1
CIVIL ENGINEERING DEPARMENT
DCC 3122
HIGHWAY LAB REPORT
TITLE DETERMINATION OD AGGREGATE IMPACT VALUE
COURSE / SESSION DCC 3122 – GEOTECHNIC AND HIGHWAY LABORATORY
PREPARE BY GROUP GROUP A
GROUP MEMBERS 1. AINUNYASMINE BINTI HASLAN
03DKA16F2023
2. MOHD IQBAL NAQIUDDIN BIN ZULKIPLI
03DKA16F2018
3. MOHAMAD AMIR SAIF BIN ABDUL HAMID
03DKA16F1130
4. MUHAMMAD AIZAT BIN ABD RASHID
03DKA16F2021
LECTURER’S NAME 1. PUAN SALMA BINTI YAHYA
2. EN. AHMAD TAZRI BIN AZIZ
3. CIK FAIZAH BINTI HJ. ZAINAL ABIDIN
PRACTICAL DATE DECEMBER 5, 2017
SUBMISSION DATE DECEMBER 12, 2017
2
Table of Contents
OBJECTIVES ................................................................................................................................. 1
THEORY ....................................................................................................................................... 2
APPARATUS ................................................................................................................................. 3
PROCEDURE .................................................................................................................................. 4
RESULT / DATA ........................................................................................................................... 6
CALCULATIONS .......................................................................................................................... 6
DISCUSSION .................................................................................................................................. 7
PRECAUTIONS .............................................................................................................................. 8
CONCLUSION ................................................................................................................................ 9
REFFERENCES ............................................................................................................................ 10
3
OBJECTIVES
To assess their suitability inroad construction on the basis of impact value. This test is done to
determine the aggregate impact value of coarse aggregates. Many tests have been developed
toempirically characterize aggregate properties without, necessarily, strong relationships to the
performance of final products incorporating an aggregate. This seems to be particularly true for
aggregate “toughness and abrasion resistance” and “durability and soundness.” The objective of
this research is to select tests for characterizing aggregate toughness/abrasion resistance and
durability/soundness that are related to the performance of asphalt concrete pavements.
4
THEORY
The property of a material to resist impact is known as toughness. Due to movement of vehicles
on the road the aggregates are subjected to impact resulting in their breaking down into smaller
pieces. The aggregates should therefore have sufficient toughness to resist their disintegration due
to impact. This characteristic is measured by impact value test. The aggregate impact value is a
measure of resistance to sudden impact or shock, which may differ from its resistance to gradually
applied compressive load.
Aggregate Impact Value (AIV) is the percentage of fines produced from the aggregate sample after
subjecting it to a standard amount of impact. The standard amount of impact is produced by a
known weight, i.e. a steel cylinder, falling a set height, a prescribed number of times, onto an
amount of aggregate of standard size and weight retained in a mould. Aggregate Impact Values,
(AIV’s), below 10 are regarded as strong, and AIV’s above 35 would normally be regarded as too
weak for use in road surfaces. Aggregate Impact Values and Aggregate Crushing Values are often
numerically very similar, and indicate similar aggregate strength properties. Classification of
aggregates using Aggregate Impact Value is as given below:
Aggregate Impact Value Classification
<20%.= Exceptionally Strong
10 – 20% .=Strong
20-30%. =Satisfactory for road surfacing
>35%.= Weak for road surfacing
5
APPARATUS
1. Aggregate Impact Value Test Machine
2. BS test sieve
3. A metal tamping rod
4. A weighing Balance
5. Aggreagate
6
PROCEDURE
The test sample was prepared as follows:
1. The sample was sieve through test sieves and then the material passing through the sieve
and that retained on the sieve was collected.
2. The cylindrical mould was measure and it weight recorded as W1.
3. The cylindrical mould was then fill in measure layers and then each layers was tamper with
25 blows using the tamping rod. Each blow was given by allowing the Tamping rod to fall
freely from a height of about 50mm above the Surface of the Aggregate, evenly distributed
over the surface.
4. The net mass of Aggregate was then measure and recorded as W2.
5. The steel cup (which is part of the test machine) was fixed firmly in position on the base
of the machine.
6. The height of the hammer was adjusted so that its lower face is 380mm above the upper
surface of the Aggregate and the allow it to fall freely To the Aggregate.
7. The Aggregate was subjected to a total of 15 such blows, each being delivered at an interva l
of not less than one second.
8. The crushed Aggregate was then removed and was pass through a sieve size 2.36mm.
7
9. The fraction passing the sieve size 2.36 was measured and the weight was recorded as B.
The weighed of the fraction retained was also measured and the weight recorded as C.
8
RESULT / DATA
S1 S2
Total weight of dry sample
(W1)
560.5g 463.7g
Weight of portion 2.36mm
sieve. (W2)
95.1g 71g
Aggregate impact value (%) 17% 15%
CALCULATION
Sample 1
1. Total weight of dry sample (W1) :
3255.7 g – 2695.2 g = 560.6 g
2. Weight of portion passing 2.36 mm sieve (W2) :
582.7 g – 487.6 g = 95.1 g
3. Aggregate impact vaue :
95.1
560.5 × 100 = 17 %
Sample 2
1. Total weight of dry sample (W1) :
3154 g – 2690 g = 463.7 g
2. Weight of portion passing 2.36 mm sieve (W2) :
558.4 g 487.4 g = 71 g
3. Aggregate impact vaue :
71
463.7× 100 = 15 %
9
DISCUSSION
After 15 blows from the hammer, the crush sample was reduced to smaller sizes. The proportion
of material passing sieve size 2.36mm was smaller than that retained. The aggregate impact value
indicates a relative measure of the resistance of the aggregate to a sudden shock or impact which
in some aggregates differs from its resistance to a slow compressive load. From the calculat ions
done we know that the aggregate can be acceptable as their Aggregate Impact value is less then
20% Aggregate Impact Value
10
PRECAUTIONS
1. To wear safety shoes & goggles at the time of testing.
2. Before testing, machine should be properly checked.
3. After test clean the sieve by a smooth brush.
4. Keep all the exposed metal parts greased.
5. Keep the guide rods firmly fixed to the base & top plate.
6. Equipment should be clean thoroughly before testing & after testing.
7. Special care should be taken that no outer air enters when using the balance.
11
CONCLUSION
From the experiment, we get the value is 17% and 15%less than the requirement of JKR’s;
20%.Aggregate physical property must lower Aggregate Impact Value, AIV because is tougher
and resistance to crushed. We can conclude that the aggregate been used are medium toughand
resistant to be crash. It’s because the value are more than half than JKR’s requirement.These
experiments are successful because its still not exceed the JKR’s requirement.
12
REFERENCES
1. Transportation laboratory manual, civil engineering department, university of Ilorin.
2. org/building/building-material/determination-of-aggregateimpact-value/1355/
3. engineeringcivil.com/aggregate- impact-value.html
4. org/2013/05/07/aggregate- impact-value- is2386-part- iv-1963/
5. com/plain-reinforced-concrete-experiments/exp-4-aggregateimpact-value/