The document provides details on laboratory tests performed on cement and aggregates to determine their quality parameters. It describes procedures for determining the compressive strength, fineness, and setting time of cement. It also outlines tests to find the water absorption, impact value, abrasion value, flakiness index, and elongation index of aggregates used in construction. The tests are conducted according to Indian standards and provide important information about the strength and properties of materials used.
This presentation is of Penetration Test for Bitumen. Penetration test measures the hardness or softness of bitumen by measuring the depth in tenths of a millimeter to which a standard loaded needle will penetrate vertically in 5 seconds.
There are different grades of Bitumen used for the civil (especially for roads works) work. This presentation consists of the aim, significance, about the apparatus used procedure, noting the reading, Bis recommendation values and IRC recommendation values, precautions,
The penetration test is used as a measure of consistency. Higher values of penetration indicate softer consistency.
The test is widely used all over the world for classifying bituminous materials into different grades.
A summer training presentation on Highway material and soil testing.
In this presentation along with the entire test procedure readings and images of apparatus are used for better understanding.
The experiments are presented in a creative manner.
This presentation is of Penetration Test for Bitumen. Penetration test measures the hardness or softness of bitumen by measuring the depth in tenths of a millimeter to which a standard loaded needle will penetrate vertically in 5 seconds.
There are different grades of Bitumen used for the civil (especially for roads works) work. This presentation consists of the aim, significance, about the apparatus used procedure, noting the reading, Bis recommendation values and IRC recommendation values, precautions,
The penetration test is used as a measure of consistency. Higher values of penetration indicate softer consistency.
The test is widely used all over the world for classifying bituminous materials into different grades.
A summer training presentation on Highway material and soil testing.
In this presentation along with the entire test procedure readings and images of apparatus are used for better understanding.
The experiments are presented in a creative manner.
Astm designation c 136 for coarse aggregatesMuhammad Ahmad
Sieve Analysis for Coarse Aggregate as per ASTM. Slides contain all the relevant data and steps that would be required for the performance of sieve analysis of coarse aggregates.
Introduction on aggregate impact testing machine pptAbhishek Sagar
Toughness is the property of a material to resist impact. Due to traffic loads, the road stones are subjected to the pounding action or impact and there is possibility of stones breaking into smaller pieces. The road stones should therefore be tough enough to resist fracture under impact. A test designed to evaluate the toughness of stones
How to determine compressive strength of cement?Civil Insider
Get PPT here
https://civilinsider.com/compressive-strength-test-on-cement/
The compressive strength of hardened cement is the most important of all the properties. Therefore, it is not surprising that the cement is always tested for its strength at the laboratory before the cement is used in important works.
Why the compressive strength test of Cement is important? Compressive Strength Test on Cement mortar is calculated to find out whether the Cement conforms IS specifications or not and whether it can develop required strength or not when used in Concrete.
Any kind of strength testings are not done directly on Cement itself because of properties like shrinkage and cracking. So Compressive strength test on Cement either done in the form of mortar or concrete. In this article, we will take a look at the compressive strength test of cement mortar using standard sand conforming to IS 650-1991.
we supply all kind of bitumen/Asphalt from Iran refineries, such as
http://en.pasargadoil.com
and http://jeyoil.com/en/
As I am sure all of you a wear, unfortunately most of Iranian refineries does not deliver on LC Terms and your Discharge port, that is where we are coming in picture.
We have direct connections with those refinery so we purchase in cash on FOB iran and deliver to you and our clients on their own request port and LC Terms.
We will offer quality and services with suitable price.
Also we can arrange visiting side as well.
Astm designation c 136 for coarse aggregatesMuhammad Ahmad
Sieve Analysis for Coarse Aggregate as per ASTM. Slides contain all the relevant data and steps that would be required for the performance of sieve analysis of coarse aggregates.
Introduction on aggregate impact testing machine pptAbhishek Sagar
Toughness is the property of a material to resist impact. Due to traffic loads, the road stones are subjected to the pounding action or impact and there is possibility of stones breaking into smaller pieces. The road stones should therefore be tough enough to resist fracture under impact. A test designed to evaluate the toughness of stones
How to determine compressive strength of cement?Civil Insider
Get PPT here
https://civilinsider.com/compressive-strength-test-on-cement/
The compressive strength of hardened cement is the most important of all the properties. Therefore, it is not surprising that the cement is always tested for its strength at the laboratory before the cement is used in important works.
Why the compressive strength test of Cement is important? Compressive Strength Test on Cement mortar is calculated to find out whether the Cement conforms IS specifications or not and whether it can develop required strength or not when used in Concrete.
Any kind of strength testings are not done directly on Cement itself because of properties like shrinkage and cracking. So Compressive strength test on Cement either done in the form of mortar or concrete. In this article, we will take a look at the compressive strength test of cement mortar using standard sand conforming to IS 650-1991.
we supply all kind of bitumen/Asphalt from Iran refineries, such as
http://en.pasargadoil.com
and http://jeyoil.com/en/
As I am sure all of you a wear, unfortunately most of Iranian refineries does not deliver on LC Terms and your Discharge port, that is where we are coming in picture.
We have direct connections with those refinery so we purchase in cash on FOB iran and deliver to you and our clients on their own request port and LC Terms.
We will offer quality and services with suitable price.
Also we can arrange visiting side as well.
Lab Quality Confab 2015 - Learnings on French consolidationBertrand Guillot
#MedLab #Improvement #Stragegy What Labs in France are Learning about the Power of Quality Management Systems to Support Standardization and Performance of Multi-site Laboratory Organizations
Started to create milestones, we, balaji construction equipment marked our presence in the year 1986 and operate in the manufacturing/servicing of construction equipment, grouting pump since 27 years. Our quality services products have been always appreciated by our clients. Our spontaneous attitude and confident approach in offering an excellent range of Concrete Mixer, Concrete Vibrator, Watering Pump, Earth Rammer, Builders Hoist, Cube Cutting Machine, Cube Mould, Slum Cones, Weight Batcher has deepened our roots in the market. We, balaji construction equipment breathe with the aim of fully satisfying our clients with our high-quality products services. We are a unit of highly experienced professionals, all of them contributing at the best of their potentials to offer the highest degree of efficiency and client satisfaction.
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DETERMINATION OF UNCONFINED COMPRESSIVE STRENGTH OF SOIL in Foundation Engineering
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USE OF PAPER MILL SLUDGE AND COTTON WASTE IN CLAY BRICKS MANUFACTURINGijiert bestjournal
A large amount of paper mill sludge waste & cotton waste is produced at a place where paper mill
industry & textile industry is located respectively. So, many engineers are trying to convert a huge
quantum of waste in to useful building material. Paper mill sludge & cotton waste as main raw
material in the manufacture of bricks will not only create ample opportunity for its proper and useful
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Cement and admixtures and laboratory tests for cement, initial and final setting time, soundness test, compressive test, tests on concrete, types of admixtures
GraphRAG is All You need? LLM & Knowledge GraphGuy Korland
Guy Korland, CEO and Co-founder of FalkorDB, will review two articles on the integration of language models with knowledge graphs.
1. Unifying Large Language Models and Knowledge Graphs: A Roadmap.
https://arxiv.org/abs/2306.08302
2. Microsoft Research's GraphRAG paper and a review paper on various uses of knowledge graphs:
https://www.microsoft.com/en-us/research/blog/graphrag-unlocking-llm-discovery-on-narrative-private-data/
GDG Cloud Southlake #33: Boule & Rebala: Effective AppSec in SDLC using Deplo...James Anderson
Effective Application Security in Software Delivery lifecycle using Deployment Firewall and DBOM
The modern software delivery process (or the CI/CD process) includes many tools, distributed teams, open-source code, and cloud platforms. Constant focus on speed to release software to market, along with the traditional slow and manual security checks has caused gaps in continuous security as an important piece in the software supply chain. Today organizations feel more susceptible to external and internal cyber threats due to the vast attack surface in their applications supply chain and the lack of end-to-end governance and risk management.
The software team must secure its software delivery process to avoid vulnerability and security breaches. This needs to be achieved with existing tool chains and without extensive rework of the delivery processes. This talk will present strategies and techniques for providing visibility into the true risk of the existing vulnerabilities, preventing the introduction of security issues in the software, resolving vulnerabilities in production environments quickly, and capturing the deployment bill of materials (DBOM).
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Bob Boule
Robert Boule is a technology enthusiast with PASSION for technology and making things work along with a knack for helping others understand how things work. He comes with around 20 years of solution engineering experience in application security, software continuous delivery, and SaaS platforms. He is known for his dynamic presentations in CI/CD and application security integrated in software delivery lifecycle.
Gopinath Rebala
Gopinath Rebala is the CTO of OpsMx, where he has overall responsibility for the machine learning and data processing architectures for Secure Software Delivery. Gopi also has a strong connection with our customers, leading design and architecture for strategic implementations. Gopi is a frequent speaker and well-known leader in continuous delivery and integrating security into software delivery.
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Are you looking to streamline your workflows and boost your projects’ efficiency? Do you find yourself searching for ways to add flexibility and control over your FME workflows? If so, you’re in the right place.
Join us for an insightful dive into the world of FME parameters, a critical element in optimizing workflow efficiency. This webinar marks the beginning of our three-part “Essentials of Automation” series. This first webinar is designed to equip you with the knowledge and skills to utilize parameters effectively: enhancing the flexibility, maintainability, and user control of your FME projects.
Here’s what you’ll gain:
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Don’t miss this opportunity to elevate your FME expertise and drive your projects to new heights of efficiency.
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Paper presented at SYNERGY workshop at AVI 2024, Genoa, Italy. 3rd June 2024
https://alandix.com/academic/papers/synergy2024-epistemic/
As machine learning integrates deeper into human-computer interactions, the concept of epistemic interaction emerges, aiming to refine these interactions to enhance system adaptability. This approach encourages minor, intentional adjustments in user behaviour to enrich the data available for system learning. This paper introduces epistemic interaction within the context of human-system communication, illustrating how deliberate interaction design can improve system understanding and adaptation. Through concrete examples, we demonstrate the potential of epistemic interaction to significantly advance human-computer interaction by leveraging intuitive human communication strategies to inform system design and functionality, offering a novel pathway for enriching user-system engagements.
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The latest edition of the OT/ICS and IoT security Threat Landscape Report 2024 also covers:
State of global ICS asset and network exposure
Sectoral targets and attacks as well as the cost of ransom
Global APT activity, AI usage, actor and tactic profiles, and implications
Rise in volumes of AI-powered cyberattacks
Major cyber events in 2024
Malware and malicious payload trends
Cyberattack types and targets
Vulnerability exploit attempts on CVEs
Attacks on counties – USA
Expansion of bot farms – how, where, and why
In-depth analysis of the cyber threat landscape across North America, South America, Europe, APAC, and the Middle East
Why are attacks on smart factories rising?
Cyber risk predictions
Axis of attacks – Europe
Systemic attacks in the Middle East
Download the full report from here:
https://sectrio.com/resources/ot-threat-landscape-reports/sectrio-releases-ot-ics-and-iot-security-threat-landscape-report-2024/
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Learn about:
• The Future of Testing: How AI is shifting testing towards verification, analysis, and higher-level skills, while reducing repetitive tasks.
• Test Automation: How AI-powered test case generation, optimization, and self-healing tests are making testing more efficient and effective.
• Visual Testing: Explore the emerging capabilities of AI in visual testing and how it's set to revolutionize UI verification.
• Inflectra's AI Solutions: See demonstrations of Inflectra's cutting-edge AI tools like the ChatGPT plugin and Azure Open AI platform, designed to streamline your testing process.
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Monitoring Java Application Security with JDK Tools and JFR Events
Quality control lab
1. Quality Control lab
As per the schedule we have to work for few days in quality control laboratory to understand the
strength and other parameters of material used.
Here are the few tests that we performed in the quality control lab.
Lab tests on cement :
DETERMINATION OF COMPRESSIVE STRENGTH OF CEMENT.
(IS: 4031 – Part – 6)
Object:
Determination of the compressive strength of standard cement mortar cubes compacted by means
of a standard vibration machine.
Apparatus:
Vibration machine, cube moulds of size 7.06 cms(confirming to IS : 4031 – 1968), and Standard
Sand to be used in the test shall be confirm to IS : 650 – 1966.
Procedure:
Mix Proportions and Mixing: Clean appliances shall be used for mixing and the temperature of
the water and that of the test room at the time when the above operations are being performed
shall be 270
+/- 20
C. Place in a container a mixture of cement and standard sand in the proportion
of 1 : 3 by weight; mix it dry, with a trowel for one minute and then with water until the mixture
is of uniform colour. The quantity of water to be used shall be as specified below. In any event, it
should not take more than 4 minutes to obtain uniform colored mix. If it exceeds 4 minutes, the
mixture shall be rejected and the operation repeated with a fresh quantity of cement, sand and
water.
The material for each cube shall be mixed separately and the quantity of cement, standard sand
and water shall be as follows: Percentage of water to be added to the cement and sand in ( 1:3 )
cm (P/4 + 3) X % combined weight of cement and sand = (P/4 + 3) X 800/100.
Cement 200 gms, standard sand 600 gms, water (P/4 + 3) per cent of combined weight of cement
and sand, where P is the percentage of water required to produce a paste of standard consistency.
Molding Specimens:
In assembling the moulds ready for use, cover the joints between the halves of the mould with a
thin film of petroleum jelly and apply a similar coating of petroleum jelly between the contact
surfaces of the bottom of the mould and its base plate in order to ensure that no water escapes
during vibration. Treat the interior faces of the mould with a thin coating of mould oil. Place the
assembled mould on the table of the vibration machine and firmly hold it in position by means of
suitable clamps. Securely attach a Hooper of suitable size and shape at the top of the mould to
facilitate filling and this Hooper shall not be removed until completion of the vibration.
Immediately after mixing the mortar, place the mortar in the cube mould and rod with a rod. The
mortar shall be rodded 20 times in about 8 seconds to ensure elimination of entrained air and
honey combing. Place the remaining quantity of mortar in the Hooper of the cube mould and rod
again as specified for the first layer and then compact the mortar by vibration. The period of
vibration shall be two minutes at the specified speed of 12000 +/- 400 vibrations per minutes. At
2. the end of vibration remove the mould together with the base plate from the machine and finish
the top surface of the cube in the mould by smoothing surface with the blade of a trowel.
Curing Specimens:
Keep the filled moulds at a temperature of 270
C +/- 20
C in an atmosphere of at least 90% relative
humidity for about 24 hours after completion of vibration. At the end of that period remove them
from the moulds immediately submerge in clean fresh water and keep them under water until
testing. The water in which the cubes are submerged shall be renewed every 7 days and shall be
maintained at a temperature of 270
C +/- 20
C. After they have been taken out and until they are
tested, the cubes shall not be allowed to become dry.
Testing:
Test three cubes for compressive strength at the periods mentioned under the relevant
specifications for different hydraulic cements, the periods being reckoned from the completion of
vibration. The compressive strength shall be the average of the strengths of the three cubes for
each period of curing. The cubes shall be tested on their sides without any packing between the
cube and the steel platens of the testing machine. One of the platens shall be carried base and
shall be self-adjusting and the load shall be steadily and uniformly applied, starting from zero at
a rate of 350 kgs/cm2
/min.
Calculation:
Calculate the compressive strength from the crushing load and the average area over which the
load is applied. Express the results in kgs/cm2
to the nearest 0.5 kg/cm2
.
Compressive strength, kg/cm2
= P/A, where ‘P’ is the crushing load in kg, and ‘A’ is the area in
cm2
.
CEMENT: FINENESS BY DRY SIEVING REFERENCE: IS 4031 – (PART – 1) 1996
IMPORTANCE: During manufacturing, cement must be ground to be uniformly fine
Otherwise concrete needs large amount of water for mixing which results in bleeding as
well as poor workmanship.
• Test sieve of non-corrodible metal having 150 mm to 200 mm dia, and
40 mm to 100 mm depth fitted with 90 µm mesh sieve cloth of woven stainless steel or other
abrasion resistant non- corrodible wires.
• Suitable tray with lid to fit sieve size.
3. • Stoppered jar with blunt ended stirrer rod
• Weighing balance to weigh up to 10 gms to nearest 10 mg.
• Nylon or pure bristle brush (25 mm / 40 mm bristles) for cleaning sieves.
PROCEDURE: Determination of cement residue:
• Agitate the cement sample by shaking for 2 minutes in a stoppered jar to disperse the
agglomerates. Wait for few minutes.
• Stir the resulting powder gently with dry rod to distribute the fines throughout the sample.
• Weigh approx. 10 gm of cement and put in sieve fitted with bottom tray and top lid.
• Agitate and shake the sieve thoroughly
• Weigh the residue – retained on sieve.
• Clean base of sieve gently by brush to remove fine material.
• Find out % (R1) of residue in comparison with total weight of sample.
• Repeat the procedure at least twice till results do not differ by more than 1%.
CALCULATION Find out mean of observations and express this percentage as R
CEMENT: DETERMINATION OF SETTING TIME REFERENCE: IS 4031 – (PART –
5) 1996
IMPORTANCE OF TEST: The object is to distinguish between, quick setting and normal
setting time and to detect the deterioration due to storage.
APPARATUS
• Vicat Apparatus
• Balance (capacity 1000 gms, accuracy 0.1 gm)
• Annular attachment of Vicat Apparatus
4. TEMPERATURE • Dry Materials, Water and Moulding Room : 27 + 2O C
& HUMIDITY • Relative Humidity in Laboratory : 65 + 5 %
PROCEDURE On a non-porous platform
• Mix neat cement with enough water to give a paste of Standard
Consistency.
• Start stop watch immediately on adding water to cement. Note
Stop watch reading (To)
• Rest Vicat mould on non-porous plate and fill it completely with cement paste. Level of top
surface and expel air by shaking.
• Place test block with mould under the rod bearing needle of Vicat apparatus and bring rod
level with top of test specimen. Release needle slowly and let it penetrate in the test block.
• Repeat the procedure until needle stops of distance of (5 + 0.5) mm from base of test block.
Read the stop watch and note the time (T1).
• Replace needle by annular attachment. Repeat procedure of releasing the needle till needle
makes an impression on top of test block while attachment fails to do so. Read the stop
watch and note time (T2).
CALCULATION
Initial Setting Time (IST) = (T1 – T0)
Final Setting Time (FST) = (T2 – T 0)
REPORTING Report IST & FST to nearest 5 minutes
5. Lab Tests on Aggregates:
WATER ABSORPTION TEST:
This test helps to determine the water absorption of coarse aggregates as per IS: 2386 (Part III) –
1963. For this test a sample not less than 2000g should be used. The apparatus used for this test
are :-
Wire basket – perforated, electroplated or plastic coated with wire hangers for suspending it from
the balance, Water-tight container for suspending the basket, Dry soft absorbent cloth – 75cm x
45cm (2 nos.), Shallow tray of minimum 650 sq.cm area, Air-tight container of a capacity similar
to the basket and Oven.
Procedure to determine water absorption of Aggregates.
i) The sample should be thoroughly washed to remove finer particles and dust, drained and then
placed in the wire basket and immersed in distilled water at a temperature between 22 and 32o
C.
ii) After immersion, the entrapped air should be removed by lifting the basket and allowing it to
drop 25 times in 25 seconds. The basket and sample should remain immersed for a period of 24
+ ½ hrs afterwards.
iii) The basket and aggregates should then be removed from the water, allowed to drain for a few
minutes, after which the aggregates should be gently emptied from the basket on to one of the
dry clothes and gently surface-dried with the cloth, transferring it to a second dry cloth when the
first would remove no further moisture. The aggregates should be spread on the second cloth and
exposed to the atmosphere away from direct sunlight till it appears to be completely surface-dry.
The aggregates should be weighed (Weight ‘A’).
iv) The aggregates should then be placed in an oven at a temperature of 100 to 110o
C for 24hrs.
It should then be re moved from the oven, cooled and weighed (Weight ‘B’).
Formula used is Water absorption = [(A - B)/B] x 100%.
Two such tests should be done and the individual and mean results should be reported. A sample
Performa for the record of the test is
6. AGGREGATE IMPACT VALUE
This test is done to determine the aggregate impact value of coarse aggregates as per IS: 2386
(Part IV) – 1963. The apparatus used for determining aggregate impact value of coarse
aggregates is
Impact testing machine conforming to IS: 2386 (Part IV)- 1963,IS Sieves of sizes – 12.5mm,
10mm and 2.36mm, A cylindrical metal measure of 75mm dia. and 50mm depth, A tamping rod
of 10mm circular cross section and 230mm length, rounded at one end and Oven.
Preparation of Sample
i) The test sample should conform to the following grading:
- Passing through 12.5mm IS Sieve – 100%
- Retention on 10mm IS Sieve – 100%
ii) The sample should be oven-dried for 4hrs. at a temperature of 100 to 110o
C and cooled.
iii) The measure should be about one-third full with the prepared aggregates and tamped with 25
strokes of the tamping rod.
A further similar quantity of aggregates should be added and a further tamping of 25 strokes
given. The measure should finally be filled to overflow, tamped 25 times and the surplus
aggregates struck off, using a tamping rod as a straight edge. The net weight of the aggregates in
the measure should be determined to the nearest gram (Weight ‘A’).
7. Procedure to determine Aggregate Impact Value
i) The cup of the impact testing machine should be fixed firmly in position on the base of the
machine and the whole of the test sample placed in it and compacted by 25 strokes of the
tamping rod.
ii) The hammer should be raised to 380mm above the upper surface of the aggregates in the cup
and allowed to fall freely onto the aggregates. The test sample should be subjected to a total of
15 such blows, each being delivered at an interval of not less than one second.
Reporting of Results
i) The sample should be removed and sieved through a 2.36mm IS Sieve. The fraction passing
through should be weighed (Weight ‘B’). The fraction retained on the sieve should also be
weighed (Weight ‘C’) and if the total weight (B+C) is less than the initial weight (A) by more
than one gram, the result should be discarded and a fresh test done.
ii) The ratio of the weight of the fines formed to the total sample weight should be expressed as a
percentage.
Aggregate impact value = (B/A) x 100%
iii) Two such tests should be carried out and the mean of the results should be reported.
AGGREGATE ABRASION VALUE
This test helps to determine the abrasion value of coarse aggregates as per IS: 2386 (Part IV) –
1963.
The apparatus used in this test are Los Angles abrasion testing machine, IS Sieve of size –
1.7mm, Abrasive charge – 12 nos. cast iron or steel spheres approximately 48mm dia. and each
weighing between 390 and 445g ensuring that the total weight of charge is 5000 +25g and Oven.
Sample Preparation
The test sample should consist of clean aggregates which has been dried in an oven at 105 to
110oC to a substantially constant weight and should conform to one of the gradings shown in the
table below:
8. Procedure to determine Aggregate Abrasion Value
The test sample and the abrasive charge should be placed in the Los Angles abrasion testing
machine and the machine rotated at a speed of 20 to 33 revolutions/minute for 1000 revolutions.
At the completion of the test, the material should be discharged and sieved through 1.70mm IS
Sieve.
Reporting of Results
i) The material coarser than 1.70mm IS Sieve should be washed, dried in an oven at a
temperature of 100 to 110o
C to a constant weight and weighed (Weight ‘B’).
ii) The proportion of loss between weight ‘A’ and weight ‘B’ of the test sample should be
expressed as a percentage of the original weight of the test sample. This value should be reported
as,
Aggregate abrasion value = (A-B)/B x 100%.
9. Flakiness index and Elongation Index of Coarse Aggregates
AIM:
i. To determine the elongation index of the given aggregates
ii. To determine the flakiness index of the given aggregates
APPARATUS:
The apparatus for the shape tests consists of the following:
(i) A standard thickness gauge
(ii) A standard length gauge
(iii) IS sieves of sizes 63, 50 40, 31.5, 25, 20, 16, 12.5,10 and 6.3mm
(iv) A balance of capacity 5kg, readable and accurate up to 1 gm.
THEORY:
The particle shape of aggregates is determined by the percentages of flaky and
elongated particles contained in it. For base course and construction of bituminous and
10. cement concrete types, the presence of flaky and elongated particles are considered
undesirable as these cause inherent weakness with possibilities of breaking down under
heavy loads. Thus, evaluation of shape of the particles, particularly with reference to
flakiness and elongation is necessary.
The Flakiness index of aggregates is the percentage by weight of particles whose
least dimension (thickness) is less than three- fifths (0.6times) of their mean dimension.
This test is not applicable to sizes smaller than 6.3mm.
The Elongation index of an aggregate is the percentage by weight of particles
whose greatest dimension (length) is greater than nine-fifths (1.8times) their mean
dimension. This test is not applicable for sizes smaller than 6.3mm.
PROCEDURE:
i) Sieve the sample through the IS sieves (as specified in the table).
ii)Take a minimum of 200 pieces of each fraction to be tested and weigh them.
(iii) In order to separate the flaky materials, gauge each fraction for thickness on a
thickness gauge. The width of the slot used should be of the dimensions specified in
column (4) of the table for the appropriate size of the material.
(iv) Weigh the flaky material passing the gauge to an accuracy of at least 0.1 per cent of
the test sample.
(v) In order to separate the elongated materials, gauge each fraction for length on a length
gauge. The width of the slot used should be of the dimensions specified in column (6)
of the table for the appropriate size of the material.
(vi) Weigh the elongated material retained on the gauge to an accuracy of at least 0.1 per
cent of the test sample.
11. Size of aggregates Weight of
fraction
consisting
of at least
200
pieces,g
Thickness
gauge
size, mm
Weight of
aggregates
in each
fraction
passing
thickness
gauge,mm
Length
gauge
size,
mm
Weight of
aggregates
in each
fraction
retained on
length
gauge,mm
Passing
through
IS Sieve,
mm
Retained
on IS
Sieve,
mm
1 2 3 4 5 6 7
63 50 W1 23.90 X1 - -
50 40 W2 27.00 X2 81.00 Y1
40 31.5 W3 19.50 X3 58.00 Y2
31.5 25 W4 16.95 X4 - -
25 20 W5 13.50 X5 40.5 Y3
20 16 W6 10.80 X6 32.4 Y4
16 12.5 W7 8.55 X7 25.5 Y5
12.5 10 W8 6.75 X8 20.2 Y6
10 6.3 W9 4.89 X9 14.7 Y7
Total W = X = Y =
12. OBSERVATIONS:
Flakiness Index = (X1+ X2+…..) / (W1 + W2 + ….) X 100
Elongation Index = (Y1 + Y2 + …) / (W1 + W2 + ….) X 100
RESULT:
i) Flakiness Index =
ii) Elongation Index =
13.
14. Lab Tests on Concrete
DETERMINATION OF COMPRESSIVE STRENGTH OF CONCRETE.
(IS: 516 – 1959)
Apparatus:
Testing Machine: The testing machine may be of any reliable type of sufficient capacity for the
tests and capable of applying the load at the specified rate. The permissible error shall not be
greater than 2 percent of the maximum load. The testing machine shall be equipped with two
steel bearing platens with hardened faces. One of the platens shall be fitted with a ball seating in
the form the portion of a sphere, the center of which coincides with the central point of the face
of the platen. The other compression platen shall be plain rigid bearing block. The bearing faces
of both platens shall be at least as larger as, and preferably larger than the nominal size of the
specimen to which the load is applied. The bearing surface of the platens, when new, shall not
depart from a plane by more than 0.01mm at any point, and they shall be maintained with a
permissible variation limit of 0.02mm. the movable portion of the spherical seated compression
platen shall be held on the spherical seat, but the design shall be such that the bearing face can be
rotated freely and tilted through small angles in any direction.
Age at test: Tests shall be made at recognized ages of the test specimens, the most usual being 7
and 28 days. The ages shall be calculated from the time of the addition of water of the dry
ingredients.
Number of Specimens: At least three specimens, preferably from different batches, shall be made
for testing at each selected age.
Procedure:
Specimens stored in water shall be tested immediately on removal from the water and while they
are still in the wet condition. Surface water and grit shall be wiped off the specimens and any
projecting find removed specimens when received dry shall be kept in water for 24 hours before
they are taken for testing. The dimensions of the specimens to the nearest 0.2mm and their
weight shall be noted before testing.
Placing the specimen in the testing machine the bearing surface of the testing machine shall be
wiped clean and any loose sand or other material removed from the surface of the specimen,
which are to be in contact with the compression platens. In the case of cubes, the specimen shall
be placed in the machine in such a manner that the load shall be applied to opposite sides of the
cubes as cast, that is, not to the top and bottom. The axise of the specimen shall be carefully
aligned with the center of thrust of the spherically seated platen. No packing shall be used
between the faces of the test specimen and the steel platen of the testing machine. As the
spherically seated block is brought to bear on
15. the specimen the movable portion shall be rotated gently by hand so that uniform seating may be
obtained. The load shall be applied without shock and increased continuously at a rate of
approximately 140 kg/cm2
/min.until the resistance of the specimen to the increasing load breaks
down and no grater load can be sustained. The maximum load applied to the specimen shall then
be recorded and the appearance of the concrete and any unusual features in the type of failure
shall be noted.
Calculation: The measured compressive strength of the specimen shall be calculated by dividing
the maximum load applied to the specimen during the test by the cross sectional area, calculated
from the mean dimensions of the section and shall be expressed to the nearest kg per cm2
.
Average of three values shall be taken as the representative of the batch provided the individual
variation is not more than +/-15 percent of the average. Otherwise repeat tests shall be made.
A correction factor according to the height / diameter ratio of specimen after capping shall be
obtained from the curve shown in Fig.1 of IS:516-1959. The product of this correction factor and
the measured compressive strength shall be known as the corrected compressive strength this
being the equivalent strength of a cylinder having a height/diameter ratio of two. The equivalent
cube strength of the concrete shall be determined by multiplying the corrected cylinder strength
by 5/4.
DETERMINATION OF FLEXURAL STRENGTH OF CONCRETE.
(IS: 516 – 1959)
Object: Determination of the flexural strength of concrete specimen.
Apparatus:
a) Standard moulds of size 15 X 15 X 70 cms for preparing the specimen.
b) Tamping bar.
c) Testing Machine.
Procedure:
Test specimens stored in water at a temperature of 250
C to 300
C for 48 hours before testing shall
be tested immediately on removal from the water, whilst they are still in a wet condition. The
dimensions of each specimen shall be noted before testing. No preparation of the surface is
required.
Placing the specimen in the testing machine: The bearing surfaces of the supporting and loading
rollers shall be wiped clean, and any loose sand or other material removed from the surfaces of
the specimen where they are to make contact with the rollers. The specimen shall then be placed
in the machine in such a manner that the load shall be applied to the upper most surface as cast in
the mould, along two lines spaced 20 or 13.30 cms apart. The axis of the specimen shall be
carefully aligned with the axis of the loading device. No packing shall be used between the
bearing surface of the specimen and the rollers. The load shall be applied with shock and
increasing continuously at a rate such that the extreme fiber stress increases at approximately 7
16. kgs/cm2
/mm for the 10 cm specimens, the load shall be increased until the specimen falls, and
the maximum load applied to the specimen during the test shall be recorded. The appearance of
the fractured faces of the concrete and any unusual features in the type of failure shall be noted.
Calculation:
The flexural strength of the specimen shall be expressed as the modules of rapture ‘ fb’ which if
‘a’ equals the distance between the line of fracture and the nearer support measured on the
centerline of the tensile side of the specimen, in cm, shall be calculated to the nearest 0.5 kg/cm2
as follows.
fb = ( p X l ) / ( b X d2
)
When ‘a’ is greater than 20.0 cm . for 15.0 cm specimen or greater than 13.30 cm for a 10.0 cm
specimen, or
fb = ( 3p X a ) / ( b X d2
)
When ‘a’ is less than 20.0 cms. but greater than 17.0 cms for 15.00 cms specimen, or less than
13.30 cms but greater than 11.0 cms for a 10.0 cms specimen, where b = measured width in cms
of the specimen, d = measured depth in cms of the specimen at the point of failure, l = length in
cm. of the span on which the specimen was supported, and p = maximum load in kg. applied to
the specimen.
If ‘a’ is less than 17.0 cm. for a 15 cm specimen or less than 11.0 cm for a 10.0 cm specimen, the
result of the test shall be discarded.