight of 105 kg. These ADI brackets successfully traveled over 322,000 km without any problem [34]. Agricultural Applications Due to its high strength-to-weight ratio as well as its increased wear resistance, austempered ductile iron is well suited for agricultural applications from suspension to ground-engaging components [35] Defence The defence industry has been relatively slow to adopt ADI, however some of the applications include track links, armor and various hardware for trucks and armored vehicles [16].
  • 53. liii CHAPTER - 3 EXPERIMENTAL WORK RESEARCH METHODOLOGY During the present research an attempt was made to observe the tensile strength of ductile iron by the addition of copper, nickel, a combination of copper and nickel and lanthanum. Different heats with and without copper, nickel and a combination of copper and nickel were made to find out the effect of these alloying elements on ductile iron. Samples for this study consisted of tensile test bars having different compositions of ductile iron with and without the alloying additions. Test bars from one melt without lanthanum were produced in the Casting Laboratory of the University of Birmingham, UK. Test bars with varying composition of lanthanum from three melts were produced to observe the effect of the addition of lanthanum. Different experiments were conducted for studying the effect of alloying elements and effect of heat treatment on ductile iron.  To find out the optimum austempering time, ductile iron samples were heat treated at fixed austenitizing temperature at 900 o C and austempering temperature at 270 o C and 370 o C. The austempering time was varied from half an hour, one hour and one and a half hour to determine the most suitable austempering time.
  • 54. liv  To ascertain the suitable austenitizing temperature, the austempering temperature at 270 o C and 370 o C and austempering time for one hour was fixed. Austenitizing temperature of 850 o C, 900 o C and 925 o C was maintained for one hour to find out the best austenitizing temperature for these samples.  Addition of Copper Four heats were made to find out the effect of copper on the tensile strength of ductile iron. Copper content was varied from nil to 1.5 wt. %.  Addition of Nickel Different heats were produced to examine the effect of nickel on ductile iron. The melts were made with the addition of 1.0 wt. %, 2.0 wt. % and 3.0 wt. % of nickel.  Addition of a combination of Copper and Nickel Different melts with a combination of copper and nickel were made to examine the effect of both of alloying elements together.  Addition of Lanthanum Four melts were made for this purpose. One melt was made without lanthanum while three melts with varying compositions of lanthanum were made. Three aspects of the composition of lanthanum were investigated i.e. nodule count, nodularity and tensile strength with and without heat treatment. Different properties of ductile iron were studied taking into consideration the following:  Change of tensile strength with the change of austempering time.
  • 55. lv  The change of tensile strength with the change of austenitizing temperature.  The change in nodule count and nodularity with the change in the amount of lanthanum.  The change of tensile strength with the change of austempering temperature in low and high temperature ranges.  The change of tensile strength with the change of lanthanum, copper and nickel content Limitations of Study Two major constraints were experienced during the experimental design stage. One was that the ferro-lanthanum alloying element was not available in the local market and the other was the non availability of relevant technical literature. The difficulties were overcome by conducting some of the experiments at the University of Birmingham, UK. Aim of Study The aim of the experimental work was to study the effects of copper, nickel, a combination of copper and nickel and lanthanum and to study the heat treatment variables (time and temperature) on ductile iron. For this purposes ductile iron castings were produced with and without copper, nickel, a combination of copper and nickel and lanthanum. The results were compared to find out the best austempering time, austenitization temperature and the percentage of alloying addition to get the maximum tensile strength.
  • 56. lvi 3.1 PRODUCTION OF DUCTILE IRON 3.1.1 Ductile Iron without and with Copper, Nickel and Copper- Nickel Together Ductile iron was made using local materials and local facilities. The melting was carried out in a commercial electro-induction foundry furnace. The materials used were pig iron from Pakistan Steel, mild steel from the local market and ductile iron returns of the foundry. In order to get the required composition, ferro-alloys were added to the melt. After melting, the metal was poured into a ladle with two pockets at the bottom. In one pocket ferro-silicon-magnesium alloy and inoculant ( ferro-silicon) were placed while the other was kept empty. The following raw materials for the production of ductile iron were used. Pig Iron Pig iron from Pakistan Steel was used for making ductile iron. The composition of the iron is given in table 3.1 Table 3.1 Chemical Composition of Pig iron in wt % C Si Mn P S Fe 4.1 0.83 0.6 0.025 0.021 Balance Mild Steel Mild steel with the following composition mentioned in table 3.2 was used. Table 3.2 Chemical Composition of Mild Steel in wt % C Si Mn Fe 0.2 0.3 0.4 Balance
  • 57. lvii Ferro-silicon-magnesium Ferro-silicon-magnesium used for the spheroidization with the composition shown in table 3.3. Table 3.3 Chemical Composition of Ferro-silicon-magnesium in wt % Si Mg Ca Al Fe 42 5.5 1.2 1.0 Balance The melt was poured from about 1450 o C into a standard Y block sand mould. Tensile specimens of 15 mm diameter 250 mm long were machined from the castings. Chemical Composition of Heats Produced  The chemical analysis of ductile iron produced without and with copper addition is mentioned in the table 3.4. Four heats were made to find out the effect of copper on ductile iron. The details of heats are as follows: Heat No. C0 without any copper Heat No. C10 with 1.0 % copper Heat No. C5 with 0.5 % copper Heat No. C15 with 1.5 % copper Table 3.4 Chemical Composition of Ductile Iron Produced with copper in wt % Elements Heat No C0 Heat No C5 Heat No C10 Heat No C15 C 3.6 3.5 3.7 3.9 Si 2.7 2.9 2.6 2.7 Mn 0.1 0.2 0.1 0.2 Cu 0.0 0.5 1.0 1.5 S 0.07 0.09 0.08 0.09 P 0.02 0.03 0.02 0.02
  • 58. lviii  The chemical analysis of ductile iron produced without nickel and with nickel addition is mentioned in the table 3.5. The details of heats prepared to find out the effect of nickel are mentioned below: Heat No. N0 without any nickel Heat No. N1 with 1.0 % nickel Heat No. N2 with 2.0 % nickel Heat No. N3 with 3.0 % nickel Table 3.5 Chemical Composition of Ductile Iron Produced with Nickel in wt % Elements Heat No N0 Heat No N1 Heat No N2 Heat No N3 C 3.6 3.7 3.7 3.8 Si 2.7 2.8 2.7 2.7 Mn 0.1 0.2 0.2 0.2 Nickel 0.0 1.0 2.0 3.0 S 0.08 0.09 0.08 0.08 P 0.02 0.02 0.02 0.02  The chemical analysis of ductile iron produced without and with a combination of copper and nickel contents is mentioned in the table 3.6. The details of heats prepared to find out the effect of copper and nickel together are mentioned below: Heat No. CN0 without any copper and nickel Heat No. CN1 with 0.5 wt % copper and 1.0 wt.% nickel Heat No. CN2 with 1.0 wt. % copper and 2.0 wt.% nickel Heat No. CN3 with 1.5 wt. % copper and 3.0 wt. % nickel
  • 59. lix Table 3.6 Chemical Composition of Ductile Iron Produced with Copper & Nickel Together in wt %. Elements Heat No CN0 Heat No CN1 Heat No CN2 Heat No CN3 C 3.8 3.7 3.6 3.8 Si 2.9 2.7 2.8 2.9 Mn 0.2 0.1 0.1 0.2 Nickel 0.0 1.0 2.0 3.0 Copper 0.0 0.5 1.0 1.5 S 0.07 0.09 0.08 0.08 P 0.03 0.02 0.02 0.02 3.1.2 Ductile Iron Prepared without Lanthanum Ductile iron samples were prepared at the University of Birmingham, U K. The furnace used was medium frequency induction furnace of capacity 28 kg. The material used was sorel metal, mild steel and ferroalloys. The investigation for optimum austempering time and austenitizing temperature was carried out on the samples of this melt. The composition of ductile iron produced is given in the table 3.7. Table 3.7 Chemical Composition of Ductile Iron in wt. % C Si Ni S P Mg 3.5% 2.5% 0.019% 0.05% 0.005% 0.05% 3.1.3 Ductile Iron Produced with Lanthanum Four melts were made with and without the addition of lanthanum i.e. 0.00 wt.%, 0.006 wt.%, 0.02 wt.% and 0.03 wt.% at the University of Birmingham, UK. For
  • 60. lx this purpose, the following charge materials were used. A good quality of charge was selected for the melting. The composition of the charge was as follows: Sorel Metal Sorel Metal of Grade RTF 10 was used. The composition is given the table 3.8. Table 3.8 Chemical Composition of Sorel Metal in wt. % C Si Mn S P 4.33 0.134 0.014 0.005% 0.017 Ferro-silicon 75(Base) Ferro-silicon with 75 wt. % of silicon was used. Ferro-silicon-magnesium Ferro-silicon-magnesium with Si = 45.45 wt.% and Mg =4.72wt.% was used for graphitization Swedish Iron Swedish iron was used for the production of ductile iron . The composition of the iron is given the table 3.9 Table 3.9 Chemical Composition of Swedish Iron in wt. % C Si Mn S P 0.01 0.03 0.18 0.004 0.011
  • 61. lxi 3.1.4 Moulding Method A vertically-parted sand mould was used. Fig.3.1 [36] shows the dimension of the mould. The mould constituted three parts, a pouring basin, a runner and a series of ten test bar cavities. Ten cavities were used for the castings. The sand moulds were made from local silica sand from Kings Lynn AFS grade 60 bonded with Ashland pepset resin. For making the mould, silica sand with pepset 1505 with catalyst pepset 2590 were used. The pattern was sprayed with silicon-free release agent, from Blayson company, for easy removal of mould. Fig.3.1 16mm diameter test bar mould (Dimension in mm)
  • 62. lxii 3.1.5 Melting Technique The charge materials were melted in INDUCTOTHERM medium frequency Induction furnace of 28 kg capacity for making melts with and without lanthanum. To achieve a good and reliable result, care was taken to maintain a good melting practice throughout the experimental work. In each experiment 24 kg melt was used. Ductile iron samples alloyed with copper, nickel and copper & nickel together were produced from a 100 kg high frequency induction furnace installed at a commercial foundry. 3.1.6 Spheroidizing Treatment The Sandwich method was employed for spheroidizing. After melting, the metal was poured into a ladle with two pockets at the bottom. In one pocket ferro- silicon 75 (base) and ferro-silicon- magnesium were placed while the other pocket was kept empty. The alloys were covered with 1/8 inches thick plate to delay the reaction and to avoid vaporization of alloying elements. 3.1.7 Inoculant Ferro-silicon inoculant was used for the production of ductile iron samples alloyed with copper, nickel and a combination of copper and nickel. The ductile iron samples were inoculated for melts alloyed with lanthanum by traditional ladle inoculation method. The inoculant was added to the metal as it was transferred from the furnace to the pouring ladle. The turbulence quickly dissolved the inoculant. For the first three melts ferro-silicon was used as an inoculant. It proved to be unsuccessful in removing the carbides in the castings. Later, for the remaining four melts, it was replaced with super-seed.
  • 63. lxiii 3.1.8 Chemical Analysis Standard coin samples were chilled cast for chemical analysis for every melt. The samples were taken from the middle of casting. The chemical analysis of samples of ductile iron is given in the table 3.10. Table 3.10 Chemical Analysis of Ductile Iron Alloyed with Lanthanum Elements Melt Number MELT 1 MELT 2 MELT 3 MELT 4 C 3.71 3.45 3.40 3.41 Si 2.45 2.75 2.63 2.68 Mn 0.111 0.105 0.107 0.106 P 0.016 0.022 0.021 0.022 S 0.008 0.006 0.008 0.008 Cr 0.027 0.028 0.026 0.028 Mo 0.002 0.001 0.001 0.001 Ni 0.029 0.028 0.029 0.029 Al 0.019 0.018 0.017 0.016 Cu 0.016 0.015 0.016 0.015 Mg 0.064 0.071 0.058 0.060 Sn 0.001 0.001 0.001 0.001 Ti 0.005 0.005 0.005 0.006 V 0.008 0.008 0.007 0.008 La 0.000 0.006 0.020 0.030 Fe Bal. Bal. Bal. Bal.
  • 64. lxiv 3.1.9 Filtration of Ductile Iron The ductile iron produced at the University of Birmingham was filtered with a Sedex ceramic foam filter having 10 pores per inch to get slag free samples for the study. A ceramic filter was used for every melt to produce high quality ductile iron. It was placed at the bottom of the sprue, as shown in Figure 3.1. The dross (slag) is relatively high in ductile iron. Oxides are the principal constituents of slag/dross in cast iron and come from furnace refractories, ladle lining, moulds, and the oxidation of dissolved magnesium and silicon during the melting and pouring. The use of ceramic filter means that the running system can be used for its primary purpose of metal delivery to the cavity of the casting, whilst cleanliness is controlled by filter, to give inclusion-free casting and to improve yield [37]. 3.2 MICROSTRUCTURE Two samples from each melt were taken, one from the middle and the other from the bottom. These samples were sectioned from the test bars. Later these were mounted in thermoplastic and marked for identification. Conventional metallographic preparation techniques were used. The microstructural study was carried out using Leica optical microscope and Olympus microscope. The nodule count and nodularity of the samples was carried out using an image analyzer installed at the university of Birmingham, UK. 3.3 SALTS USED The salts used for austempering were purchased from the local market. Different companies are selling their salts with their own fabricated names.
  • 65. lxv 3.4 EQUIPMENTS USED 3.4.1 Melting Furnaces Different furnaces were used for the melting of metal during the present work. These are listed below. 1. Gas Fired Furnace: The gas fired furnace of capacity 60 kg was used to produce the ductile iron for the initial heats. It was fitted with a blower. Natural gas was fed to the furnace for the melting of the metal. 2. Induction Furnaces: Two furnaces were used for the melting of iron. The Inductotherm medium frequency induction furnace of capacity 28 kg was used. It was installed at the University of Birmingham, UK. The second furnace was a high frequency induction furnace of capacity 100 kg installed at a commercial foundry, Lahore (Pakistan). 3.4.2 Heat Treatment Furnaces Different types of furnaces were used for the heat treatment of tensile samples. The majority of samples were heat treated at the University of Engineering and Technology, Lahore (Pakistan) and some of the samples were heat treated by ADI Treatment, UK. The details of furnaces are given below. Muffle Furnace The austenitizing heat treatment of the samples were carried out in a muffle furnace installed at Materials Research Laboratory, Research Centre University of Engineering and Technology, Lahore ( Pakistan ). The samples were austenitized in
  • 66. lxvi Carbolite Furnace, Type GPC 13/36 with 9000 watts and its maximum temperature limit was 1300 o C . Vertical tube furnace The tensile samples were austempered in salt bath placed in a vertical furnace fitted at Research Centre of University of Engineering & Technology, Lahore (Pakistan). The samples were austempered in salt bath using Carbolite Furnace Type VCF 12/10 with 3000 watts and its maximum temperature limit was 1200o C. Quench Austempered Furnace The heat treatment of some of the tensile samples was carried out by ADI Treatment Ltd., UK as the heat treatment facilities were not available at the time of experimentation at the University Birmingham, UK. The ADI Treatment Ltd., were kind enough to carry out the heat treatment at their premises. The organization is ISO 9000: 2000 certified. It is equipped with most modern furnaces using controlled atmosphere belt. ADI Treatment Ltd. had installed the world‟s largest sealed quench austempering furnace facility which provides controlled atmosphere heat treatment. The patented design incorporated a controlled atmosphere bath with recirculating roof fans, radiant tubes, intermediate purge transfer chamber, and vestibule austempering quench tank. 3.4.3 Microscopes Used For microstructural study the following microscopes and image analyzer were used. Optical Microscopes Leica optical microscope was used for microstructural study which was installed at the University of Birmingham, UK. It was fitted with a camera. The second
  • 67. lxvii microscope which was used was Olympus Inverted Metallurgical Microscope PME-3- 312B installed at the Research Centre of the University of Engineering and Technology, Lahore. The specimens for the microscope were prepared by using conventional method. For etching the samples 4 % nital was used. Scanning Electron Microscope Hitachi S-3000H scanning electron microscope was used for the microstructure study. The microscope is fitted at Research Centre of the University of Engineering & Technology, Lahore, (Pakistan) Image Analyzer To find out the nodularity and nodule count, the image analyzer was used fitted at Interdisciplinary of Research Centre, University of Birmingham, UK 3.4.4 Tensile Testing Machines The tensile samples alloyed with lanthanum were tested using Instron Universal Testing Machine Model 1195, capacity 100 kn, installed in the laboratory of Pakistan Quality & Standards Control Authority, Lahore. The machine uses interchangeable load cell to detect the load on the sample under test. The load is measured by an electrical sensing device which produces signals corresponding to load variations. The second tensile testing machine was Universal Tensile Testing Machine Shimadzu UH-F-500 KNA that was used for the testing of samples alloyed with copper, nickel and a combination of copper and nickel. This machine was installed at Civil Engineering Department of University of Engineering and Technology, Lahore.
  • 68. lxviii Chapter - 4 RESULTS AND DISCUSSION Different variables have been studied during the present research. The first variable was the effect of austempering time on ductile iron. The second variable was the effect of austenitizing temperature on the ductile iron. The third major variable was the effect of alloying additions on the ductile iron. The alloying elements selected for this purpose were copper, nickel, a combination of copper and nickel and lanthanum. 4.1 EFFECT OF AUSTEMPERING TIME ON DUCTILE IRON To find out the effect of time on austempering time on tensile strength of ductile iron temperature, the tensile samples were austenitized at 900o C for one hour and then austempered at 270o C and 370o C for three different length of time i.e. half an hour, one hour and one and a half hours. The results are shown in Table 4.1. It can be seen from the table 4.1 that the average tensile strength was 968.9 N/mm2 , when the samples were austenitized at 900o C and austempered for ½ hour at 270o C but it became 1360.9 N/mm2 when the time was increased from half an hour to one hour. When the austempering time was further increased to 1 ½ hour, it was revealed that the tensile strength was decreased to 1312.3 N/mm2 at the same austempering temperature i.e. 270o C. However, the tensile strength of the samples which were austentized at 900o C and austempered for ½ hour at a temperature of 370o C was 811.8 N/mm2 . This value increased to 925.2 N/mm2 when the sample was autenitized at 900o C
  • 69. lxix and the austempered at 370 o C for 1 hour. The austempering time was increased to 1 ½ hour. The tensile strength again decreased to 817.5 N/mm2 . Table 4.1: Effect of Time on the Tensile Strength of Ductile Iron No. Austenitizing Temp. o C Austempering Temp. o C Austempering Time (Hours) Elog. % UTS N/mm2 1 2 3 900 900 900 270 270 270 ½ 1 1 1/2 1.2 1.3 1.2 968.9 1360.9 1312.3 4 5 6 900 900 900 370 370 370 ½ 1 1 1/2 2.5 2.7 2.6 811.8 925.2 817.5 5 Without any treatment 4.0% 696.4 Figure 4.1 Effect of time on tensile strength of ductile iron austenitized at 900o C and austempered at 270o C.
  • 70. lxx Figure 4.2 Effect of time on tensile strength of ductile iron austenitized at 900o C and austempered at 370o C. Figures 4.1 and 4.2 show that there was a gradual increase of tensile strengths when the samples were autenitized at 900o C and austempered at 270o C and 370o C. Tensile strength went on increasing up to one hour austempering time in both the cases. The tensile strength decreased when austempering time was further increased. The effect of time on austempering was studied by changing the time duration of austempering while other parameters i.e. austenitizing temperature was fixed at 900 o C and austempering temperatures were fixed at 270 o C and 370 o C. The austempering time was changed from half an hour to one and a half hour. The tensile strength went on increasing up to one hour but decreased at 1½ hour. It was observed that the optimum time for austempering was one hour. The second stage started after the austempering time was longer than one hour. In this stage, high carbon austenite decomposed to ferrite and carbide.
  • 71. lxxi It was also pointed out by Y. Lin [38] that after completing the first stage, the microstructure of matrix in austempered ductile iron (ADI) contains acicular ferrite and carbon rich austenite, giving ADI the outstanding mechanical properties of high strength and good ductility. If the isothermal holding time is long enough to permit the reaction to reach the second stage, the carbon rich austenite will decompose into ferrite and carbide. Therefore, the austempering holding time should be controlled at the completion of the first stage and the reaction of second stage should be avoided [38-40]. The two temperatures selected for austempering were 270 o C and 370 o C. The tensile strength was 1360.9 N/mm2 when the samples were austenetized at 900 o C and austempered at 270 o C for one hour but it decreased to 925.2 N/mm2 when these were austempered at 370 o C for one hour. The main reason of this change in value was the formation of upper and lower bainite. Whenever the isothermal transformation of ductile cast iron takes place, a two- stage transformation is involved. In the first stage, austenite decomposes into ferrite and high carbon austenite. In the second stage, this high carbon austenite decomposes into ferrite and carbide. The formation of carbides is detrimental to mechanical properties, so it should be avoided. The second stage also embrittles the material which affects the mechanical properties. The second stage occurs due to long austempering time. Therefore the time should be optimum. This is the reason for keeping austempering time as the first variable to be studied in this study.
  • 72. lxxii 4.2 EFFECT OF AUSTENITIZING TEMPERATURE ON DUCTILE IRON The samples prepared at the University Birmingham, UK, were subjected to different austenitizing temperatures to find out the best austenitizing temperature. The temperature ranged from 850 o C to 925 o C for a fixed austempering time i.e. one hour . The samples were then austempered at 270 o C and 370 o C for one hour which was found to be the optimum austempering time according to the findings of the effect of time on austempering. The results are shown in table 4.2. Table 4.2 Effect of Austenitizing Temperature on Tensile Strength of Ductile Iron Sample No Austenitizing Temperatures C Austempering Temperatures C Tensile Strength N/mm2 1 850 270 1142.47 2 900 270 1313.32 3 925 270 1205.95 4 850 370 991.19 5 900 370 1117.84 6 925 370 1010.46 The samples were austenitized for one hour at 850 o C and austempered at 270 o C the tensile strength was 1142.47 N/mm2 . When the austenitizing temperature was increased to 900 o C the tensile strength increased to 1313.32 N/mm2 and on further increasing the austenitizing temperature to 925o C, the tensile strength decreased to 1205.95 N/mm 2 .
  • 73. lxxiii Afterwards, austenitizing temperatures were kept the same i.e. 850 o C, 900 o C and 950 o C but the austempering temperature was increased to the upper limit temperature i.e. 370 o C to find out its effect on the tensile strength. The tensile strength showed the same pattern as in the previous experiment. When the samples were austempered at temperature 850 o C and austempered at 370o C their tensile strength was 991.19 N/mm2 ; when the austenitizing temperature was increased to 900 o C, the tensile strength increased to 1117.84 N/mm2 , but it decreased to 1010.46 N/mm2 by austenitizing at 925o C. Figure 4.3 Effect of austenitizing temperature on the tensile strength of ductile iron austempered at 270o C.
  • 74. lxxiv
  • 75. lxxv Figure 4.4 Effect of austenitizing temperature on the tensile strength of ductile iron austempered at 370o C. Figure 4.3 and 4.4 show that there is a gradual increase of tensile strength upto 900o C (austenitizing temperature) i.e. 1313.3 and 1117.8 N/sq-mm when the samples were austempered at 270o C and 370o C respectively. When austenitizing temperature was increased to 925o C and austempered at 270o C and 370o C the values decreased to 1205.9 and 1010.4 N/sq-mm respectively. It was observed that the higher austenitizing temperatures are not good for austempering. J R Keough [16] also pointed out that higher austenitizing temperature made transformation problematic during austempering and reduced mechanical properties after austempering. Similarly P. Shanmugan [41] found that lower austenitizing temperatures are better for fatigue strength. Susal K. et al. [42] also investigated the influence of
  • 76. lxxvi austenitizing temperature on ductile iron. They found that yield strength went on increasing up to 898 o C and the strength decreased at 927 o C. They found that the yield strength was 1228.7 MPa when the samples were austenitized at 871 o C and austempered at 302 o C. When the temperature was increased to 898 o C, the yield strength increased to 1246.6 MPa .But when the austentizing temperature was further increased to 927 o C the yield strength decreased to1195.5 MPa under the same condition. The findings of the present study are supported by the experiments conducted by P.Shanmugan and Susal K.et al. 4.3 EFFECT OF ALLOYING ELEMENTS ON DUCTILE IRON Alloying additions are used for different purposes but mainly to increase mechanical properties especially to increase hardenability. Several alloying elements are used. Molybdenum is effective in increasing the hardenability [43]. There are some disadvantages in the use of larger molybdenum addition; these are relatively high cost and effect of this element also reduces ductility [44-46]. Manganese is a relatively cheap element but it tends to segregate in cast irons during solidification and additions exceeding 0.3 wt.% to austempered nodular irons reduce ductility as a result of embrittlement at cell boundaries [47]. However, Molybdenum has relatively small carbide- stabilizing effect and causes a large increase in hardenability, so it has been studied by several researchers [48-50]. In order to make austempered ductile iron with the required strength and ductility, alloying elements can be added to conventional ductile iron. These elements must play roles to avoid pearlite formation as well as stabilize austenite during austempering treatment. In that way ductile irons can produce a supersaturated austenite
  • 77. lxxvii and therefore ausferrite phase can be achieved [51]. Molybdenum plays a significant role in increasing the hardenability of ductile iron [52]. A combination of nickel, copper and molybdenum was typically added to ductile iron [53-56]. 4.3.1 Effect of Copper on the Tensile Strength of Ductile Iron To find out effect of copper, four heats were made with 0.0 wt. %, 0.5 wt %, 1.0 wt. % and 1.5 wt. % by wt. in a commercial foundry. The tensile samples were machined from the castings. The samples were austenitized in a Carbolite muffle furnace at a temperature of 900 C for one hour and austempered at 270 o C and 370 o C for one hour. Then the tensile test was performed. The results are tabulated in table 4.3. Table 4.3 Effect of Copper on Tensile Strength of Ductile Iron Copper UTS N/mm2 0.0 wt % UTS N/mm2 0.5 wt % UTS N/mm2 1.0 wt % UTS N/mm2 1.5 wt % Without heat- treatment 495.3 517.6 581.7 705.7 Austempered at 270 o C 938.8 988.8 1096.1 1222.4 Austempered at 370 o C 698.0 816.7 828.3 911.6 The tensile strength of ductile iron samples was 495.3 N/mm2 without any addition of copper to the heat. When copper addition of 0.5 wt % was made in the ductile iron, the tensile strength increased to 517.6 N/mm2 . With the copper addition of 1.0 wt %, the tensile strength increased to 581.7 N/mm2 . When the copper addition was further
  • 78. lxxviii increased to 1.5 wt %, the tensile strength again increased to 705.7 N/mm2 . Figure 4.5 shows the gradual increase of tensile strength with the increase of copper content without any heat treatment. The samples were then austenitized at 900 o C for one hour and austempered at 270 o C. The tensile strength of ductile iron samples was 938.8 N/mm2 without any addition of copper to the melt. With the copper addition of 0.5 wt % in the ductile iron the tensile strength increased to 988.8 N/mm2 . When the copper addition was increased to 1.0 wt %, the tensile strength was increased to 1096.1 N/mm2 . When the copper addition was further increased to 1.5 wt %, the tensile strength was also increased to 1222.4 N/mm2 . Now the austempering temperature was increased. After austenitizing at 900 o C for one hour, the samples were transferred quickly to salt bath maintained at 370 o C for a time period of one hour. The tensile strength of ductile iron samples was 698.0 N/mm2 without any addition of copper. With the copper addition of 0.5 wt % in the ductile iron the tensile strength increased to 816.7 N/mm2 . The copper addition was further increased to 1.0 wt %, the tensile strength also increased to 828.3 N/mm2 . When the copper addition was increased to 1.5 wt %, the tensile strength increased to 911.6 N/mm2 . (table 4.3). The graphical representation of increase of tensile strength when the samples were austempered at 370o C is shown in figure 4.6.
  • 79. lxxix Fig. 4.5 Effect of copper on tensile strength without any heat treatment Figure 4.6 shows a similar increase of tensile strength with the increase of copper when the samples were austempered at 270 o C for one hour. Fig. 4.6 Effect of copper on tensile strength when austenitized at 900 o C and austempered at 270 o C.
  • 80. lxxx Figure 4.7 shows the same pattern of increase of tensile strength when the samples were austenitized at 900 o C for one hour and austempered at 370 o C for one hour. Fig. 4.7 Effect of copper on tensile strength when austenitized at 900 o C and austempered at 370 o C for one hour. The present results are similar to the research conducted by Yoon-Jun Kim et al, [51]. In their study, the samples were alloyed with copper and molybdenum and austenitized at 910 o C for 90 minutes and subsequently austempered in salt bath. They found that copper and molybdenum addition played an effective role in the formation of ausferrite structure as well as an increment of mechanical properties such as tensile strength and hardeability. Another study by A.A. Cushway [43] revealed that copper addition up to 1.5 wt. percent increased the hardenability of nodular iron. He further found that the addition of copper above 1.5 percent resulted in no further increase in hardenability. In the present study the tensile strength also went on increasing up to 1.5 wt. percent of copper addition.
  • 81. lxxxi Guerin et al [57] made alloying addition of copper, tin and a combination of manganese and copper to ductile iron. They found that the use of manganese (% Mn > 0.4 %) or tin (% Sn > 0.07 %) caused the formation of embritlling intercellular phases. The best mechanical properties were obtained with 1.48 wt. per cent of copper. They further found that manganese and tin were less effective than copper to harden and strengthen ductile iron. P.W. Sheton and A. A. Bonner [58] reported that when copper was added in quantities exceeding the limits of solid solubility in ferrous alloys (0.7 wt. %) it significantly improved its strength and toughness. These results are in agreement with the present study. 4.3.2 Effect of Nickel on Tensile Strength of Ductile Iron The effect of nickel on ductile iron was studied by preparing different heats with 1.0 wt.%, 2.0 wt.% and 3.0 wt. % nickel addition. The tensile samples were made from the castings made by the Y block pattern. Then these tensile samples were subjected to tensile test with and without heat treatment. The test results are tabulated in the table 4.4. Table 4.4 Effect of Nickel on Tensile Strength of Ductile Iron Nickel UTS N/ mm2 0.0 wt. % UTS N/ mm2 1.0 wt. % UTS N/ mm2 2.0 wt. % UTS N/ mm2 3.0 wt. % Without heat- treatment 495.3 552.4 575.3 628.2 Austempered at 270 C 938.8 970.5 979.7 1082.5 Austempered at 370 C 698.0 721.18 732.8 917.7
  • 82. lxxxii The present results showed that there is a gradual increase in the tensile strength of ductile iron with the increase of nickel content without heat treatment. The tensile strength was 495.3 N/mm2 without any addition of nickel. By adding of 1.0 wt.% of nickel, the tensile strength increased to 552.4 N/mm2 (table 4.4). When 2.0 wt % nickel was added in the ductile iron, the tensile strength increased to 575.3 N/ mm2 . Further increasing of nickel content to 3.0 wt %, the tensile strength also increased to 628.2 N/mm2 . The ductile iron samples were then heat treated by austenitizing the samples at 900o C for one hour and austempered at 270 o C for one hour. The tensile strength of ductile iron samples was 938.8 N/ mm2 without any addition of nickel to the melt. With the nickel addition of 1.0 wt. % in the ductile iron, the tensile strength increased to 970.5 N/ mm2 . When the quantity of nickel was increased to 2.0 wt % in the ductile iron, the tensile strength again increased to 979.7 N/ mm2 . When the nickel addition was further increased to 3.0 wt. %, the tensile strength again increased to 1082.5 N/mm2 (table 4.4). Now the salt bath temperature was increased to 370 o C for austempering. After austenitizing at 900 o C for one hour, the samples were austempered for one hour. The tensile strength of ductile iron samples was 698.0 N/ mm2 without any addition of nickel. With the nickel addition of 1.0 wt % in the ductile iron the tensile strength increased to 721.1 N/ mm2 . When the 2.0 wt % nickel was added to the ductile iron, the tensile strength also increased to 732.8 N/ mm2 . When the nickel addition was further increased
  • 83. lxxxiii to 3.0 wt. %, the tensile strength again showed the similar tendency and it increased to 917.7 N/ mm2 (table 4.4). The effect of nickel was studied by making melts with nil to 3 wt. % nickel. The addition of varying quantities of nickel to the ductile iron showed a positive effect of mechanical properties of ductile iron by increasing its tensile strength in a proportionate manner. The graphs shown in figures 4.8, 4.9 and 4.10 revealed the gradual increase of tensile strength with the increase of nickel content with and without any heat treatment. Figure 4.8 shows that with the increase of nickel quantity the tensile strength increased without any heat treatment. Fig. 4.8 Effect of nickel on tensile strength without any heat treatment When the samples are austenitized at 900 o C and austempered at 270 o C, the increase in tensile strength can be seen in figure 4.9.
  • 84. lxxxiv Fig. 4.9 Effect of nickel on tensile strength when austenitized at 900 o C and austempered at 270 o C When the tensile samples were austenitized at 900 o C and austempered at 370o C, the tensile strength again increased. The slope in figure 4.10 is not as steep as in case of austempering at 270 o C in figure 4.9. Fig. 4.10 Effect of nickel on tensile strength when austenitized at 900 o C and austempered at 370 o C
  • 85. lxxxv Cheng-Hsun Hsu et al [59] studied the mechanical properties of cobalt and nickel alloyed ductile irons. They found that the highest strength was achieved with the addition of 4.0 % nickel. They found that the tensile strength of unalloyed ductile iron was 463 MPa but when the ductile iron was alloyed with 4. 0 wt % nickel the tensile strength increased to 1025 MPa. In the present study, the highest strength of ductile iron produced in a commercial foundry using local raw materials without any heat treatment was 495.3 N/mm2 and with 3.0 wt % nickel, it increased to 628.2 N/ mm2 .There is tendency of increasing tensile strength in all the samples. The author could make nickel addition up to 3.0 wt. % only due to financial constraints. Both copper and nickel are austenite stabilizers, so they widen the austenite zone of phase diagram. As both copper and nickel are austenite stabilizers. Both copper and nickel move the nose of isothermal diagram to right, and make the transformation even easier as the cooling rate is lower. Both copper and nickel increase the hardenability; however the information of these two elements on the mechanical properties is limited. 4.3.3 Effect of a combination of Copper and Nickel on Ductile Iron In this study, ductile iron was alloyed in different combinations of copper and nickel. Three melts of ductile iron were made as given below 1. 0.5wt% copper and 1.0wt% nickel
  • 86. lxxxvi 2. 1.0wt% copper and 2.0wt% nickel 3. 1.5wt% copper and 3.0wt% nickel. The tensile strength was compared with unalloyed ductile iron. The test results of tensile strength of unalloyed ductile iron and alloyed ductile iron with copper and nickel together without heat treatment and with heat treatment are shown the table 4.5 Table 4.5 Effect of Copper and Nickel together on Tensile Strength of Ductile Iron Copper Nickel UTS N/ mm2 0.0 wt % 0.0 wt % UTS N/ mm2 0.5 wt % 1.0 wt % UTS N/ mm2 1.0 wt % 2.0 wt % UTS N/ mm2 1.5 wt % 3.0 wt % Without heat- treatment 495.3 544.0 552.7 576.8 Austempered at 270 o C 938.8 1034.3 1055.3 1164.1 Austempered at 370 o C 698.0 715.7 738.7 787.3 The tensile strength of ductile iron samples without any addition of copper and nickel was 495.3 N/mm2 (without any heat treatment). When copper addition of 0.5 wt % along with 1.0 wt % nickel was made in the ductile iron the tensile strength increased to 544.4 N/mm2 . With the copper addition of 1.0 wt% and nickel 2.0 wt % in the ductile iron, the tensile strength increased to 552.7 N/mm2 . When the copper addition was further increased to 1.5 wt % in combination of 3.0 wt %nickel, the tensile strength again increased to 576.8 N/mm2 , (table 4.5).
  • 87. lxxxvii The samples were then austenitized at 900 o C for one hour and austempered at 270 o C. The tensile strength of ductile iron samples was 938.8 N/mm2 without any addition of copper and nickel to the melt. With the copper addition of 0.5 wt % in combination of 1.0 wt % nickel in the ductile iron the tensile strength increased to 1034.3 N/mm2 , (table 4.5). When the copper addition was increased to 1.0 wt % with 2.0 wt % nickel in the ductile iron, the tensile strength increased slightly to 1055.3 N/mm2 . The copper addition was further increased to 1.5 wt % in combination of 3.0 wt %, the tensile strength showed a similar pattern and it increased to 1164.1 N/mm2 . When the samples were austenitized at 900 o C for one hour and the austempering temperature was increased to 370 o C, the tensile strength of ductile iron samples was 698.0 N/mm2 without any addition of copper and nickel. With the copper addition of 0.5wt % and 1.0 wt % nickel in the ductile iron the tensile strength increased to 715.7 N/mm2 . When the copper addition was further increased to 1.0 wt % along with 2.0 wt % nickel in the ductile iron, the tensile strength also increased to 738.7 N/mm2 . When the copper addition was further increased to 1.5 wt % in combination of 3.0 wt nickel, the tensile strength again increased to 787.3 N/mm2 (table 4.5). The samples with different combinations of copper and nickel were austenitized at 900 o C and austempered at 270 o C and 370 o C. The results showed the same pattern as with copper and nickel addition separately but there was not a significant increase in the tensile strength in combination of copper and nickel.
  • 88. lxxxviii Fig. 4.11 Effect of copper and nickel without heat treatment. Figure 4.12 Effect of copper and nickel together on tensile strength of ductile iron when austenitized at 900 o C and austempered at 270 o C.
  • 89. lxxxix Fig. 4.13 Effect of copper and nickel on tensile strength when austenitized at 900o C and austempered at 370 o C The above figures 4.11-4.13 show the gradual increase in tensile strength with the increase of a combined effect of copper and nickel. To achieve a good hardenabilty and tensile strength it is advisable to use comparatively cheap alloying addition i.e. copper rather using an expensive nickel alloy. Both copper and nickel can be used to increase the hardenability of ductile iron. More information on the effect of addition of copper or nickel is limited [43]. 4.3.4 Effect of Lanthanum on Ductile Iron Lanthanum and other rare earth metals (REM) have been utilized in molten metal processing in a number of ways. For ductile iron production, rare earth metals have been used to modify cast iron eutectic structures. In addition to use REM to neutralize