The document discusses the need to clean stainless steel surfaces after fabrication. It provides context on stainless steel grades and their varying levels of corrosion resistance and pickleability. Higher alloy stainless steels are more difficult to clean due to their composition. The document outlines different surface finishes and defects that may occur and need cleaning. It describes various mechanical and chemical cleaning methods and considerations for choosing an appropriate cleaning process.
This document provides information on cleaning stainless steel surfaces. It discusses why cleaning is important for maintaining corrosion resistance and outlines common surface defects like heat tint, weld defects, iron contamination, and organic contamination. It then describes mechanical cleaning methods like grinding, blasting, and brushing as well as chemical methods like electropolishing and pickling. Pickling involves using an acid mixture, and its effectiveness depends on factors like the steel grade, surface condition, acid composition/concentration, and temperature. The document provides guidance on pickling procedures and concludes with a table comparing the pickleability of different stainless steel grades.
Weld Purging ~ Corrosion Problems in Stainless Steel by WeldingRon Sewell
Abstract
Corrosion is not uncommon in stainless steels, despite their name. Salt water environments in particular can give rise to corrosion and this is even noticeable at domestic level where cutlery discolours in mild salt solutions during dishwashing cycles. Loss of corrosion resistance during welding takes place when oxygen levels in shield and purge gases are high enough to deplete the chromium content.
Experimental Study on Surface Roughness by Using Abrasive ParticlesIJERA Editor
New advancement of technology and never satisfying demands of the civilization are putting huge pressure on the natural fuel resources and these resources are at a constant threat to its sustainability. Surface finish has a vital influence on functional properties such as wear resistance and power loss due to friction on most of the engineering components. Voltage, mesh number, revolutions per minute (rpm) of electromagnet, and percentage weight of abrasives has been identified as important process parameters affecting surface roughness. The experiments were planned using response surface methodology and percentage change in surface roughness (ΔRa) was considered as response. Analysis of experimental data showed that percentage change in surface roughness (ΔRa) was highly influenced by mesh number followed by percentage weight of abrasives, rpm of electromagnet, and voltage. The process has been investigated extensively in the finishing of cylindrical surfaces. The surface finish was found to improve significantly with an increase in the grain size, relative size of abrasive particles vis-à-vis the iron particles, feed rate and current. Super finishing is a micro-finishing process that produces a controlled and smooth surface condition on work pieces. It is not primarily a sizing operation, its major purpose is to produce a surface on a work piece capable of sustaining uneven distribution of a load by improving the geometrical accuracy. The wear life of the parts micro finished to maximum smoothness is extended considerably. According to the design of experimentation, mathematical model for Lapping operation on advance ceramic material is proposed. In order to get minimum values of the surface roughness, optimization of the mathematical model is done and optimal operation of the examined factors is going to be determined. The obtained res
Painting structural steel at a fabrication shop offers advantages over field painting like better control over weather and application. Shops have used these advantages to produce high quality coatings work. Successful shop painting depends on controlling factors like steel design, surface preparation, coatings application, and work procedures to ensure coating quality. Proper techniques are needed for tasks like abrasive blasting, coating application, and handling of steel pieces.
Cleaning and descaling stainless steel 9001markexd25
This document provides information on cleaning and descaling stainless steels. It discusses various methods for removing oxide scales from fabrication processes like hot forming, welding, and thermal treatments. These include acid pickling using hydrochloric or nitric acid, caustic descaling using alkaline solutions, and sand blasting. It also covers cleaning stainless steel surfaces to remove shop soils, oils, fingerprints and other contaminants using methods like alkaline cleaning, electrolytic cleaning, solvent degreasing, and vapor blasting. Passivation, the use of nitric acid to dissolve iron contamination, is also discussed.
Surface preparation is critical for coating performance and longevity. It involves cleaning the surface of contaminants like mill scale, rust, grease and dirt. The level of cleaning depends on factors like the substrate material and coating system. Common preparation methods include solvent cleaning, abrasive blasting and chemical treatments. Proper surface preparation can increase coating adhesion and the protective life of a paint system by over 80%.
This document provides information on cleaning stainless steel surfaces. It discusses why cleaning is important for maintaining corrosion resistance and outlines common surface defects like heat tint, weld defects, iron contamination, and organic contamination. It then describes mechanical cleaning methods like grinding, blasting, and brushing as well as chemical methods like electropolishing and pickling. Pickling involves using an acid mixture, and its effectiveness depends on factors like the steel grade, surface condition, acid composition/concentration, and temperature. The document provides guidance on pickling procedures and concludes with a table comparing the pickleability of different stainless steel grades.
Weld Purging ~ Corrosion Problems in Stainless Steel by WeldingRon Sewell
Abstract
Corrosion is not uncommon in stainless steels, despite their name. Salt water environments in particular can give rise to corrosion and this is even noticeable at domestic level where cutlery discolours in mild salt solutions during dishwashing cycles. Loss of corrosion resistance during welding takes place when oxygen levels in shield and purge gases are high enough to deplete the chromium content.
Experimental Study on Surface Roughness by Using Abrasive ParticlesIJERA Editor
New advancement of technology and never satisfying demands of the civilization are putting huge pressure on the natural fuel resources and these resources are at a constant threat to its sustainability. Surface finish has a vital influence on functional properties such as wear resistance and power loss due to friction on most of the engineering components. Voltage, mesh number, revolutions per minute (rpm) of electromagnet, and percentage weight of abrasives has been identified as important process parameters affecting surface roughness. The experiments were planned using response surface methodology and percentage change in surface roughness (ΔRa) was considered as response. Analysis of experimental data showed that percentage change in surface roughness (ΔRa) was highly influenced by mesh number followed by percentage weight of abrasives, rpm of electromagnet, and voltage. The process has been investigated extensively in the finishing of cylindrical surfaces. The surface finish was found to improve significantly with an increase in the grain size, relative size of abrasive particles vis-à-vis the iron particles, feed rate and current. Super finishing is a micro-finishing process that produces a controlled and smooth surface condition on work pieces. It is not primarily a sizing operation, its major purpose is to produce a surface on a work piece capable of sustaining uneven distribution of a load by improving the geometrical accuracy. The wear life of the parts micro finished to maximum smoothness is extended considerably. According to the design of experimentation, mathematical model for Lapping operation on advance ceramic material is proposed. In order to get minimum values of the surface roughness, optimization of the mathematical model is done and optimal operation of the examined factors is going to be determined. The obtained res
Painting structural steel at a fabrication shop offers advantages over field painting like better control over weather and application. Shops have used these advantages to produce high quality coatings work. Successful shop painting depends on controlling factors like steel design, surface preparation, coatings application, and work procedures to ensure coating quality. Proper techniques are needed for tasks like abrasive blasting, coating application, and handling of steel pieces.
Cleaning and descaling stainless steel 9001markexd25
This document provides information on cleaning and descaling stainless steels. It discusses various methods for removing oxide scales from fabrication processes like hot forming, welding, and thermal treatments. These include acid pickling using hydrochloric or nitric acid, caustic descaling using alkaline solutions, and sand blasting. It also covers cleaning stainless steel surfaces to remove shop soils, oils, fingerprints and other contaminants using methods like alkaline cleaning, electrolytic cleaning, solvent degreasing, and vapor blasting. Passivation, the use of nitric acid to dissolve iron contamination, is also discussed.
Surface preparation is critical for coating performance and longevity. It involves cleaning the surface of contaminants like mill scale, rust, grease and dirt. The level of cleaning depends on factors like the substrate material and coating system. Common preparation methods include solvent cleaning, abrasive blasting and chemical treatments. Proper surface preparation can increase coating adhesion and the protective life of a paint system by over 80%.
This document provides guidelines for inspecting and repairing hot dip galvanized coatings. It discusses testing coating thickness and uniformity, evaluating surface conditions, and repair procedures. The minimum coating thicknesses specified in standards are summarized in tables for different material thicknesses and classes of work. Factors that can influence coating thickness and uniformity are also outlined.
Case study for material selection (Automobile Silencer)Nishit Karkar
This document discusses material selection for automobile silencers and catalytic converters. It provides details on the manufacturing process, technical aspects, and criteria for selecting materials for silencers. Common materials used include steel, stainless steel, cast iron, and alloys for their mechanical properties, corrosion resistance, and ability to withstand high exhaust temperatures. The document also discusses the material requirements and alternatives for catalytic converters, focusing on a ferrite alloy and stainless steel sheet that is pre-oxidized to provide a surface for catalyst adhesion.
Corrosion various concepts and reasons of corrosion and measuresMohd Haris
This document discusses corrosion resistant materials used in pharmaceutical equipment fabrication. It notes that Title 21 CFR regulations require equipment surfaces contacting drugs to not react or absorb in a way that alters safety. Austenitic stainless steels and higher alloys like nickel are generally used for applications requiring high corrosion resistance. Welding must meet ASME and customer specifications. Over time, highly corrosion resistant materials like alloy 316L stainless steel and nickel alloys have replaced standard stainless steel due to better resistance to chemistry and heat treatment issues. Electro-polishing stainless steel improves corrosion resistance and cleanability. Fluoropolymers like Teflon are highlighted as the most functional modern construction material due to their chemical inertness and non-wetting properties
The document describes the various steel treatment and painting processes used on Atlas Copco generators and light towers to protect them from corrosion when exposed to outdoor environments. Different components receive different treatments based on their exposure and importance. All steel components receive a galvanization treatment before further treatments and painting. The canopy receives powder coating, while critical components and the base frame undergo nitrogen laser cutting and cataphoresis before final painting. These treatments help provide long-term corrosion protection and extend the life of components.
This document discusses welding solutions for the chemical industry from voestalpine Böhler Welding. It provides an overview of their expertise in welding applications for the chemical industry, lists their global industry segment manager as a point of contact, and promotes their three specialized brands for catering to customer needs. The company focuses on filler metals and technical consultation for industrial welding and possesses deep technical understanding of industry applications and processes.
A seminar report on control of corrosion on underwater pilesRam Sayan Yadav
This document is a seminar report on controlling corrosion on underwater piles. It provides background on corrosion mechanisms of steel in seawater and defines zones of corrosion on steel piles. It then discusses corrosion management in three phases: assessment, physical assessment and remediation, and future monitoring. The report also describes various corrosion protection methods like protective coatings (inorganic zinc silicates primers, high build epoxy coatings, aliphatic polyurethane topcoats, zinc rich epoxy primers, non-skid deck coatings) and cathodic protection (suspension anodes, rod anodes). It gives examples of applying FRP composites on bridges to control corrosion.
Corrosion Prevention and Corrosion Repair of Steel ReinforcementIRJET Journal
This document discusses corrosion prevention and repair techniques for steel reinforcement in concrete. It begins by defining corrosion and its causes, such as chemical reactions between iron and oxygen/moisture in the environment. Some effects of corrosion are loss of material properties and increased maintenance costs. The document then examines various corrosion prevention techniques, including applying anti-corrosion coatings like cement slurry mortar, epoxy zinc, and polymer-modified cement to steel reinforcement. It also discusses methods for improving the chloride resistance of concrete and corrosion resistance of reinforcement, such as using mineral additions.
This document is a seminar report on controlling corrosion on underwater piles. It discusses corrosion mechanisms in seawater and defines four zones of corrosion: atmospheric, splash, tidal, and submerged. It outlines a three-phase corrosion management program involving assessment, remediation, and monitoring. Finally, it examines various corrosion protection methods including protective coatings, cathodic protection, and the application of fiber reinforced polymer composites to piles.
Internal corrosion of pipelines can be caused by chemicals in the transported fluid reacting with the pipe metal. Common causes include water, CO2, H2S, oxygen, bacteria, and other impurities. Techniques to control internal corrosion include pigging to remove deposits, using corrosion inhibitors added to the fluid, and lining the pipe interior. Corrosion is monitored using techniques such as residual inhibitor analysis, corrosion coupons, electrical probes, and non-destructive testing.
1. The document provides an overview of coating techniques used by Technip Singapore including for offshore pipeline installation, offshore structure installation, fabrication services, and diving.
2. It discusses the instructor's background and contact information, as well as Technip Singapore's capabilities in areas like shallow to deep water pipelay, rigging of pipes, and installation of platforms and subsea structures.
3. Abbreviations commonly used in coating projects are defined.
Educational Presentation High Performance MetalsJimHalliday
Stainless steel is a highly durable and sustainable material that offers significant lifecycle cost savings compared to other metals due to its corrosion resistance and low maintenance needs. It can last the entire lifespan of a building with little to no upkeep and is fully recyclable. Specifying stainless steel can help contribute to LEED certification points and green building standards due to its environmental benefits. The document provides information on stainless steel grades, fabrication, finishes, examples of architectural applications, and corrosion resistance testing to help designers understand why it is a smart choice for their projects.
This document provides an overview of mass finishing processes and techniques. It discusses the relationship between mass finishing and manufacturing quality. Mass finishing can improve surfaces, reduce costs, and enhance product quality. Different mass finishing methods are described, including rotary barrel, vibratory, centrifugal disc, and spindle finishing. Media types, compounds, and applications for various mass finishing operations are also outlined.
The document discusses surface preparation methods for bonding with industrial adhesives. It emphasizes that surface preparation is critical for achieving a strong bond, as the adhesive must adhere well to the substrates. The types of surface preparation depend on the expected performance requirements, service conditions, and cost considerations. Common preparation methods include degreasing to remove oils and greases, abrading to increase surface area, and special pretreatments like plasma treatment or chemical etching. Thorough cleaning without contamination is important for optimal bonding.
The document discusses different methods for surface preparation and cleaning prior to coating application. It outlines 6 stages of surface preparation including cleaning, removing old coatings and contaminants, profiling the surface, and drying. Various mechanical, chemical, and solvent-based cleaning methods are described at length, including abrasive blast cleaning levels from light blast to white metal blast. Flame cleaning of structural steel is also mentioned. The document provides detailed classifications and standards for solvent and abrasive blast cleaning methods.
Glass-lined steel process equipment is used in virtually all of the world’s pharmaceutical manufacturing facilities and is also widely employed by the chemical, petrochemical, pesticide, metallurgical and food industries. Here are the advantages in using this unique material of construction.
TALAT Lecture 5301: The Surface Treatment and Coil Coating of AluminiumCORE-Materials
This lecture describes the continuous coil coating processes for aluminium in sufficient detail in order to understand the industrial coating technology and its application potential. General background in materials engineering and familiarity with the subject matter covered in TALAT This lectures 5100 and 5200 is assumed.
Waste Minimization and Cost Reduction in Process Industriesijsrd.com
The complete process of iron angles processing; machining and coating by Kalpataru Power Transmission Ltd. has been studied in detail. The different phases of production of the iron/steel angles include automation, CNC machines, Robo arms, overhead cranes and other mechanical equipments. After the straightening, shearing, punching, stamping, heating & bending operations are performed upon the different sections; each set of parts follow a sequence of processes. Once the sections are done with the machining processes, they follow the hot dip galvanization process. Surface Fluxing is the primary stage; followed by Steel Galvanizing and finally dichromate quenching. All the sections are arranged in their respective jigs. These structures or frames are handled by the overhead cranes and dipped in various tubs and lifted from them. Initially, the sections perform hot caustic degreasing followed by Hydrochloric acid pickling. Now these sections are rinsed in water and then soaked in a hot pre-flux. Before dipping into the Zinc tub, these sections are dried in the oven so that wet sections do not splash zinc off the tub. After taking out from the zinc tub, it is quenched in warm water. In the final step of this phase, all these sections are submerged into the dichromate solution to emboss a glossy texture. Here, in the whole coating process, it happens that the sections are to be immersed into various liquid tubs. So, when removing them out, many of the sections fail to be retrieved and remain inside the tub. So this decreases the production though negligible but with a feasible solution, it appears to be worth practicing. The objective of the project is to reduce the loss of iron angles and molten zinc during the coating of iron angles before dispatching.
Araldite Preparacion superficial y pretatamientos. Antala Industria (Spain).Antala Industria
El éxito en las uniones depende de una combinación de múltiples factores, tales como mecánicos, químicos o electrostáticos. La unión es una cuestión de interfaz, ya que el adhesivo tiene que adherirse bien a los sustratos a unir. Por lo tanto, las condiciones de la superficie de las piezas a unir son un factor esencial en el logro de una unión de calidad.
Los Adhesivos industriales Huntsman son adhesivos de alto rendimiento que se adhieren firmemente a la mayoría de los materiales.
Se pueden obtener altas tasas de resistencia después de la eliminación de grasa y partículas sueltas, por ejemplo, óxido, de las superficies a unir.
Sin embargo, cuando se requiere la máxima resistencia y durabilidad a largo plazo. Se recomienda encarecidamente un pretratamiento superficial.
El tipo de preparación de la superficie se lleve a cabo antes de la unión depende de las prestaciones previstas (Figuras 18, 19 y 20), las condiciones de servicio de la unión y consideraciones económicas (relación costes / beneficios).
+34 93 474 66 66 | antala@antala.es
www.antala.es
Araldite surface preparation and pretreatments. Antala Ltd.Antala Ltd.
+44 161 494 1345 | info@antala.co.uk
www.antala.co.uk
Bonding performances are always a combination of multiple
factors, such as mechanical, chemical or electrostatic
interactions. Bonding is a matter of interface, as the adhesive
has to adhere well to the substrates to be bonded. Therefore,
the surface conditions of the parts to be bonded are a critical
factor in achieving a dependable quality bond.
Huntsman industrial adhesives are high performance
adhesives which adhere firmly to most materials. High
strength bonds can be obtained after removal of grease and
loose particles, e.g. rust, from the surfaces to be joined.
However, when maximum strength and long-term durability
are required, a more thorough mechanical or a chemical
surface pretreatment is highly recommended.
The type of surface preparation to be carried out prior to
bonding depends on the expected performances (Figures
18, 19 and 20), the service conditions of the assembly and
economic considerations (ratio costs / benefits).
This document provides guidelines for inspecting and repairing hot dip galvanized coatings. It discusses testing coating thickness and uniformity, evaluating surface conditions, and repair procedures. The minimum coating thicknesses specified in standards are summarized in tables for different material thicknesses and classes of work. Factors that can influence coating thickness and uniformity are also outlined.
Case study for material selection (Automobile Silencer)Nishit Karkar
This document discusses material selection for automobile silencers and catalytic converters. It provides details on the manufacturing process, technical aspects, and criteria for selecting materials for silencers. Common materials used include steel, stainless steel, cast iron, and alloys for their mechanical properties, corrosion resistance, and ability to withstand high exhaust temperatures. The document also discusses the material requirements and alternatives for catalytic converters, focusing on a ferrite alloy and stainless steel sheet that is pre-oxidized to provide a surface for catalyst adhesion.
Corrosion various concepts and reasons of corrosion and measuresMohd Haris
This document discusses corrosion resistant materials used in pharmaceutical equipment fabrication. It notes that Title 21 CFR regulations require equipment surfaces contacting drugs to not react or absorb in a way that alters safety. Austenitic stainless steels and higher alloys like nickel are generally used for applications requiring high corrosion resistance. Welding must meet ASME and customer specifications. Over time, highly corrosion resistant materials like alloy 316L stainless steel and nickel alloys have replaced standard stainless steel due to better resistance to chemistry and heat treatment issues. Electro-polishing stainless steel improves corrosion resistance and cleanability. Fluoropolymers like Teflon are highlighted as the most functional modern construction material due to their chemical inertness and non-wetting properties
The document describes the various steel treatment and painting processes used on Atlas Copco generators and light towers to protect them from corrosion when exposed to outdoor environments. Different components receive different treatments based on their exposure and importance. All steel components receive a galvanization treatment before further treatments and painting. The canopy receives powder coating, while critical components and the base frame undergo nitrogen laser cutting and cataphoresis before final painting. These treatments help provide long-term corrosion protection and extend the life of components.
This document discusses welding solutions for the chemical industry from voestalpine Böhler Welding. It provides an overview of their expertise in welding applications for the chemical industry, lists their global industry segment manager as a point of contact, and promotes their three specialized brands for catering to customer needs. The company focuses on filler metals and technical consultation for industrial welding and possesses deep technical understanding of industry applications and processes.
A seminar report on control of corrosion on underwater pilesRam Sayan Yadav
This document is a seminar report on controlling corrosion on underwater piles. It provides background on corrosion mechanisms of steel in seawater and defines zones of corrosion on steel piles. It then discusses corrosion management in three phases: assessment, physical assessment and remediation, and future monitoring. The report also describes various corrosion protection methods like protective coatings (inorganic zinc silicates primers, high build epoxy coatings, aliphatic polyurethane topcoats, zinc rich epoxy primers, non-skid deck coatings) and cathodic protection (suspension anodes, rod anodes). It gives examples of applying FRP composites on bridges to control corrosion.
Corrosion Prevention and Corrosion Repair of Steel ReinforcementIRJET Journal
This document discusses corrosion prevention and repair techniques for steel reinforcement in concrete. It begins by defining corrosion and its causes, such as chemical reactions between iron and oxygen/moisture in the environment. Some effects of corrosion are loss of material properties and increased maintenance costs. The document then examines various corrosion prevention techniques, including applying anti-corrosion coatings like cement slurry mortar, epoxy zinc, and polymer-modified cement to steel reinforcement. It also discusses methods for improving the chloride resistance of concrete and corrosion resistance of reinforcement, such as using mineral additions.
This document is a seminar report on controlling corrosion on underwater piles. It discusses corrosion mechanisms in seawater and defines four zones of corrosion: atmospheric, splash, tidal, and submerged. It outlines a three-phase corrosion management program involving assessment, remediation, and monitoring. Finally, it examines various corrosion protection methods including protective coatings, cathodic protection, and the application of fiber reinforced polymer composites to piles.
Internal corrosion of pipelines can be caused by chemicals in the transported fluid reacting with the pipe metal. Common causes include water, CO2, H2S, oxygen, bacteria, and other impurities. Techniques to control internal corrosion include pigging to remove deposits, using corrosion inhibitors added to the fluid, and lining the pipe interior. Corrosion is monitored using techniques such as residual inhibitor analysis, corrosion coupons, electrical probes, and non-destructive testing.
1. The document provides an overview of coating techniques used by Technip Singapore including for offshore pipeline installation, offshore structure installation, fabrication services, and diving.
2. It discusses the instructor's background and contact information, as well as Technip Singapore's capabilities in areas like shallow to deep water pipelay, rigging of pipes, and installation of platforms and subsea structures.
3. Abbreviations commonly used in coating projects are defined.
Educational Presentation High Performance MetalsJimHalliday
Stainless steel is a highly durable and sustainable material that offers significant lifecycle cost savings compared to other metals due to its corrosion resistance and low maintenance needs. It can last the entire lifespan of a building with little to no upkeep and is fully recyclable. Specifying stainless steel can help contribute to LEED certification points and green building standards due to its environmental benefits. The document provides information on stainless steel grades, fabrication, finishes, examples of architectural applications, and corrosion resistance testing to help designers understand why it is a smart choice for their projects.
This document provides an overview of mass finishing processes and techniques. It discusses the relationship between mass finishing and manufacturing quality. Mass finishing can improve surfaces, reduce costs, and enhance product quality. Different mass finishing methods are described, including rotary barrel, vibratory, centrifugal disc, and spindle finishing. Media types, compounds, and applications for various mass finishing operations are also outlined.
The document discusses surface preparation methods for bonding with industrial adhesives. It emphasizes that surface preparation is critical for achieving a strong bond, as the adhesive must adhere well to the substrates. The types of surface preparation depend on the expected performance requirements, service conditions, and cost considerations. Common preparation methods include degreasing to remove oils and greases, abrading to increase surface area, and special pretreatments like plasma treatment or chemical etching. Thorough cleaning without contamination is important for optimal bonding.
The document discusses different methods for surface preparation and cleaning prior to coating application. It outlines 6 stages of surface preparation including cleaning, removing old coatings and contaminants, profiling the surface, and drying. Various mechanical, chemical, and solvent-based cleaning methods are described at length, including abrasive blast cleaning levels from light blast to white metal blast. Flame cleaning of structural steel is also mentioned. The document provides detailed classifications and standards for solvent and abrasive blast cleaning methods.
Glass-lined steel process equipment is used in virtually all of the world’s pharmaceutical manufacturing facilities and is also widely employed by the chemical, petrochemical, pesticide, metallurgical and food industries. Here are the advantages in using this unique material of construction.
TALAT Lecture 5301: The Surface Treatment and Coil Coating of AluminiumCORE-Materials
This lecture describes the continuous coil coating processes for aluminium in sufficient detail in order to understand the industrial coating technology and its application potential. General background in materials engineering and familiarity with the subject matter covered in TALAT This lectures 5100 and 5200 is assumed.
Waste Minimization and Cost Reduction in Process Industriesijsrd.com
The complete process of iron angles processing; machining and coating by Kalpataru Power Transmission Ltd. has been studied in detail. The different phases of production of the iron/steel angles include automation, CNC machines, Robo arms, overhead cranes and other mechanical equipments. After the straightening, shearing, punching, stamping, heating & bending operations are performed upon the different sections; each set of parts follow a sequence of processes. Once the sections are done with the machining processes, they follow the hot dip galvanization process. Surface Fluxing is the primary stage; followed by Steel Galvanizing and finally dichromate quenching. All the sections are arranged in their respective jigs. These structures or frames are handled by the overhead cranes and dipped in various tubs and lifted from them. Initially, the sections perform hot caustic degreasing followed by Hydrochloric acid pickling. Now these sections are rinsed in water and then soaked in a hot pre-flux. Before dipping into the Zinc tub, these sections are dried in the oven so that wet sections do not splash zinc off the tub. After taking out from the zinc tub, it is quenched in warm water. In the final step of this phase, all these sections are submerged into the dichromate solution to emboss a glossy texture. Here, in the whole coating process, it happens that the sections are to be immersed into various liquid tubs. So, when removing them out, many of the sections fail to be retrieved and remain inside the tub. So this decreases the production though negligible but with a feasible solution, it appears to be worth practicing. The objective of the project is to reduce the loss of iron angles and molten zinc during the coating of iron angles before dispatching.
Araldite Preparacion superficial y pretatamientos. Antala Industria (Spain).Antala Industria
El éxito en las uniones depende de una combinación de múltiples factores, tales como mecánicos, químicos o electrostáticos. La unión es una cuestión de interfaz, ya que el adhesivo tiene que adherirse bien a los sustratos a unir. Por lo tanto, las condiciones de la superficie de las piezas a unir son un factor esencial en el logro de una unión de calidad.
Los Adhesivos industriales Huntsman son adhesivos de alto rendimiento que se adhieren firmemente a la mayoría de los materiales.
Se pueden obtener altas tasas de resistencia después de la eliminación de grasa y partículas sueltas, por ejemplo, óxido, de las superficies a unir.
Sin embargo, cuando se requiere la máxima resistencia y durabilidad a largo plazo. Se recomienda encarecidamente un pretratamiento superficial.
El tipo de preparación de la superficie se lleve a cabo antes de la unión depende de las prestaciones previstas (Figuras 18, 19 y 20), las condiciones de servicio de la unión y consideraciones económicas (relación costes / beneficios).
+34 93 474 66 66 | antala@antala.es
www.antala.es
Araldite surface preparation and pretreatments. Antala Ltd.Antala Ltd.
+44 161 494 1345 | info@antala.co.uk
www.antala.co.uk
Bonding performances are always a combination of multiple
factors, such as mechanical, chemical or electrostatic
interactions. Bonding is a matter of interface, as the adhesive
has to adhere well to the substrates to be bonded. Therefore,
the surface conditions of the parts to be bonded are a critical
factor in achieving a dependable quality bond.
Huntsman industrial adhesives are high performance
adhesives which adhere firmly to most materials. High
strength bonds can be obtained after removal of grease and
loose particles, e.g. rust, from the surfaces to be joined.
However, when maximum strength and long-term durability
are required, a more thorough mechanical or a chemical
surface pretreatment is highly recommended.
The type of surface preparation to be carried out prior to
bonding depends on the expected performances (Figures
18, 19 and 20), the service conditions of the assembly and
economic considerations (ratio costs / benefits).
Use PyCharm for remote debugging of WSL on a Windo cf5c162d672e4e58b4dde5d797...shadow0702a
This document serves as a comprehensive step-by-step guide on how to effectively use PyCharm for remote debugging of the Windows Subsystem for Linux (WSL) on a local Windows machine. It meticulously outlines several critical steps in the process, starting with the crucial task of enabling permissions, followed by the installation and configuration of WSL.
The guide then proceeds to explain how to set up the SSH service within the WSL environment, an integral part of the process. Alongside this, it also provides detailed instructions on how to modify the inbound rules of the Windows firewall to facilitate the process, ensuring that there are no connectivity issues that could potentially hinder the debugging process.
The document further emphasizes on the importance of checking the connection between the Windows and WSL environments, providing instructions on how to ensure that the connection is optimal and ready for remote debugging.
It also offers an in-depth guide on how to configure the WSL interpreter and files within the PyCharm environment. This is essential for ensuring that the debugging process is set up correctly and that the program can be run effectively within the WSL terminal.
Additionally, the document provides guidance on how to set up breakpoints for debugging, a fundamental aspect of the debugging process which allows the developer to stop the execution of their code at certain points and inspect their program at those stages.
Finally, the document concludes by providing a link to a reference blog. This blog offers additional information and guidance on configuring the remote Python interpreter in PyCharm, providing the reader with a well-rounded understanding of the process.
Software Engineering and Project Management - Introduction, Modeling Concepts...Prakhyath Rai
Introduction, Modeling Concepts and Class Modeling: What is Object orientation? What is OO development? OO Themes; Evidence for usefulness of OO development; OO modeling history. Modeling
as Design technique: Modeling, abstraction, The Three models. Class Modeling: Object and Class Concept, Link and associations concepts, Generalization and Inheritance, A sample class model, Navigation of class models, and UML diagrams
Building the Analysis Models: Requirement Analysis, Analysis Model Approaches, Data modeling Concepts, Object Oriented Analysis, Scenario-Based Modeling, Flow-Oriented Modeling, class Based Modeling, Creating a Behavioral Model.
Redefining brain tumor segmentation: a cutting-edge convolutional neural netw...IJECEIAES
Medical image analysis has witnessed significant advancements with deep learning techniques. In the domain of brain tumor segmentation, the ability to
precisely delineate tumor boundaries from magnetic resonance imaging (MRI)
scans holds profound implications for diagnosis. This study presents an ensemble convolutional neural network (CNN) with transfer learning, integrating
the state-of-the-art Deeplabv3+ architecture with the ResNet18 backbone. The
model is rigorously trained and evaluated, exhibiting remarkable performance
metrics, including an impressive global accuracy of 99.286%, a high-class accuracy of 82.191%, a mean intersection over union (IoU) of 79.900%, a weighted
IoU of 98.620%, and a Boundary F1 (BF) score of 83.303%. Notably, a detailed comparative analysis with existing methods showcases the superiority of
our proposed model. These findings underscore the model’s competence in precise brain tumor localization, underscoring its potential to revolutionize medical
image analysis and enhance healthcare outcomes. This research paves the way
for future exploration and optimization of advanced CNN models in medical
imaging, emphasizing addressing false positives and resource efficiency.
Null Bangalore | Pentesters Approach to AWS IAMDivyanshu
#Abstract:
- Learn more about the real-world methods for auditing AWS IAM (Identity and Access Management) as a pentester. So let us proceed with a brief discussion of IAM as well as some typical misconfigurations and their potential exploits in order to reinforce the understanding of IAM security best practices.
- Gain actionable insights into AWS IAM policies and roles, using hands on approach.
#Prerequisites:
- Basic understanding of AWS services and architecture
- Familiarity with cloud security concepts
- Experience using the AWS Management Console or AWS CLI.
- For hands on lab create account on [killercoda.com](https://killercoda.com/cloudsecurity-scenario/)
# Scenario Covered:
- Basics of IAM in AWS
- Implementing IAM Policies with Least Privilege to Manage S3 Bucket
- Objective: Create an S3 bucket with least privilege IAM policy and validate access.
- Steps:
- Create S3 bucket.
- Attach least privilege policy to IAM user.
- Validate access.
- Exploiting IAM PassRole Misconfiguration
-Allows a user to pass a specific IAM role to an AWS service (ec2), typically used for service access delegation. Then exploit PassRole Misconfiguration granting unauthorized access to sensitive resources.
- Objective: Demonstrate how a PassRole misconfiguration can grant unauthorized access.
- Steps:
- Allow user to pass IAM role to EC2.
- Exploit misconfiguration for unauthorized access.
- Access sensitive resources.
- Exploiting IAM AssumeRole Misconfiguration with Overly Permissive Role
- An overly permissive IAM role configuration can lead to privilege escalation by creating a role with administrative privileges and allow a user to assume this role.
- Objective: Show how overly permissive IAM roles can lead to privilege escalation.
- Steps:
- Create role with administrative privileges.
- Allow user to assume the role.
- Perform administrative actions.
- Differentiation between PassRole vs AssumeRole
Try at [killercoda.com](https://killercoda.com/cloudsecurity-scenario/)
Applications of artificial Intelligence in Mechanical Engineering.pdfAtif Razi
Historically, mechanical engineering has relied heavily on human expertise and empirical methods to solve complex problems. With the introduction of computer-aided design (CAD) and finite element analysis (FEA), the field took its first steps towards digitization. These tools allowed engineers to simulate and analyze mechanical systems with greater accuracy and efficiency. However, the sheer volume of data generated by modern engineering systems and the increasing complexity of these systems have necessitated more advanced analytical tools, paving the way for AI.
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2. 2
MATCHLESS IN STAINLESS
Böhler Welding weldCare is a leading producer of superior
pickling products for stainless steels and special alloys. For
over 50 years Böhler Welding weldCare has worked closely
with leading producers of stainless steel and offers exten-
sive knowledge and a wide range of finishing chemicals:
»
» Pickling Gels
»
» Pastes
»
» Sprays
»
» Liquids and
»
» Cleaning agents.
Using weldCare Finishing Chemicals will restore the surface
and return stainless steel to it‘s original look. Stainless steel
retains its beautiful finish thanks to a protective layer that
forms on the surface. The products help to maintain or
restore this protective layer and help customers around the
world in their daily work of creating a superior stainless steel
surface.
Our products are made in Malmö, Sweden, in our own
modern, automated process plant. All products have full
traceability from raw material to finished product, which
gives us total control of the product quality. Our quality
and environmental management systems are certified
according to the ISO 9001 and ISO 14001 standards.
LASTING CONNECTIONS
As a pioneer in innovative welding consumables, Böhler Welding offers a uni-
que product portfolio for joint welding worldwide. More than 2000 products are
adapted continuously to the current industry specifications and customer requi-
rements, certified by well-respected institutes and thus approved for the most
demanding welding applications.
Our customers benefit from a partner with
»
» the highest expertise in joining, rendering the best application support
globally available
»
» specialized and best in class product solutions for their local and global
challenges
»
» an absolute focus on customer needs and their success
»
» a worldwide presence through factories, offices
and distributors
3. L asting C onnections 3
CONTENT
1. STAINLESS STEELS AND THE NEED FOR
CLEANING ....................................................................... 5
1.1. Stainless steel grades and cleaning ......................... 6
1.2. Surface finishes and cleaning .................................... 9
1.3. Welding methods and cleaning ................................ 11
1.4. Correct handling and cleaning .................................. 11
1.5. Industrial trends and cleaning ................................... 12
1.6. Typical defects .................................................................. 12
1.6.1. Heat tint and oxide scale ........................................................12
1.6.2. Weld defects ...............................................................................12
1.6.3. Iron contamination ...................................................................13
1.6.4. Rough surface .............................................................................13
1.6.5. Organic contamination ...........................................................13
2. CLEANING PROCEDURES ..................................... 14
2.1. Mechanical methods ..................................................... 14
2.1.1. Grinding ........................................................................................14
2.1.2. Blasting .........................................................................................15
2.1.3. Brushing ........................................................................................15
2.1.4. Summary ......................................................................................15
2.2. Chemical methods .......................................................... 16
2.2.1. Pickling ..........................................................................................16
2.2.2. Passivation and decontamination ......................................18
2.2.3. Electropolishing ..........................................................................18
2.3. Choice of method ............................................................ 19
2.4. Examples of a complete cleaning process ........... 20
2.4.1. Case details .................................................................................20
3. CHEMICAL METHODS IN PRACTICE ............. 21
3.1. BÖHLER WELDING WELDCARE PRODUCTS ........ 21
3.2. General requirements .................................................... 21
3.3. Precleaning/degreasing .............................................. 22
3.4. Pickling ................................................................................. 23
3.4.1. Pickling with paste .....................................................................24
3.4.2. Pickling with solution (spray-pickling gel) ..........................24
3.4.3. Typical pickling times for brush and spray pickling ........24
3.4.4. Pickling in a bath ........................................................................27
3.4.5. Fume reduction during pickling ............................................31
3.5. Passivation and desmutting ........................................ 32
4. NEUTRALISATION AND WASTE
TREATMENT .................................................................... 33
4.1. Neutralisation .................................................................... 33
4.2. Waste treatment ............................................................... 33
5. INSPECTION AND TROUBLESHOOTING ... 34
5.1. Test methods ...................................................................... 34
5.2. Troubleshooting ................................................................ 35
6. SAFE HANDLING AND STORAGE OF
PICKLING PRODUCTS .............................................. 36
6.1. Safety rules ......................................................................... 36
6.2. Personal safety ................................................................. 37
6.3. Storage ................................................................................. 37
REFERENCES ..............................................................38
IMPORTANT NOTICE! ..............................................38
5. S T A I N L E S S S T E E L S A N D T H E N E E D F O R C L E A N I N G 5
A good stainless steel surface is clean, smooth and fault-
less. The importance of this is obvious when stainless steel
is used in, for example, façades or applications with strin-
gent hygiene requirements. However, a fine surface finish
is also crucial to corrosion resistance.
Stainless steel is protected from corrosion by its passive
layer – a thin, impervious, invisible, surface layer that is pri-
marily chromium oxide. The oxygen content of the atmo-
sphere or of aerated aqueous solutions is normally sufficient
to create and maintain (“self-heal”) this passive layer. Unfor-
tunately, surface defects and imperfections introduced
during manufacturing may drastically disturb this “self-hea-
ling” process and reduce resistance to several types of local
corrosion. Thus, as regards hygiene and corrosion, a final
cleaning process is often required to restore an acceptable
surface quality.
The extent of, and methods for, post-fabrication treatment
are determined by a number of factors. These include: the
corrosivity of the environment (e.g. marine); the corrosion
resistance of the steel grade; hygiene requirements (e.g. in
the pharmaceutical and food industries); and, aesthetic
considerations. Local environmental requirements must
also be considered. Both chemical and mechanical clea-
ning methods are available.
Good design, planning and methods of manufacture can
reduce the need for post-treatment and thus lower costs.
When manufacturing to surface quality specifications, the
impact of defects and, ultimately, the cost of removal must
be borne in mind.
The cost of treating/cleaning is small compared to the ini-
tial capital expenditure on a piece of equipment. It is also
small compared to the continuing operational cost of not
cleaning.
There are two main elements in the economics of post-fa-
brication cleaning – the cost of cleaning and the benefits
that cleaning brings as regards long-term performance.
Fabrication can reduce the overall corrosion performance
of a stainless steel to below its “normal” level. Furthermore,
in real conditions, it is difficult, if not impossible, to com-
plete the fabrication of a significant facility or piece of
equipment without some surface contamination.
Because they generally have relatively poor corrosion per-
formance, areas that have not been cleaned after fabri-
cation are essentially the weak link in the chain. Depending
on the extent of cleaning required, treatment after cons-
tructing a tank (for example) might cost as little as 1 – 3%
of the total spent on materials and manufacture. Conse-
quently, as it maximises the return on the investment,
post-fabrication cleaning is not expensive (see also ref. 9).
1. STAINLESS STEELS AND THE NEED FOR
CLEANING
Before After
6. 6
Definitions
The following terms are often imprecisely used: cleaning;
post-fabrication cleaning; precleaning; descaling; pickling;
passivation; and, desmutting. For a better understanding
of surface treatment and this publication, it is important to
define these terms.
Cleaning includes all operations necessary to ensure the
removal of surface contaminants from metals and:
»
» Maximise the metal’s corrosion resistance.
»
» Prevent product contamination.
»
» Achieve the desired appearance.
Combinations of grinding, degreasing, pickling and pass-
ivation may be necessary to obtain a clean surface.
Post-fabrication cleaning is the process of cleaning after
fabrication. Its purpose is to remove all contamination asso-
ciated with the fabrication process.
Precleaning is the removal of grease, oil, paint, soil, grit
and other coarse contamination prior to pickling or final
cleaning.
Degreasing is the removal of grease prior to pickling or
final cleaning.
Pickling is the use of chemicals to clean a metal by remo-
ving: defects; the surface film of inherent or thickened
oxide; and, below this, some micrometres of the parent
metal.
Overpickling is a too strong etching of a surface with pick-
ling acids. This leaves a rough surface that may result in a
lowering of the metal’s properties.
NOx is toxic nitric fumes (NO and NO2) formed during the
pickling process.
Passivation is the name applied to a number of different
processes related to stainless steel. Unless otherwise spe-
cified, passivation in the present context is the chemical
treatment of a stainless steel with a mild oxidant so as to
remove free iron from the surface and speed up the pro-
cess of forming a protective/passive layer. However, pass-
ivation is not effective for the removal of heat tint or oxide
scale on stainless steel.
Smut is an undesired discoloration or deposit on a surface
after pickling (can appear as a dark adhesive film). These
dark spots can indicate that there are some remaining con-
taminants on the steel and that these have interfered with
the pickling reaction.
Desmutting is the removal of smut. Desmutting is neces-
sary if dark areas appear on a surface during pickling. This
can be overcome by applying more pickling spray to these
spots or by applying a passivator until they disappear. This
must be done when the surface is still wet (i.e. “wet on wet”),
just before the pickling spray is rinsed off.
Welding methods:
MMA: manual metal arc (SMAW = shielded metal arc
welding)
MIG/MAG: metal inert/active gas (GMAW, gas metal arc
welding)
TIG: tungsten inert gas (GTAW = gas tungsten arc
welding)
SAW: submerged arc welding
FCAW: flux cored arc welding
MCAW: metal cored arc welding
1.1. STAINLESS STEEL
GRADES AND CLEANING
In any application, stainless steel grades are selected on
the basis of required properties (e.g. corrosion resistance),
design criteria and fabrication requirements. However,
there are many different iron-carbon-chromium alloys that
are collectively referred to as stainless steels.
Typical micro structures of different stainless steel
grades
Ferritic
11–17% Cr
+
Ni
+C
++
Ni
Duplex
21–26% Cr
Martensitis
11–17% Cr
Austenitis
18–30% Cr
7. S T A I N L E S S S T E E L S A N D T H E N E E D F O R C L E A N I N G 7
A pickled, duplex 2304 storage tank
A steel’s corrosion resistance, weldability, mechanical properties, etc are largely determined by its
microstructure (see figure 3). This, in turn, is determined by the steel’s chemical composition. As per
EN 10088, stainless steels can be divided into the following, basic, microstructure-dependent groups:
»
» Martensitic.
»
» Ferritic.
»
» Austenitic.
»
» Austenitic-ferritic (duplex).
As they are normally added to increase corrosion resistance, the various alloying elements have a
large impact on the ease with which a stainless steel can be pickled (pickleability). It is the proporti-
ons of the different alloys that have a great effect on the pickleability of a stainless steel. As regards
steel grades, the rule of thumb is: “The higher the alloy content (i.e. the corrosion resistance), the more
difficult it is to pickle the steel”.
The most basic grades are the iron-carbon-chromium alloys. These fall into two groups – martensi-
tic and ferritic.
8. 8
Martensitis stainless steels generally contain only 11 to
17% chromium and have a higher carbon content than the
ferritic grades. The steels in this group are characterised by
high strength and limited corrosion resistance. They are
mainly used where hardness, strength and good wear resis-
tance are required (e.g. turbine blades, razor blades and
cutlery).
Ferritische stainless steels are more corrosion resistant than
the martensitic grades, but less resistant than the austeni-
tic grades. Like martensitic grades, these are straight chro-
mium steels with no nickel. The most common of these steels
contain either 12% or 17% chromium – 12% steels are used
mostly in structural applications and automotive applica-
tions (exhaust systems) while 17% steels are used for cata-
lytic converters, housewares, boilers, washing machines
and internal building structures. Owing to the low chromium
content, the corrosion resistance of the two steel groups
above is lower than that of the two steel groups below. This
lower resistance means they are “easier” to pickle. In other
words, to avoid the risk of overpickling, they need a shorter
pickling time or a less aggressive pickling agent.
The addition of nickel to the austenitic and austenitic-fer-
ritic steels further improves their corrosion resistance.
Austenitis is the most widely used type of stainless steel. It
has a nickel content of at least 7%. This makes the steel
structure fully austenitic and gives it non-magnetic proper-
ties, good ductility and good weldability. Austenitic steels
can also be used throughout a wide range of service
temperatures. Applications for which austenitic stainless
steels are used include: housewares; containers; industrial
piping; tanks; architectural façades; and, building structu-
res. This type of stainless steel dominates the market.
Austenitic-ferritic (duplex) stainless steels have a ferritic
and austenitic lattice structure (hence duplex). To give a
partly austenitic lattice structure, this steel has some nickel
content. The duplex structure delivers both strength and
ductility. Duplex steels are mostly used in the petrochemi-
cal, paper, pulp and shipbuilding industries.
Modern duplex steels span the same wide range of corro-
sion resistance as the austenitic steels. For more detailed
information about the stainless steel grades, see the
Böhler Welding Stainless Steel Handbook and the Outo-
kumpu Corrosion Handbook. Nickel-base alloys are now
also becoming increasingly popular for use in highly cor-
rosive environments.
Nickel-base alloys are vitally important to modern indus-
try as a complement to stainless steel. This is because of
their ability to withstand a wide variety of severe operating
conditions involving corrosive environments, high tempe-
ratures, high stresses and combinations of these factors.
Nickel itself offers very useful corrosion resistance and pro-
vides an excellent base for developing specialised alloys.
Special intermetallic phases can be formed between nickel
and some of its alloying elements. This enables the formu-
lation of very high-strength alloys for both low and high-tem-
perature service.
9. S T A I N L E S S S T E E L S A N D T H E N E E D F O R C L E A N I N G 9
1.2. SURFACE FINISHES AND CLEANING
A smooth surface that is durable enough to resist cracking, chipping, flaking and abra-
sion cannot only resist the build up of contaminants but also be cleaned easily. Engineers
and architects choosing stainless steel for a particular purpose have an extensive number
of different grades to select from. There are also various surface finishes to choose from.
The decision as to what type of steel is best suited for any given purpose is largely based
on the corrosivity of the environment. However, surface quality (surface finish) also affects
sensitivity to corrosion and the ability to repel dirt and bacteria. This is of particular import-
ance in the food/beverage industry and the pharmaceutical sector.
The importance of surface finish goes well beyond aesthetic considerations. The rougher
a surface, the more easily contamination sticks to it and the more difficult it is to clean
and pickle. Consequently, hot rolled surfaces with their rougher finishes are more difficult
to clean and pickle than cold rolled surfaces with their smoother finishes.
Some basic definitions of surface finish criteria
In considering the concept of surface finish, sporadic surface defects that have mechanical
or metallurgical causes are disregarded in this manual. Instead, the focus is on the surface
layer and the minute, evenly distributed irregularities that are characteristic of the different
production and finishing methods used for steel products. Strictly defined, “surface finish”
can be said to be a measure of deviation from the ideal flat surface. This deviation is nor-
mally expressed in terms such as roughness, lay and waviness. In turn, these may be defined
as set out below.
Surface roughness
Y = roughness
S = lay
V = waviness
10. 10
A bright annealed (BA) finish after using Avesta Cleaner 401.
»
» Roughness is the size of the finely
distributed surface-pattern
deviations from the ideal smooth
surface.
»
» Lay is the dominant direction of
the surface pattern (e.g. grinding
marks).
»
» Waviness is deviations that are
relatively far apart.
Of these, waviness is the most difficult
to detect by eye.
As shown in table 1, surface smoo-
thness increases from hot rolled to
bright annealed (BA).
Table 1: Stainless steel surface finishes
Descrip-
tion
ASTM EN
10088-2
Surface
finish
Notes
Hot
rolled
1 1D Rough and
dull
A rough, dull surface produced by
hot rolling to the specified
thickness, followed by heat
treatment and pickling.
Cold
rolled
2D 2D Smooth A dull finish produced by cold
rolling to the specified thickness,
followed by heat treatment and
pickling.
Cold
rolled
2B 2B Smoother
than 2D
A bright, cold-rolled finish
commonly produced in the same
way as a 2D finish followed by skin
passing. The most common
surface finish. Good corrosion
resistance, smoothness and
flatness.
Cold
rolled
BA 2R Smoother
than 2B,
bright and
reflective
BA finish produced by cold rolling
followed by bright annealing in an
inert atmosphere.
11. S T A I N L E S S S T E E L S A N D T H E N E E D F O R C L E A N I N G 11
1.3. WELDING METHODS
AND CLEANING
The different welding methods can result in problems that
have different consequences for surface cleaning. Particu-
lar attention must be paid to preparation before pickling.
Table 2: Welding methods
Welding method Possible problems
depending on…*
Solution
(before
pickling)
MMA (SMAW) Slag residues
Tarnish (heat tint)
Brushing
(grinding)
FCAW Tarnish (heat tint)
Slag residues
Brushing
(while warm)
MIG (GMAW) Heavy bead oxidation
Slag residues
Spatter
Grinding
(brushing)
TIG (GTAW) Small slag islands
(“black spots”)
Grinding
(if possible)
SAW Sometimes slag
residues
Brushing
(grinding)
*filler metal, welding position, overheating, gas mixture, etc.
1.4. CORRECT HANDLING
AND CLEANING
The correct handling of stainless steels limits surface defects
and minimises the need for post-fabrication cleaning.
On delivery from the manufacturer, stainless steel plates,
tubes and pipes are normally clean and passivated. In other
words, the material has a natural corrosion-resistant film
over its entire surface. It is important to maintain as much
as possible of the stainless material’s original appearance
and corrosion resistance. Especially as regards exterior
building components, the instructions below must be borne
in mind at every stage from project design to production
and installation.
»
» Do not use steel brushes or steel tools made of carbon
steel.
»
» Do not carry out shot blasting using carbon steel
blasting materials or blasting materials that have
been used for shot blasting carbon steels.
»
» Hydrochloric acid, or cleaners containing chlorides,
must not be used for cleaning stainless steels.
»
» Do not use hydrochloric acid to remove cement or
mortar residues from stainless steels.
»
» Throughout storage, avoid contact between stainless
steel and carbon steel.
»
» When using forklifts, avoid direct contact between
carbon steel forks and stainless steel.
»
» At installation, use fasteners (e.g. nails, screws and
bolts) made of stainless steel.
»
» In areas exposed to moisture, avoid the risk of galva-
nic corrosion between stainless steel components and
plain carbon steel components (e.g. by providing
electrical insulation).
»
» Use clean tools that are free from residues of plain
carbon steel (e.g. swarf and iron particles from
previous work).
»
» Remove the protective plastic film only when it is no
longer needed, i.e. when the construction phase is
over and the local environment is free of debris and
dirt particles. Some plastic films deteriorate in sunlight
and can become difficult to strip.
12. 12
1.5. INDUSTRIAL TRENDS AND
CLEANING
Higher quality demands from industry in general are opening a gro-
wing number of applications for stainless steels. In the past, the use
of stainless steels was mainly restricted to closed, corrosive environ-
ments in the chemical process industry. Now, the material has become
more consumer oriented and can be found in many new applications
such as those listed below.
»
» Civil constructions such as bridges
(e.g. the Bilbao Bridge in Spain).
»
» Public transport such as buses and trains
(e.g. the X2000 high-speed train).
»
» Kitchen equipment and fixtures
(e.g. cookers, fridges and freezers).
»
» Fittings in public places
(e.g. street furniture, railings and building façades).
Today’s quality standards have resulted in stainless steels being intro-
duced into a large number of applications, all of them with their own
specific stipulations as regards surface treatment. They have also led
to other trends and the development of new methods. The following
are a few examples:
»
» The use of high-alloy steel grades (e.g. duplex) for construction
of chemical tankers and 6% Mo grades for desalination plants.
New welding methods such as FCAW, pulse MIG, automatic TIG
and laser welding.
»
» Increased production of hot rolled plates (thanks to lower
production costs).
»
» Great demand for bright finishes.
The need for industry to minimise any negative impact it has on the
environment has put the surface treatment of stainless steels in the
spotlight. A number of measures can easily be taken to comply with
new local requirements:
»
» Changing to more environment-friendly pickling products
(e.g. weldCare BAT-products)
»
» Upgrading pickling facilities.
»
» Installing neutralising facilities for treating the waste rinse water.
»
» Installing ventilation systems connected to a gas scrubber
(to treat acidic fumes).
1.6. TYPICAL DEFECTS
1.6.1. Heat tint and oxide
scale
Caused by processes such as heat treatment or
welding, high-temperature oxidation produces
an oxide layer that, compared to the original
passive layer, has inferior protective properties.
There is also a corresponding chromium deple-
tion in the metal immediately below the oxide.
With normal welding, the chromium-depleted
zone is very thin and can normally be removed
together with the tint. However, to completely
restore corrosion resistance, it is vital that this
zone is removed.
1.6.2. Weld defects
Incomplete penetration, undercut, pores, slag
inclusions, weld spatter and arc strikes are typi-
cal examples of weld defects. These defects have
a negative impact on mechanical properties and
resistance to local corrosion. They also make it
difficult to maintain a clean surface. Thus, the
defects must be removed – normally by grinding,
although sometimes repair welding is also neces-
sary.
13. S T A I N L E S S S T E E L S A N D T H E N E E D F O R C L E A N I N G 13
1.6.3. Iron contamination
Iron particles can originate from: machining; cold forming and cutting tools; blasting grits/sand or
grinding discs contaminated with lower alloyed materials; transport or handling in mixed manufac-
ture; or, simply, iron-containing dust. These particles corrode in humid air and damage the passive
layer. Larger particles may also cause crevices. In both cases, corrosion resistance is reduced. The
resultant corrosion is unsightly and may also contaminate media used in/with the equipment in ques-
tion. Iron contamination on stainless steels and welds can be detected using the ferroxyl test
(see chapter 5).
1.6.4. Rough surface
Uneven weld beads and grinding or blasting too heavily give rough surfaces. A rough surface col-
lects deposits more easily, thereby increasing the risk of both corrosion and product contamination.
Heavy grinding also introduces high tensile stresses. These increase the risk of stress corrosion cracking
and pitting corrosion. For many applications, there is a maximum allowed surface roughness
(Ra value). Manufacturing methods that result in rough surfaces should generally be avoided.
1.6.5. Organic contamination
In aggressive environments, organic contaminants in the form of grease, oil, paint, footprints, glue
residues and dirt can cause crevice corrosion. They may also make surface pickling ineffective and
pollute products handled in/with the equipment. Organic contaminants must be removed using a
suitable cleaner. In simple cases, a high-pressure water jet may suffice.
Surface defects
base material
Weld metal
Slag residues Undercut
Tarnish
Spatter
Organic
contamination
Iron
contamination
14. 14
Stainless steel construction
ready for pickling.
2. CLEANING PROCEDURES
As detailed in chapter 1, the extent of, and methods for, post-fabrication treatment are determined by a num-
ber of factors.
Different chemical and mechanical methods, and sometimes a combination of both, can be used to remove
the defects mentioned. Chemical cleaning can be expected to produce superior results. This is because most
mechanical methods tend to produce a rougher surface while chemical methods reduce the risk of surface con-
tamination. However, chemical cleaning may be limited not only by local regulations on environmental and
industrial safety, but also by waste disposal problems.
2.1. MECHANICAL METHODS
2.1.1. Grinding
Grinding is a common method of removing some defects and deep scratches. The grinding methods used must
never be rougher than necessary. A flapper wheel is often sufficient for removing weld tint or surface contami-
nation.
The following points must always be borne in mind when using grinding to clean stainless steels:
»
» Use the correct grinding tools. Iron-free discs must always be used for stainless steels. Never use discs that
have previously been used for grinding low-alloy steels.
»
» Avoid producing a surface that is too rough. Rough grinding with a 40 – 60 grit disc must always be
followed by fine grinding using, for example, a higher grit mop or belt to obtain a surface finish corre-
sponding to grit 180 or better. If surface requirements are very exacting, polishing may be necessary.
»
» Do not overheat the surface. In order to avoid creating further heat tint or higher stresses, apply less
pressure when grinding.
»
» Always check that the entire defect has been removed.
15. C L E A N I N G P R O C E D U R E S 15
2.1.2. Blasting
Blasting can be used to remove high-temperature oxide as well as iron contamination.
However, great care must be taken to ensure that the blasting material or media are per-
fectly clean. Thus, blasting material must not have been previously used for carbon steel.
Similarly, because it becomes increasingly polluted (even if it has only been used for blas-
ting contaminated stainless steel surfaces), media must not be too old. Surface roughness
is a limiting factor for this method. In most cases, blasting will not remove the chromi-
um-depleted zone.
2.1.3. Brushing
For the removal of heat tint, brushing using stainless steel or nylon brushes usually provi-
des a satisfactory result. These methods do not cause any serious roughening of the sur-
face. However, they do not guarantee complete removal of the chromium-depleted zone.
The other mechanical methods present a high risk of contamination. Consequently, it is
important to use clean tools that have not been used for processing carbon steels.
2.1.4. Summary
After a typical manufacturing programme, a final mechanical cleaning stage could be as
set out below.
How to clean mechanically (when pickling has not been selected)*
1. Use grinding to remove welding defects.
2.
Remove material affected by high temperatures and, if possible, remove iron
impurities. The mechanical method chosen must not make the surface unacceptably
rough.
3. Remove organic contaminants (see section 1.2.5).
4. A final passivation/decontamination should be carried out (strongly recommended).
* In most cases, pickling is essential for optimal corrosion resistance.
16. 16
2.2. CHEMICAL METHODS
Chemical treatments can remove high-temperature oxide and iron contamination. They also
restore the steel’s corrosion-resistant properties without damaging the surface finish.
After the removal of organic contaminants, the normal procedures are commonly pickling,
passivation/decontamination and/or electropolishing.
2.2.1. Pickling
Pickling is the most common chemical procedure used to remove oxides and iron contamina-
tion. Besides removing the surface layer by controlled corrosion, pickling also selectively remo-
ves the least corrosion-resistant areas such as the chromium-depleted zones.
Pickling normally involves using an acid mixture containing nitric acid (HNO3), hydrofluoric
acid (HF) and, sometimes, also sulphuric acid (H2SO4). Owing to the obvious risk of pitting cor-
rosion, chloride-containing agents such as hydrochloric acid (HCl) must be avoided.
As mentioned in chapter 1, the main factors determining the effectiveness of pickling are as
set out below
Steel grade
Table 3 below shows the most common stainless steel grades and the matching welding con-
sumables from Böhler Welding. Pickleability has been tested and the steels arranged into four
groups (see also appendix 1, “Steel grades”). The groupings are based on the ease with which
the steels can be pickled.
»
» Steel group 1: Owing to the low chromium content, the corrosion resistance of this group
is lower than that of the groups below. The lower resistance of the steels in this group
means they are “easier” to pickle. In other words, to avoid the risk of overpickling, they
need a shorter pickling time or a less aggressive pickling agent. Special care must be
taken to avoid overpickling!
»
» Steel group 2: The steels in this group are standard grades and fairly easy to pickle.
Simply follow the instructions provided.
»
» Steel groups 3 – 4: The steels in this group are high-alloy grades. Being more corrosion
resistant, they need a more aggressive acid mixture and/or higher temperature (to avoid
an excessively long pickling time). The risk of overpickling these steel grades is much lower
(see table 1).
17. C L E A N I N G P R O C E D U R E S 17
Surface finish
A rough, hot rolled surface may be harder to pickle than a smooth, cold rolled one.
Welding method and resultant thickness and type of oxide layer
Thickness and type depend largely on the welding procedure used. To produce a
minimum of oxides, weld using an effective shielding gas that is as free of oxygen
as possible. For further information, see the Böhler Welding Stainless Steel Hand-
book. Particularly when pickling high-alloy steel grades, mechanical pretreatment
to break or remove the oxides might be advisable.
Precleaning
The surface must be free of organic contamination.
Table 3: Stainless steel grades and pickleability
Stainless steel grades Welding
method
Welding consumables
EN ASTM
Group 1: Very easy to pickle*
1.4006 410 MMA BÖHLER FOX KW 10
1.4016 430 MMA BÖHLER FOX SKWA
1.4016 430 MMA Avesta 308L/MVR
1.4016 430 FCAW
Avesta FCW-2D 308L/
MVR
1.4313 410NiMo MMA BÖHLER FOX CN 13/4
1.4313 410NiMo MCAW BÖHLER CN 13/4-MC
Group 2: Easy to pickle
1.4301 304 MMA Avesta 308L/MVR
1.4301 304 MAG Avesta 308L-Si/MVR-Si
1.4401 316 MMA Avesta 316L/SKR
1.4401 316 MAG Avesta 316L-Si/SKR-Si
1.4404 316L MMA Avesta 316L/SKR
1.4404 316L MMA Avesta 316L/SKR
1.4404 316L FCAW Avesta 316L/SKR
1.4404 316L MAG Avesta 316L-Si/SKR-Si
1.4404 316L MCAW BÖHLER EAS 4 M-MC
Stainless steel grades Welding
method
Welding consumables
EN ASTM
Group 3: Difficult to pickle
1.4539 904L MMA Avesta 904L
1.4539 904L MAG Avesta 904L
1.4539 904L MMA Thermanit 625
1.4501 S32760 MMA Avesta 2507/P100
1.4161 S32101 MAG Avesta LDX 2101
1.4161 S32101 FCAW Avesta LDX 2101
1.4362 S32304 MAG Avesta 2304
1.4362 S32304 FCAW Avesta 2304
1.4462 S32205 MMA Avesta 2205
1.4462 S32205 MAG Avesta 2205
Group 4: Very difficult to pickle
1.4547 S31254 MMA Thermanit 625
1.4547 S31254 MAG Thermanit 625
1.4565 S34565 MMA Thermanit Nimo C 24
1.4565 S34565 MAG Thermanit Nimo C 24
1.4410 S32750 MMA Avesta 2507/P100
* Group 1 is very easy to pickle but, at the same time, difficult to treat. There is
a risk of overpickling. Great attention must be paid to pickling time and
temperature.
18. 18
Temperature
The effectiveness of pickling acids increases with tempe-
rature. Thus, the pickling rate can be considerably increa-
sed by increasing the temperature. However, there are
upper temperature limits that must also be considered.
Especially when using a bath, the risk of overpickling increa-
ses with high temperatures. When using pickling paste/gel/
spray/solution at high temperatures, evaporation presents
the risk of poor results. Besides an uneven pickling effect,
this also leads to rinsing difficulties. To avoid these prob-
lems, objects must not be pickled at temperatures above
40ºC or in direct sunlight.
Composition and concentration of the acid mixture
Pickling method
There are three different pickling methods.
»
» Pickling with pickling paste/gel: Pickling paste (or gel)
for stainless steels is suitable for pickling limited areas,
e.g. weld-affected zones. It is best applied using an
acid-resistant brush. Rinsing with water must be
carried out before the paste dries. Even if, for environ-
mental and practical reasons, neutralisation of the
pickling paste is carried out on the metal surface,
thorough rinsing with water is vital.
»
» Pickling with pickling solution/spray: Pickling solution
(or pickling gel in spray form) is suitable for pickling
large surfaces, e.g. when the removal of iron contami-
nation is also desired.
»
» Pickling in a bath is a convenient method if suitable
equipment is available.
2.2.2. Passivation and
decontamination
This procedure is carried out in a manner similar to pickling.
The passivator, applied by immersion or spraying, streng-
thens the passive layer. Because the passivator also remo-
ves iron impurities from the surface, the treatment is more
important after mechanical cleaning and operations invol-
ving a risk of iron contamination. It is for this reason that
the method can also be referred to as decontamination.
2.2.3. Electropolishing
Electropolishing normally produces a surface that guaran-
tees optimal corrosion resistance. It does not selectively
remove areas of inferior corrosion resistance, but polishes
microtips from the surface. The material gains a fine lustre
and, most importantly, an even microprofile that meets
extremely stringent hygiene requirements. For these rea-
sons, electropolishing is normally used as a final treatment
after pickling. This method is not covered in the present
publication.
19. C L E A N I N G P R O C E D U R E S 19
Grinding Polishing Pickling
2.3. CHOICE OF METHOD
The choice of method and the amount of final cleaning required depend on: corrosion
resistance requirements; hygiene considerations (pharmaceuticals, food, etc.); and, the
importance of the steel’s visual appearance. Removal of welding defects, welding oxides,
organic substances and iron contaminants is normally a basic requirement and usually
allows a comparatively free choice of final treatment.
Provided that the surface roughness so permits, both mechanical and chemical methods
can be used. However, if an entirely mechanical cleaning method is decided on, the manu-
facturing stage has to be very well planned in order to avoid iron contamination. If it is
not, decontamination, probably with nitric acid, will be necessary (see section 2.2.4). Where
surface finish and corrosion resistance requirements are exacting, the choice of method
is more critical. In such cases, a treatment sequence based on pickling (see section 2.2.3)
gives the best chances of superior results.
The figure below shows the results of a test where the samples (steel grade 1.4404/316 L
with MMA welds) were post-weld cleaned using three different methods. They were then
exposed to a marine environment for 2 weeks.
20. 20
How to carry out a complete cleaning process
1. Inspect
2. Pretreat mechanically
3. Preclean
4. Rinse
5. Pickle
6. Desmut
7. Rinse
8. Passivate
9. Neutralise
10. Inspect
All these steps are discussed in greater detail in subsequent chapters.
2.4. EXAMPLES OF A COMPLETE
CLEANING PROCESS
After a typical manufacturing programme, a complete cleaning process could
be as set out below.
2.4.1. Case details
Landaluce, a company in Spain’s Cantabria, has manufactured a total of
90 beer tanks for Heineken and its brewery in Seville. Made in ASTM 304 hot
rolled stainless steel, the 4.5 m diameter tanks are 18 m long.
The beer tanks went through complete cleaning using the following Avesta
Products:
»
» Cleaner 401
»
» RedOne™ Spray 240 (tank exteriors)
»
» Pickling Bath 302 (tank interiors)
»
» FinishOne™ Passivator 630
21. C H E M I C A L M E T H O D S I N P R A C T I C E 21
3. CHEMICAL
METHODS IN
PRACTICE
3.1. BÖHLER WELDING
WELDCARE PRODUCTS
Böhler Welding weldCare offers a wide programme of clea-
ning preparations:
»
» Pickling Paste
»
» Pickling Spray
»
» Pickling Bath
»
» Cleaning Neutralising Agent
»
» Passivator
High-pressure rinsing
after pickling
3.2. GENERAL REQUIREMENTS
The choice of chemical cleaning process is primarily deter-
mined by: the type of contaminants and heat oxides to be
removed; the degree of cleanness required; and, the cost.
This chapter gives guidelines on suitable chemical cleaning
procedures.
In order to avoid health hazards and/or environmental pro-
blems, pickling must be carried out in a special pickling area,
preferably indoors. In this context, compliance with the
recommendations below should be regarded as compul-
sory.
Handling instructions and essential information (e.g. pro-
duct labels, safety data sheets, etc.) for the various pro-
ducts must be available. Local and national regulations
must also be available. See, additionally, section 6.1.
»
» The personnel in charge must be familiar with the
health hazards associated with the products and how
these must be handled.
»
» Personal safety equipment must be used. See also
section 6.2.
»
» When pickling indoors, the workplace must be separate
from other workshop operations. This is not only to
avoid contamination and health hazards, but also to
ensure a controlled temperature.
»
» The area must be well ventilated and provided with
fume extraction apparatus.
»
» Walls, floors, roofs, tanks, etc. that are subject to
splashing must be protected by acid-resistant material.
»
» A washing facility must be available, preferably
including a high-pressure water jet.
»
» A first-aid spray must be available. See also section 6.1.
»
» A facility for the collection and neutralisation of rinse
water must be available. See also section 4.1.
»
» If the rinse water is recycled, care must be taken to
ensure that the final rinse is performed using deionised
water. This is particularly important in the case of
sensitive surfaces and applications.
»
» A storage facility must be available. See also section
6.3
22. 22
3.3. PRECLEANING/DEGREASING
Surface rust – before and after removal using Avesta Cleaner 401.
How to use Avesta Cleaner 401
1.
Inspect the surface to be treated and ensure that all
non-stainless material has been protected.
2. Pretreat oxides, slags
and weld defects
mechanically. This
should preferably be
done while the welds
are still warm and the
weld oxides less hard.
3.
After any welding,
give the area to be
cleaned time to cool
down to below 40ºC.
4.
Using an acid-resis-
tant pump (Avesta
SP-25), spray the pro-
duct onto the sur-
face. Apply an even
layer that covers the
entire surface. Do not apply in direct sunlight!
5.
Allow the product sufficient reaction time, but avoid
letting it dry. If the contaminants are stubborn (diffi-
cult to remove) and in thick layers, mechanical brus-
hing with a hard plastic or nylon brush will help.
6.
Preferably using a high-pressure water jet, rinse tho-
roughly with clean tap water. To reduce acid splas-
hing, prewashing at tap-water pressure (3 bars) is
recommended. Ensure that no residues are left on
the surface. Use deionised water for the final rinsing
of sensitive surfaces.
Contamination on the surface can impair the pickling pro-
cess. To prevent this, thorough cleaning prior to pickling is
recommended. Where loose dust, fingerprints, shoeprints
and tool marks are the contaminants, acid cleaning (e.g.
Avesta Cleaner 401) is usually adequate.
23. C H E M I C A L M E T H O D S I N P R A C T I C E 23
3.4. PICKLING
Pickling products can be applied in three different ways:
»
» Brushing, using a pickling paste/gel
»
» Spraying, using a pickling solution
»
» Immersion/circulation in/with a pickling bath
The different methods are presented in the following pages.
How to use pickling pastes/gels
1.
Pretreat oxides, slags and weld defects mechanically. This should preferably be done while the
welds are still warm and the weld oxides less hard.
2. After any welding, give the area to be pickled time to cool down to below 40ºC.
3. To remove organic contamination, degrease using Avesta Cleaner 401.
4. Before using, stir or shake the paste.
5. Using an acid-resistant brush, apply the pickling paste. Do not pickle in direct sunlight!
6.
Give the product sufficient time to react (see table 2). At high temperatures, and
when prolonged pickling times are required, it might be necessary to apply more of
the product after a while. This is because the product can dry out and thus cease to
be as effective.
7. Preferably using a high-pressure water jet, rinse thoroughly with clean tap water. Ensure
that no pickling residues are left on the surface. Use deionised water for the final rin-
sing of sensitive surfaces.
8. So that it can be neutralised, collect the waste water. See also chapter 4.
24. 24
3.4.1. Pickling with paste
Creating a better working environment, Avesta BlueOne Pickling Paste
130 is a unique pickling product. Using BlueOne, there are virtually none
of the toxic nitric fumes normally formed during pickling. This paste has
good heat stability and is also well suited for use in warm conditions.
Pickling Paste 130 can be used as a universal paste on all stainless steel
grades.
Avesta GreenOne Pickling paste 120 is a unique paste with low environ-
mental impact. It is designed for the light pickling of steels that are easy
to pickle (e.g. martensitic and ferritic grades).
3.4.2. Pickling with solution (spray-pickling gel)
Creating a better working environment, Avesta RedOne Spray Pickle
Gel 240 is a unique pickling product. Using RedOne 240, toxic nitric fumes
are significantly reduced.
Combined Method: For some purposes, brushing and spraying methods
can be combined. When only a mild pickling effect is required (on sensi-
tive surfaces), pickling paste can first be applied to the weld joints and
then an acidic cleaner (e.g. Avesta Cleaner 401) can be sprayed onto the
surface.
3.4.3. Typical pickling times for brush and
spray pickling
The pickling times given in the table below must be seen as indicative
only. They are stated as intervals because, for the same steel grade, the
time required depends on the surface finish and the welding method (see
also chapter 1). For hot rolled surfaces, pickling times should normally be
increased. Similarly, depending on the shielding gas used, MIG welds
might need longer than MMA or FCAW welds.
Brush pickling
25. C H E M I C A L M E T H O D S I N P R A C T I C E 25
Pickling equipment: To achieve a good spraying result, a
suitable pump is necessary. The pump must be made of an
acid-resistant material and must provide an even applica-
tion pressure. Avesta Spray Pickle Pump SP-25 was specially
designed to meet these requirements. It is a pneumatic,
quarter inch pump of the membrane type and has an
adjustable valve. Spray Pickle Pump SP-25 with a
special spray handle
How to use spray-pickling gel
1.
Inspect the surface to be treated and ensure that all
non-stainless material has been protected.
2.
Pretreat oxides, slags and weld defects mechanically.
This should preferably be done while the welds are still
warm and the weld oxides less hard.
3.
After any welding, give the area to be pickled time to
cool down to below 40°C.
4.
To remove organic contamination, degrease using
Avesta Cleaner 401.
5. Before using, stir the spray gel well.
6. Using an acid-resistant pump
(Avesta SP-25), apply the pro-
duct as a spray. Gently apply
an even layer of acid that
covers the entire surface. Do
not pickle in direct sunlight!
7.
Allow the product sufficient
pickling time.
8.
Carry out desmutting and NOx reduction.
9.
Desmutting is necessary if dark areas appear on the
surface. Apply either more solution or Avesta
FinishOne™ to these spots until they disappear. This
must be done when the surface is still wet (i.e. “wet on
wet”), just before the pickling spray is rinsed off. Spray-
ing FinishOne™ on top of the pickled surface also redu-
ces the production of NOx gases.
10.
When pickling outdoors, the pickling spray must not
be allowed to dry. Drying may cause discoloration of
the steel surface. This means that at high temperatu-
res, and when prolonged pickling times are required,
it may be necessary to apply more of the product after
a while.
11.
Preferably using a
high-pressure water jet,
rinse thoroughly with
clean tap water. To
reduce acid splashing,
prewashing at tap-water
pressure (3 bars) is recommended. Ensure that no pick-
ling residues are left on the surface. Use deionised
water for the final rinsing of sensitive surfaces.
12.
Passivation must be carried out directly after wet-on-
wet rinsing. Spray Avesta FinishOne Passivator 630
evenly over the entire surface.
13.Leave to dry.
14.Carry out inspection and process verification.
15.
All treated surfaces must be ocularly inspected for oil
residues, oxides, rust and other contaminants.
16.
So that it can be neutralised, collect the waste water.
See also chapter 4.
27. C H E M I C A L M E T H O D S I N P R A C T I C E 27
3.4.4. Pickling in a bath
The stainless steel grade and the type of heat oxide deter-
mine the acid mixture and the bath temperature (20 – 65ºC).
Pickling low-alloy stainless grades at excessive temperatu-
res, or for a long period of time, presents the risk of over-
pickling. This gives a rough surface.
The effectiveness of pickling is affected not only by acid
concentration and temperature, but also by the free metal
content (mainly iron) in the bath. For pickling times to be
the same, the temperature in a bath with an elevated iron
content has to be higher than that in a bath with a lower
iron content. A rough guideline is that the free iron (Fe) con-
tent measured in grams per litre must not exceed the bath
temperature (ºC). When metal contents in the bath reach
excessive levels (40 – 50 g/l), the bath solution can be par-
tially or totally emptied out and fresh acid added.
Avesta Pickling Bath 302 is a concentrate that, depending
on the steel grade being cleaned, can be diluted with water.
The ferritic and martensitic steels in group 1 are normally
not pickled in a bath. Thus, they are not mentioned here.
The pickling acid must be added to the water, not the
other way round.
Group 2 steels:
1 part 302 into 3 parts water
Group 3 steels:
1 part 302 into 2 parts water
Group 4 steels:
1 part 302 into 1 part water
Temperature, composition and circulation need to be con-
trolled to get the best results. The composition of the bath
is controlled through regular analyses. Together with new
mixing instructions to optimise the effect of the bath, weld-
Care Finishing Chemicals can offer such analyses.
The pickling times given in the table below must be seen as
indicative only. They are stated as intervals because, for
the same steel grade, the time required depends on the
surface finish and the welding method (see also chapter 1).
For hot rolled surfaces, pickling times might be increased
by 50%. Similarly, depending on the shielding gas used,
MIG welds might need longer than MMA or FCAW welds.
Bath pickling (photo courtesy
of Kurt Jensen)
28. 28
Table 5: Typical pickling times when using fresh Avesta Bath Pickling 302
Stainless steel grades Welding
method
Welding consumables Typical pickling times (minutes)
EN ASTM 20°C 30°C 45°C
Group 2: Easy to pickle*
1.4301 304 MMA Avesta 308L/MVR 30 15 10
1.4401 316 MMA Avesta 316L/SKR 40 20 10
1.4404 316L MMA Avesta 316L/SKR 40 20 10
Group3: Difficult to pickle**
1.4539 904L MMA Avesta 904L 120 90 60
1.4362 S32304 MMA Avesta 2304 120 90 60
1.4462 S32205 MMA Avesta 2205 120 90 60
Group 4: Very difficult to pickle***
1.4547 S31254 MMA Thermanit 625 240 120 90
1.4410 S32750 MMA Avesta 2507/P100 240 120 90
* 1 part 302 into 3 parts water ** 1 part 302 into 2 parts water *** 1 part 302 into 1 part water
29. C H E M I C A L M E T H O D S I N P R A C T I C E 29
How to use Avesta bath pickling
1. Pretreat oxides, slag and weld defects mechanically.
2.
After any welding, give the area to be pickled time to cool down to
below 40°C.
3. To remove organic contamination, degrease
using Avesta Cleaner 401.
4.
Mix the concentrated bath pickling solution
with water. Remember to add the acid to the
water, not the other way round! To obtain a
homogenous acid concentration in the bath,
use a pump to circulate the solution.
5.
Check the bath temperature (refer to table 4).
6. Immerse the object in the bath. Typical pickling times are shown in table
4. Avoid overpickling. This can produce a rough surface.
7.
Allow the product sufficient pickling time.
8.
Carry out desmutting and NOx reduction. If dark spots appear on the
surface, desmutting is necessary. Apply either more solution or Avesta
FinishOne™ to these spots until they disappear. This must be done when
the surface is still wet (i.e. “wet on wet”), just before the pickling spray
is rinsed off. Spraying FinishOne™ on top of the pickled surface also
reduces the production of NOx gases.
9. When lifting the object, allow time for the bath solution to flow off above
the bath.
10. A first rinse must be performed by dipping
the object into a vat of rinse water. Next,
rinse thoroughly using a high-pressure
water jet. Ensure that no pickling residues
are left on the surface. Use deionised
water for the final rinsing of sensitive sur-
faces.
11.
So that it can be neutralised, collect the
waste water. See also chapter 4.
12.
As the pickling acid in the bath is being constantly consumed and
metals precipitated, analysis of bath contents (in particular, free metal
ions) is important. Bath contents affect the pickling reaction.
31. C H E M I C A L M E T H O D S I N P R A C T I C E 31
3.4.5. Fume reduction during pickling
Environmental impact
The toxic nitric fumes generated during pickling have a number of effects.
»
» Health: High nitric fume levels may lead to respiratory problems (e.g.
infections). In the worst case, inhalation may cause lung oedema.
»
» Environmental: Acidification of groundwater and damage to plants.
Using modern pickling products such as Avesta BlueOne Picking Paste
130 and Avesta RedOne Spray 240, toxic fume levels can be reduced by
up to 80%.
40%
0
0 2 4 6 8 10 12 14
Time (min)
60%
80%
100%
Relative NOx-levels
Standard Pickling Paste
BlueOne Paste
Avesta Diagram red
TM
20%
Time (min)
relative NOx-levels
Standard pickling paste
BlueOne™ paste
40%
0
0 2 4 6 8 10 12 14
Time (min)
60%
80%
100%
Relative NOx-levels
Standard Pickling Spray
RedOne Spray
Avesta Diagram red
TM
20%
Time (min)
Standard pickling spray
RedOne™ Pickling Spray
relative NOx-levels
Fume reduction using Böhler Welding weldCare
pickling products
BlueOne™ Pickling Paste
RedOne™ Pickling Spray
32. 32
3.5. PASSIVATION AND DESMUTTING
Böhler Welding weldCare Finishing Chemicals’ Avesta FinishOne Passivator 630 is a passivating agent that is
free of nitric acid and has a low environmental impact. Because it is neutral after passivation, there is no need
for a neutralisation stage. The product can passivate, desmut and reduce fumes.
Passivation is strongly recommended after mechanical treatment (to remove remaining iron contamination)
and, in some cases, after spray pickling.
Desmutting removes the dark spots caused by excessive iron left on the surface by faulty cleaning.
Fume reduction: After bath pickling, spraying Avesta FinishOne Passivator 630 on the pickled object after
lifting it from the bath reduces the toxic nitric fumes generated during bath pickling
Passivation of what will be part of a chemical tanker bulkhead in duplex
stainless steel
Smut
How to use Avesta FinishOne passivator
»
» To passivate after mechanical treatment, first use Avesta Cleaner 401 to preclean the surface.
Next, rinse with water and apply the passivator “wet on wet”. Leave it to react for 3 – 5 minutes.
»
» To desmut or avoid smut formation during spray pickling, the passivator must be applied before
rinsing while the surface is still wet (“wet on wet”). Leave it to react for 10 – 15 minutes.
»
» To use for fume reduction after bath pickling, lift the object over the surface of the bath and spray
FinishOne™ as a mist on the object’s surface (“wet on wet”).
»
» To passivate after spray pickling, first rinse off the pickling spray and then apply the passivator.
Leave it to react for 20 – 30 minutes.
»
» Using an acid-resistant pump (Avesta SP-25), apply the product as a spray. Apply an even layer of
acid that covers the entire surface.
»
» Using an acid resistant pump (Avesta Sp 25 or Hand Pump 415); apply the passivator as an even
layer that covers the entire surface.
»
» Preferably using a high-pressure water jet, rinse thoroughly with clean tap water. Ensure that no
acid residues are left on the surface. Use deionised water for the final rinsing of sensitive surfaces.
»
» There is no need to neutralise the waste water (it is neutral and acid free).
33. N E U T R A L I S A T I O N A N D W A S T E T R E A T M E N T 33
4. NEUTRALISATION AND WASTE TREATMENT
4.1. NEUTRALISATION
The waste water from pickling is acidic and contaminated
with heavy metals (mainly chromium and nickel that have
been dissolved from the steel). This waste water must be
treated in accordance with local regulations. It can be neu-
tralised using an alkaline agent (preferably Avesta Neutra-
lising Agent, slaked lime, or soda) in combination with a
settling agent.
djusting the pH value of the waste water causes the heavy
metals to be precipitated as metal hydroxides. Precipita-
tion is optimal at pH 9.5.
The heavy metals form a sludge that can then be separa-
ted from the neutralised clear water. This sludge must be
treated as heavy metal waste and disposed of accordingly.
4.2. WASTE TREATMENT
Pickling creates waste that requires special treatment. Besi-
des what comes from the chemicals themselves, the packa-
ging must also be considered as waste.
The sludge obtained after neutralisation contains heavy
metals. This sludge must be sent away for disposal in accor-
dance with local waste regulations.
All materials used in the packaging (plastic containers,
cardboard boxes, etc.) of weldCare Finishing Chemicals’
products are recyclable.
How to use Avesta Neutralising Agent 502
1.
Stirring all the time, add
the neutralising agent to
the rinse water.
2.
The neutralising reaction
takes place instantly.
3.
Using litmus paper (for
example), check the pH of
the mixture. Precipitation of the heavy metals is opti-
mal at pH 9.5.
4.
When the waste water has reached an acceptable
pH value, wait for the sludge to sink to the bottom
and for the water to become clear. Adding a special
settling agent improves the precipitation of heavy
metals.
5. If analysis shows that the treated water satisfies local
regulations, it can be released into the sewage sys-
tem. To increase the degree of treatment, an extra
filter can be inserted before the water reaches the
sewage system.
6.
The sludge contains heavy metals and must be sent
to a waste-treatment plant.
CLEAR WATER
SLUDGE
34. 34
5. INSPECTION AND
TROUBLESHOOTING
The final step after pickling and prior to delivery should be inspection and testing of the results of
the cleaning process.
5.1. TEST METHODS
Test for free-iron contamination
One frequently used test is to repeatedly wet the surface with tap water and allow it to dry so that
the surface remains dry for a total of 8 hours in a 24-hour test period. Any residual iron rust is visible
after the test cycle.
The ferroxyl test (ASTM A-380) is another highly sensitive method for the detection of iron contami-
nation.
Test for organic contamination
As previously stated, the water-break test is a simple way of assessing the effectiveness of degrea-
sing. A thin sheet of water applied to a surface breaks around any surface contamination.
Test for pickling-agent residues
The pH value of the final rinse water gives a rough indication of acid residues. The pH value must be
7 (compare with the pH of incoming rinse water). Particular attention must be paid to tight corners,
narrow crevices, etc. These may hide residues.
Dried-on pickling chemicals
Water staining
Smut
Discoloration
35. I N S P E C T I O N A N D T R O U B L E S H O O T I N G 35
Tabelle 6: Surface defects and corrective actions
Surface defects Caused by Corrective action Precautions
Residual weld
oxides
Insufficient precleaning/pickling »
» Better pretreatment/
repickling
Avoid overpickling.
Rough surface Overpickling »
» Mechanical treatment/
repickling
Avoid both excessive
pickling times and pickling
in direct sunlight.
Rough surface Mechanical cleaning »
» Mechanical polishing
Smut/
discoloration
Poor cleaning/pickling »
» Desmutting (Avesta Finis-
hOne™ 630) or repickling or
mechanical treatment
Smut/
discoloration
Dried-on pickling chemicals (e.g.
pickling residues in crevices)
»
» Rinsing with high-pressure
water jet and then repickling
Smut/
discoloration
Surface contaminants (e.g. iron
particles)
»
» Passivation/decontamination
or repickling
Smut/
discoloration
Insufficient cleaning »
» Spot removal
Smut/
discoloration
Poor rinsing »
» Spot removal using a
cleaning agent
»
» Using deionised water for
final rinse
Smut/
discoloration
Trapped pickling acid “bleeding”
from narrow gaps
»
» Repickling
Smut/
discoloration
Contaminated rinse water »
» Passivation/decontamination
»
» Using deionised water when
surface requirements are
severe
»
» Rinsing with high-pressure jet
Water stains Contaminated rinse water »
» Using clean rinse water and/
or repickling
Water stains Dust »
» Using clean rinse water and
working in dust-free
environment
Work in dust-free
environment.
5.2. TROUBLESHOOTING
Inspection of a surface may reveal some remaining defects. The examples below show
the most common types.
36. 36
6. SAFE HANDLING AND STORAGE OF
PICKLING PRODUCTS
6.1. SAFETY RULES
Pickling products are hazardous substances and must be
handled with care. Certain rules must be followed to ensure
that the working environment is good and safe:
1.
Pickling chemicals must only be handled by persons
with a sound knowledge of the health hazards asso-
ciated with such chemicals. This means that the mate-
rial safety data sheet (SDS) and the product label must
be thoroughly studied before the chemicals are used.
2.
Eating, smoking and drinking must be forbidden in the
pickling area.
3. Employees handling pickling chemicals must wash their
hands and faces before eating and after finishing work.
4. All parts of the skin that are exposed to splashing must
be protected by an acid-resistant material such as poly-
ethylene (PE), polypropylene (PP) or polyvinyl chloride
(PVC). This means that employees handling pickling
chemicals (including during rinsing) must wear protec-
tive clothing as stipulated in the SDS for the product in
question.
5. The pickling area must be ventilated.
6. To avoid unnecessary evaporation, the containers/jars
must be kept closed.
7. To minimise the environmental impact, all pickling resi-
dues must be neutralised and all heavy metals sepa-
rated from the process water and sent to a waste
treatment plant.
Storage of pickling
products
37. S A F E H A N D L I N G A N D S T O R A G E O F P I C K L I N G P R O D U C T S 37
6.2. PERSONAL SAFETY
Health hazards can be avoided by the use of breathing equipment and skin pro-
tection. If a high degree of personal safety is to be ensured, we strongly recommend
that the following measures be regarded as compulsory.
For personal safety, a face mask (equipped with breathing apparatus) must always
be worn in connection with pickling. This mask must be equipped with a type B (grey)
breathing filter and a type P2 dust filter (all as per the Central European Norm –
CEN).
Pickling acids are aggressive and, on contact, can burn the skin. This can be avoi-
ded by protecting all exposed skin with acid-resistant clothing.
All cleaning chemicals from weldCare Finishing Chemicals are supplied with:
»
» Product information (PI) with reference numbers.
»
» Material safety data sheets (SDSs) as per ISO 11014-1 and 2001/58/EC.
These documents give the information necessary for the safe handling of the pro-
duct. They must always be consulted before using the product in question.
6.3. STORAGE
Pickling chemical containers must be stored indoors at 10 – 35°C. They must be kept
in an upright position with the lids tightly closed. The storage area must be clearly
defined and inaccessible for unauthorised persons. Pickling chemicals are sensitive
to high temperatures.
Caution: Because they accelerate the ageing process and destroy the product, sto-
rage temperatures above 45°C must be avoided. Pickling chemicals are perishable
goods. They give the best pickling results when they are fresh. This means that they
must not be kept on the shelf longer than necessary. It is better to buy small amounts
frequently rather than large amounts occasionally. Product composition and pick-
ling efficiency deteriorate with age and exposure to heat.
All Böhler weldCare products are delivered in UN certified PE containers that are
approved for the delivery of hazardous goods. Only recyclable materials are used
for product packaging.
39. JOIN! voestalpine Böhler Welding
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4,000 distribution partners around the world. Our extensive product portfolio and welding expertise combined with our
global presence guarantees we are close when you need us. Having a profound understanding of your needs enables
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