Split tensile strength test is a method of determining the
tensile strength of concrete using a cylinder which splits across the vertical
diameter. It is an indirect method of testing tensile strength of concrete.
The tensile strength of concrete is one of the basic and
important properties. Splitting tensile strength test on concrete cylinder is a
method to determine the tensile strength of concrete.
The concrete is very weak in tension due to its brittle
nature and is not expected to resist the direct tension. The concrete
develops cracks when subjected to tensile forces. Thus, it is necessary to
determine the tensile strength of concrete to determine the load at which
the concrete members may crack.
AIM:
To determine
the splitting tensile strength of cylindrical concrete specimens.
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 rate
specified in 5.5. The permissible error shall be not greater than ± 2 percent
of the maximum load.
Cylinders
-The cylindrical mould shall be of 150 mm diameter and 300 mm height conforming
to IS:10086-1982.
Weights
and weighing device, Tools and containers for mixing, Tamper (square in cross
section) etc.
FIGURE:
PROCEDURE:
- SAMPLING OF MATERIALS –
Samples
of aggregates for each batch of concrete shall be of the desired grading and
shall be in an air-dried condition. The cement samples, on arrival at the
laboratory, shall be thoroughly mixed dry either by hand or in a suitable mixer
in such a manner as to ensure the greatest possible blending and uniformity in
the material.
- PROPORTIONING –
The
proportions of the materials, including water, in concrete mixes used for
determining the suitability of the materials available, shall be similar in all
respects to those to be employed in the work.
- WEIGHING –
The
quantities of cement, each size of aggregate, and water for each batch shall be
determined by weight, to an accuracy of 0.1 percent of the total weight of the
batch.
- MIXING CONCRETE –
The
concrete shall be mixed by hand, or preferably, in a laboratory batch mixer, in
such a manner as to avoid loss of water or other materials. Each batch of
concrete shall be of such a size as to leave about 10 percent excess after
moulding the desired number of test specimens.
- MOULD –
The
cylindrical mould shall be of 150 mm diameter and 300 mm height conforming to
IS: 10086-1982.
- COMPACTING –
The
test specimens shall be made as soon as practicable after mixing, and in such a
way as to produce full compaction of the concrete with neither segregation nor
excessive laitance.
- CURING –
The
test specimens shall be stored in a place, free from vibration, in moist air of
at least 90 percent relative humidity and at a temperature of 27° ± 2°C for 24
hours ± ½ hour from the time of addition of water to the dry ingredients.
- 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.
9.
Two bearings strip of nominal (1/8 in i.e
3.175 mm) thick plywood, free of imperfections, approximately (25 mm) wide, and
of length equal to or slightly longer than that of the specimen should be
provided for each specimen.
10.
The bearing strips are placed between the
specimen and both upper and lower bearing blocks of the testing machine or
between the specimen and the supplemental bars or plates.
11.
Draw diametric lines an each end of the
specimen using a suitable device that will ensure that they are in the same
axial plane. Centre one of the plywood strips along the centre of the lower
bearing block.
12.
Place the specimen on the plywood strip and
align so that the lines marked on the ends of the specimen are vertical and
cantered over the plywood strip.
13.
Place a second plywood strip lengthwise on
the cylinder, cantered on the lines marked on the ends of the cylinder. Apply
the load continuously and without shock, at a constant rate within, the range
of 689 to 1380 kPa/min splitting tensile stress until failure of the specimen
14.
Record the maximum applied load indicated by
the testing machine at failure. Note the type of failure and appearance of
fracture.
OBSERVATIONS:
Calculations
of Mix Proportion
Mix
Proportion of Concrete
|
For
1 m3 of concrete
|
For
one batch of concrete
|
Coarse
aggregate (kg)
|
||
Fine
aggregate (kg)
|
||
Cement
(kg)
|
||
Water
(kg)
|
||
S/A
|
||
w/c
ratio
|
||
Admixture
|
Sr.
No.
|
Age
of Spec
imen
|
Identi-fication
Mark
|
Dia.
of Spec-
imen
(mm)
|
Depth
(mm)
|
Maximum
Load (N)
|
Tensile
Strength (MPa)
|
Avg
Tensile Strength (Mpa)
|
1
|
7
days
|
||||||
2
|
|||||||
3
|
|||||||
4
|
28
days
|
||||||
5
|
|||||||
6
|
CALCULATION:
Calculate
the splitting tensile strength of the specimen as follows:
T =
2P/πLD
Where
T =
Splitting tensile strength
P =
Maximum applied load
L =
Length, m
D =
Diameter
CONCLUSION:
Record
the following things
- The average 7 Days Tensile Strength of
concrete sample is found to be…..…..
- The average 28 Days Tensile Strength of
concrete sample is found to be…..…..
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