A Study on Permeability

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A STUDY ON PERMEABILITY

1 General

Permeation of water and consequent corrosion is one of the main causes of damage to hydraulic concrete structures. Under hydraulic pressure, concrete will be permeated and corroded by water, resulting in damage to the hardened cement paste. Permeability is thus one of the most important properties of hydraulic concrete structures.

Found on several ways, the water is the most important fluid on nature. Among its properties, is noticeable the capacity to penetrate in small pores or cracks, and the capacity of dissolve a large amount of substances.

Several researches refer and attest the great importance of the water molecule on the concrete structure, especially on the first ages, caused by the cement hydration and consequent hardness of the concrete. However, the presence of water after the hardness of the concrete and after the reduction, or the ceasing of the hydration reactions, may cause the deterioration of the concrete or of the steel bar present on the structure. The water take action as a direct agent (lixiviation) or transporting noxious substances, such as chloride ions, sulfate ions and acid, or components that can activate and propel many chemical reactions that speed up the degradation process of the matrix, proportioning this way a substantial reduction of the durability and the use life of the concrete and reinforced concrete structures.

Some authors emphasize that the permeability of the water is the most important factor to esteem the durability under the most diverse conditions of service of a structure. Therefore concrete must be projected and manufactured for the environment to which it goes to be displayed, because the permeability is related to the porosity that varies in accordance to the composition of the concrete, its factor water cement, its age and even though with its form of launching. In this paper, will be evaluated permeability and the compressive strength of the concrete with different compositions, water cement factor and ages, making possible to generate correlation curves, suggesting a standard of reference and analysis of the permeability in function of some variable of the concrete.

2.1 Permeability of concrete

The permeability of concrete is usually expressed as the highest water pressure that the concrete can be subjected to without incurring seepage under a specified test procedure, or the height of permeating water in the concrete specimen under a given water pressure at a specified time. From observations it is found that the permeability of the concrete decreased with time, eventually reaching a stable value.

The permeability of concrete plays an important role in durability because it controls the rate of entry of moisture that may that may contain aggressive chemicals and the movement of water during heating or freezing. The w/c ratio also increases the strength which may resist the concrete from cracking and thus permeation of water is checked.

Hardened cement paste is composed of particles connected over only a small fraction of their total surface. For this reason, a part of the water is within the field of the solid phase, i.e. it is adsorbed. This water has a high viscosity but is, nevertheless, mobile and takes part in the flow.The permeability of concrete is not a simple function of its porosity, but depends also on the size, distribution, shape, tortuosity, and continuity of the pores. Thus, although the cement gel has a porosity of 28 per cent, its permeability is only about 7 x 10-16 m/s. This is due to the extremely fine texture of hardened cement paste: the pores and the solid particles are very small and numerous, whereas, in rocks, the pores, though fewer in number, are much larger and lead to a higher permeability. For the same reason, -water can flow more easily through the capillary pores than through the much smaller gel pores: the cement paste as a whole is 20 to 100 times more permeable than the gel itself. It follows that the permeability of hardened cement paste is controlled by its capillary porosity. The permeability of cement paste varies with the progress of hydration. In a fresh paste, the flow of water is controlled by the size, shape, and concentration of the original cement particles. With the progress of hydration, the permeability decreases rapidly because the gross volume of gel (including the gel pores) is approximately 2.1 times the volume of the unhydrated cement. Permeability of concrete can be classified as follows:

2.2 Necessity of permeability study

A low permeability concrete generally possesses high strength and is resistant to the ingress of water and salt solutions. The reinforcing steel in concrete structures begins to corrode earlier and corrodes faster when the surrounding concrete is porous because chloride, oxygen, and moisture can more easily reach the steel. Measuring permeability helps detect durability problems and allows timely and cost-effective protection of the concrete structure.

Concrete deterioration can be due to adverse mechanical, physical, or chemical causes, as mentioned earlier. It is often the case where one or more deteriorative mechanisms are at work by the time a problem is identified. In fact, in terms of deterioration of concrete due to physical or chemical causes, the mobility of fluids or gases through the concrete are nearly always involved. The overall susceptibility, or penetrability of a concrete structure, especially when compounded by additional environmental or exposure challenges, is the key to its ultimate serviceability and durability. Low porosity/ permeability/ penetrability of concrete to moisture and gas is the first line off defense against: frost damage, acid attack, sulfate attack, corrosion of steel embedment’s and reinforcements, carbonation, alkali-aggregate reaction, and efflorescence to name a few of the most prominent concrete ailments.

The permeability of concrete can be measured by determining the rate of flow of moisture through concrete. Since the porosity of concrete resides in the paste, the permeability of concrete should be cement aggregate interface. It should be noted that the flow of water through concrete is of interest in construction aside from consideration of durability. Impermeable concrete is required for water retaining structures and construction below grade.

Water does not easily move through the very small gel pores and that permeability is controlled by an interconnecting network of capillary pores. As hydration proceeds, the capillary network becomes increasingly tortuous as interconnected pores are blocked by formation of C-S-H. This is accompanied by a continuous decrease in permeability coefficient and the time at which complete discontinuity of capillary pores occurs is a function of the w/c ratio. In concrete with a w/c ratio greater than 0.70, complete discontinuity of capillary pores can never be achieved, even with continuous moist curing the concrete will have relatively high permeability.

If the paste are allowed to dry and then rewetted, permeability coefficient is higher. This may be due to change in pore size distribution, that occur on shrinkage and which allow capillary pores to become partially interconnected again.

The effect is more marked in concrete since cracking at the paste aggregate interface will create further opportunities for water flow. Even in saturate concrete, permeability will be increased by imperfect consolidation or excessive segregation of materials, which can create bleeding channels within the paste.

2.3 Parameters of permeability

2.3.1. Effects of mix proportions and curing conditions:

It is considered the most important factor for durability. It can be noticed that higher permeability is usually caused by higher porosity .Therefore, a proper curing, sufficient cement, proper compaction and suitable concrete cover could provide a low permeability concrete.

2.3.2. w/c ratio:

Water cement ratio is another important factor which affects the strength of concrete and thus influences its resistance to cracking from the internal stress that may be generated by adverse reactions. The value of the coefficient of permeability decreases very substantially with a decrease in the water/cement ratio over the range of water/cement ratios of 0.75 to 0.26, the coefficient decreases by up to 4 orders of magnitude, and over the range of 0.75 to 0.45, by 2 orders of magnitude(A. M. Neville, 1996).

Many aspects of concrete durability are improved by reducing the permeability of concrete. The ACI 318 Building Code addresses an exposure condition for “concrete intended to have a low permeability when exposed to water” by requiring a maximum w/cm of 0.50 and a minimum specified strength of 4000 psi. This recognizes that a lower water-cement ratio is important to control the permeability of concrete.

2.3.3. Relative paste volume:

It must be considered that one parameter of w/cm by itself does not assure the compliance with this requirement will not adversely effect other properties of concrete. Mixtures with a lower paste (water + cementitious material) content and will likely have different performance than the mixture with the higher paste volume.

2.4 Available Performance Test for Evaluating Permeability:

2.4.1 EUROPEAN STANDARD TEST:

The test performed to evaluate the permeability of concrete is based on European standard. According to the availability of the testing machine, the test standard was set. This standard specifies a method to determine the depth of penetration of water under pressure in hardened concrete which has been water cured.

This European Standard has been prepared by Technical Committee CEN/TC 104 “Concrete (performance, production, and placing and compliance criteria)”, the secretariat of which is held by DIN.

This European Standard gives the status of a national standard, either by publication of an identical text or by endorsement, at the latest by April 2001, and conflicting national standards had been withdrawn at the latest by December 2003.

According to the CEN/CENELEC Internal Regulations, the national standards organizations of the following countries are bound to implement this European Standard: Austria, Belgium, Czech Republic, Denmark, Finland, France, Germany, Greece, Iceland, Ireland, Italy, Luxembourg, Netherlands, Norway, Portugal, Spain, Sweden, Switzerland and the United Kingdom.

This standard is one of a series concerned with testing concrete. The standard has been restricted to tests on specimens cured in water requirement in the original draft ISO Standard for the average depth of penetration to be estimated has been omitted.

2.4.2 Germans Water permeability Test (GWT):

The equipment used in this tests is named Germans Water permeability Test (GWT) made by German Instruments A/S. According to the Instruction and Maintenance Manual, the GWT can be used for tasting of micro cracking and porosities of the concrete surface, the “skin-concrete”, on-site. Also, the test system is applied for testing of joints and the integrity of waterproofing membrane by performing testing before and after membrane is applied. In Figure 2.1 its the equipment GWT. (Instruction and Maintenance Manual of GWT

, 1993)

Fig 2.1: GWT machine

2.4.3 Borehole method:

A method for measuring the water permeability in a concrete structure comprising:

a) Pressure sealing a selected length of a borehole in a concrete structure

b) Injecting an aqueous medium into the selected length of borehole

c) Applying sufficient pressure to the injected aqueous medium and for a time necessary to produce a substantially steady body , measurable flow of the measurable flow of the aqueous medium into the concrete structure from the selected length of borehole

d) Measuring the steady state flow of aqueous medium , and

e) Computing from the steady state flow measurement the water permeability of the concrete structure.

f)

The apparatus employing the method is disclosed here. Fig 2.2 is schematic drawings of an embodiment of a flow measurement means in accordance with this method.

Fig 2.2: Borehole Test Method

2.5 Apparatus Used For the Performed Test:

AT 315is used to determine the impermeability of concrete to water according to EN 12390-8 “Depth of Penetration of Water under Pressure”.

Fig 2.3: European standard machine

The apparatus is to be connected to a normal air compressor capable of ensuring at least 6 bar (max. 12 bar) of compressed air continuously and equipped with dehumidifier and oil filter. Connection is then be made to the laboratory water supply and to a drainage system. Work taps/valves can be turned to two positions: open and closed. Water supply tap is used for injecting water in the circuit and Water discharge tap is used for draining water from the circuit.

There is also a Air discharge tap which is used for depressurizing circuit.

Pressure regulation of hydraulic circuit is pneumatically controlled by means of a precision valve with hand-wheel: when turned anticlockwise, pressure decreases and, vice versa, when turned clockwise pressure increases.

The pneumatic circuit is equipped with a 0-10 bar manometer to indicate pressure regulated by the Hand-wheel valve. This circuit is also equipped with a safety valve calibrated to open at approx. 6 (bar).

The three test bays are usually used simultaneously; should they need to be used individually, so as to run various tests along with others already being run, it is a good idea to fill the apparatus with the water necessary for usage of the three test bays.

The air-water interface comprises three burettes arranged in the upper part of the apparatus: relevant graduated scales enables absorption to be measured.

The burettes should not be filled completely to prevent water overflowing into the air circuit.

Figure 2.4: Arrangement of the apparatus

2.6 Performed test Procedure:

This standard specifies a method for determining the depth of penetration of water under pressure in hardened concrete which has been water cured.

Water is applied under pressure to the surface of hardened concrete. The specimen is then split and the depth of penetration of the water front is measured.

The test specimen, for example, concrete cubes, is placed in any suitable equipment in such a manner that the water pressure can act on the test area and the pressure applied can be continuously indicated. An example of a test arrangement is shown in Figure 1.2. It is preferable that the apparatus should allow the other surfaces of the test specimen to be observed. The water pressure may be applied to the surface of the test specimen either from the bottom, or the top. A necessary seal shall be made of rubber or other similar material. The dimension of a test area is approximately half of the length of the edge or diameter of the test surface. The specimen shall be cubic, cylindrical or prismatic of length of edge, or diameter, not less than 150 mm.

Figure 2.5: Arrangement of test specimen

Key

1 Packing piece

2 Sealing ring

3 Scewed on plate

4 Screw-threaded rod

5 Water under pressure

6 Screwed on plate

2.7 Aggregates used in concrete structures:

Aggregates are the important constituents in concrete either plain or reinforced. Aggregates were considered as chemically inert materials, but now it has been recognized that some of the aggregates are chemically active and also certain aggregates exhibit chemical bond at the interface of the aggregates and paste.

2.7.1 Coarse aggregates:

It is the aggregates whose particles completely pass through 20 mm B.S sieve and which are entirely retained on 4.75 mm B.S sieve.

2.7.2 Fine aggregate:

Aggregates whose sizes are 4.75mm and less is considered as fine aggregates.

2.7.3 Characteristics of coarse aggregates:

A good aggregate should not contain any deleterious material which may cause physical and chemical changes in the concrete. An aggregate should have clean, uncoated, properly shaped particles of strong, dense, durable mineral and rock materials. Some of the important characteristics of aggregate are given here,

2.7.3.1 Shape of coarse aggregates:

As-per I.S 383.-1963 shape of aggregates may be rounded, angular, elongated and flaky.

Classifications Description Examples
Rounded Fully water worn of completely round shaped by attrition River or seashore gravels; desert seashore and wind-blown sands.
Irregular or partly rounded Naturally irregular of partly round shaped by attrition having rounded edges Pit sands and gravels; land or dug flints; cuboid rock
Angular Processing well defined edges at the intersection of roughly planar faces Crushed rocks of all types.
Flaky Aggregate of which thickness is small relative to the width and/or length. Laminated rocks.
Elongated Material of which the length is considerably larger than the other two dimensions. Laminated rocks.

2.7.3.2 Surface texture:

Surface texture is a physical property, the measure of which depends upon the relative degree to which particle surfaces are polished or dull, smooth or rough. Surface texture depends on hardness, grain size, pore structure, structure of the rock and degree to which forces acting on the particle surface.

Surface texture greatly affects the bond between particles and cement paste. An aggregate with rough surface has better bond than smooth surfaced particles. Similarly an aggregate with smooth surface but having surface pores is considered good for bond.

2.7.3.3. Porosity and absorption:

Some of the aggregates are porous and absorptive. Porosity and absorption of aggregates will affect the water/cement ratio and hence the workability of concrete. The porosity of aggregate will also affect the durability of concrete when the concrete is subjected to freezing and thawing and also when the concrete is subjected to chemically aggressive liquids.

The aggregates should have smaller porosity and absorption capacity. Absorption value is used to calculate the change in the mass of an aggregate due to water absorbed in the pore space within the constituent particles compared to that at the dry condition.

2.7.3.4. Increase in volume:

Fine aggregates (sands) increase in volume due to moisture content. Coarse aggregates do not increase in volume because of moisture content. But amount of moisture in coarse aggregates should be considered while determining the amount of water required during production of concrete.

2.7.3.5. Deleterious materials:

Iron pyrites, coal, mica, shale, clay, alkali, organic impurities are some of the materials whose presence in the aggregates is viewed as harmful. These materials should not be present in such quantity that may affect the strength and durability of the concrete. Deleterious materials cause following effects.

(i) They interfere with the hydration of cement

(ii) They affect bond between cement paste and aggregates

(iii) They reduce the strength and durability of cement concrete

(iv) They modify the setting action and contribute to efflorescence

As a convention the total amount of deleterious materials in aggregates should not exceed 5%.

1st class brick:

– Standard sized

– Uniform red or yellow colored

– Well burnt

– Regular shaped

– Uniformed textured

– No efflorescence

– No pebbles , gravels or organic matter

– AC < 20% , crushing strength > 1500 psi

– Emits metallic sounds , no finger nail impression

3rd class brick:

– Soft and light red colored

– Shape , size not regular

– Under brunt (slightly over brunt is acceptable)

– Extensive efflorescence , non-uniform texture

– Ac>= 22% ,crushing strength < 1000 psi

– Emits dull / blunt sound ;

– Left finger nail scratch marks

Classification based on fineness modulus:

Fine sand FM=2.20~2.60 d< #16 sieve =1/16 in sieve

Medium sand FM=2.60~2.90 d< #8 sieve =1/8 in sieve

Coarse sand FM=2.90~3.20 d< #4 sieve =1/4 in sieve

SUPERPLASTICIZER ADMIXTURE :

The use of superplasticizers (high range water reducer) has become a quite common practice. This class of water reducers were originally developed in Japan and Germany in the early 1960s; they were introduced in the United States in the mid-1970s. The capability of superplasticizers to reduce water requirements 12-25% without affecting the workability leads to production of high-strength concrete and lower permeability.

Experimental Program

3.1 General:

The experimental setups, tests performed, and test procedure for materials used and for permeability test will be discussed in this chapter which includes

· Controlling tests of materials used

· Compressive strength test of concrete cylinders

· Method of determining permeability.

3.2 Phase 1 testing program:

Phase 1 involves the casting of 4 batch concrete with very high class brick-chips of different ratio.

3.2.1 Materials:

The following sections provide information on materials used in casting in this phase

Coarse aggregates: first class brick chips were used as coarse aggregates. And these bricks were collected from local market. Fine aggregates: local sand and Sylhet sand were used in first batch of concreting. Rest of the three batches used Sylhet sand only. Cement: The concrete used for all type of casting was made using the ordinary Portland Cement Type I/II.

Ordinary Portland cement:

It’s a product of an intimate mixture of correctly proportioned calcareous and argillaceous materials, obtained by the calcination of a very high temperature. The calcined product, called clinker, is then finely pulverized by grinding into a very fine powder. Finally its mixed with gypsum to obtain cement. When the water is mixed with cement, a series of chemical reaction takes place. As a result , the cement paste first sets and then hardens into stone like mass. Calcareous materials: Compunds of Ca and Mg ; e.g limestones , shell , dolomites etc

Argillaceous materials: Materials include of silica, alumina and iron of oxide such as clay and shale Gypsum is added to delay the setting action of the cement for some time so that it may be properly mixed , applied and finished .Without gypsum, setting action of cement starts the moment the water is added to cement , thus giving no time for mixing, placing and finishing. The setting time can be varied by suitably adjusting the percentage of gypsum. Composition of Ordinary Portland cement:

Main three ingredients are Clay, silica and lime. Besides, cements contains small amounts of iron oxide, MgO, SO3, Alkalies and other materials. Typical percentages are these constituents in a good OPC may be as follows:

Table 3.1: Chemical ingredient of Portland Cement

constituents typical % Average (%) % Mol.Wt
Al2O3(clay ) 3 – 8 5 0.07
CaO 60-70 62.2 1.1
Silica 20-25 22 0.37
MgO 1 ~ 4 1.5 0.04
Fe2O3 2~4 3 0.02
SO3 1~5 1.4
Alkalies (soda or potash) 1 1
CaSO4.2H20 3~5 4

Water: tap water was used every time.

3.2.1.1Gradation of aggregates:

This test is primarily used to determine the grading of materials proposed for use as aggregates or being used as aggregates. Gradation of aggregate means particle size distribution of the aggregates.

Grading determines the workability of the mix which controls segregation, bleeding, water cement ratio handling, placing and other characteristics of the mix. These factors also affect economy, strength, volume change and durability of hardened concrete. Coarse aggregates were prepared from bricks. Then the samples were dried and weighted. Sieves were nested in order of decreasing size of opening from the top to bottom and the samples were placed on the two sieves. Then the sieves were agitated manually for 15 minutes. The weights of each size increment were measured by balance and the results are available in the appendix section of the report.

3.2.1.2 Absorption:

Some of the aggregates are porous and absorptive. The water absorption of aggregate is determined by measuring the increase in weight of an oven dry sample when immersed in water for 24 hours. The ratio of the increase in weight to the weight of dry sample expressed as percentage in known as absorption of aggregate. Porosity and absorption of aggregate affect the water cement ratio and hence the workability of concrete. The dried aggregate samples (brick chips) were immersed in water at room temperature for period of 24 ± 4 hours. After that period, the sample was removed from water and wiped to remove the surface water. Then the sample was weighted immediately after that, the sample was dried and cooled and finally weighted again.

Calculation:

Absorption, % =

Where,

A = weight of oven dry test sample in air, g,

B = weight of saturated-surface-dry test sample in air, g

For 1st class bricks aggregates A = 3054 gm, B = 3360 gm

\Absorption= 10%

3.2.2 Mix Proportioning:

In this phase 4 batches of concrete were casted. To complete the phase, twelve cylinders of 6” diameter and twelve 6” cubes were casted. In each batch variations were introduced. The calculation of the concrete mix is as follows:

Volume of concrete = .5’x.5’x.5’ 12+ 12? x.52x1’/4 = 3.86ft3

Using the shrinkage factor 1.5,

Total volume of mix required = 5.78ft3

A total mix of 5.78 ft3 was made in accordance with following tables.

Phase 1 & Batch-1 testing program:

Cement : Sand (50% Medium sand, 50% coarse sand): Brick chips = 1:2:4, and w/c=0.50

MATERIAL Weight(kg)
Brick chips 32
Sylhet sand 8
local sand 8
cement 8
water 8

Phase 1 & Batch-2 testing program:

Cement: Sand (100% coarse sand): Brick chips = 1:2:4 and w/c = 0.50

MATERIAL Weight(kg)
Brick chips 41.15
Sylhet sand 20.57
local sand 0
cement 10.29
water 5.15

Phase 1 & Batch-3 testing program:

Cement: Sand (100% coarse sand): Brick chips = 1:1.5:3 and w/c = 0.50

MATERIAL Weight(kg)
Brick chips 39.27
Sylhet sand 19.63
local sand 0
cement 13.09
water 6.54

Phase 1 & Batch-4 testing program:

Cement: Sand (100% coarse sand): Brick chips and 1% Admixture = 1:1.5:3 and w/c = 0.40 with ad-mixture

MATERIAL Weight(kg)
Brick chips 39.27
Sylhet sand 19.63
local sand 0
cement 13.09
water 5.23

3.3 Phase 2 testing program:

Phase 1 involves the casting of 4 batch concrete with third class brick-chips of different ratio.

3.3.1 Materials:

The following sections provide information on materials used in casting in this phase Coarse aggregates: third class brick chips were used as coarse aggregates. And these bricks were collected from local market. Fine aggregates: local sand and sylhet sand were used in first batch of concreting. Rest of the three batches used sylhet sand only. Cement: The concrete used for all type of casting was made using the Portland Cement Type I/II. Water: tap water was used every time.

3.3.1.1Gradation of aggregates:

This time, the weights of each size increment were measured by balance and the results are given in the appendix section.

3.3.1.2 Absorption:

Calculation:

Absorption, % =

Where,

A = weight of oven dry test sample in air, g,

B = weight of saturated-surface-dry test sample in air, g

For 3rd class bricks aggregates A =3310 gm, B =4038 gm

\Absorption = 22%

3.3.2 Mix Proportioning:

In this phase 4 batches of concrete were casted. To complete the phase, twelve cylinders of 6” diameter and twelve 6” cubes were casted. In each batch variations were introduced. A total mix of 5.78 ft3 was made in accordance with following tables.

Phase 2 & Batch-1 testing program:

Cement: Sand (50% Medium sand, 50% coarse sand): Brick chips = 1:2:4, and w/c=0.50

MATERIAL Weight(kg)
Brick chips 41
Sylhet sand 10.28
local sand 10.28
cement 10.29
water 5.15

Phase 2 & Batch-2 testing program:

Cement: Sand (100% coarse sand): Brick chips = 1:2:4 and w/c = 0.50

MATERIAL Weight(kg)
Brick chips 41.15
Sylhet sand 20.57
local sand 0
cement 10.29
water 5.15

Phase 2 & Batch-3 testing program:

Cement: Sand (100% coarse sand): Brick chips = 1:1.5:3 and w/c = 0.50

MATERIAL Weight(kg)
Brick chips 39.29
Sylhet sand 19.63
local sand 0
cement 13.09
water 6.54

Phase 2 & Batch-4 testing program:

Cement: Sand (100% coarse sand): Brick chips and 1% Admixture = 1:1.5:3 and w/c = 0.40 with ad-mixture

MATERIAL Weight(kg)
Brick chips 39.29
Sylhet sand 19.63
local sand 0
cement 13.09
water 5.23

3.4 Phase 3 testing program:

Phase 1 involves the casting of 4 batch concrete with third class brick-chips of different ratio.

3.4.1 Materials:

The following sections provide information on materials used in casting in this phase Coarse aggregates: stone chips were used as coarse aggregates. And these bricks were collected from local market. Fine aggregates: local sand and sylhet sand were used in first batch of concreting. Rest of the three batches used sylhet sand only.

Cement: The concrete used for all type of casting was made using the Portland Cement Type I/II.

Water: tap water was used every time.

3.4.1.1Gradation of aggregates:

This time, the weights of each size increment were measured by balance and the results are given in the appendix section.

3.4.1.2 Absorption:

Calculation:

Absorption, % =

Where,

A = weight of oven dry test sample in air, g,

B = weight of saturated-surface-dry test sample in air, g

For stone chips aggregates A =3055.7 gm, B =3080.9 gm

\Absorption = 0.82%

3.4.2 Mix Proportioning:

In this phase 4 batches of concrete were casted. To complete the phase, twelve cylinders of 6” diameter and twelve 6” cubes were casted. In each batch variations were introduced.

A total mix of 5.78 ft3 was made in accordance with following tables.

Phase 3 & Batch-1 testing program:

Cement : Sand (50% Medium sand, 50% coarse sand): stone chips = 1:2:4, and w/c=0.50

MATERIAL Weight(kg)
Stone chips 41.15
Sylhet sand 10.28
local sand 10.28
cement 10.29
water 5.75

Phase 3 & Batch-2 testing program:

Cement : Sand (100% coarse sand): stone chips = 1:2:4 and w/c = 0.50

MATERIAL Weight(kg)
Stone chips 41.15
Sylhet sand 20.57
local sand 0
cement 10.29
water 5.15

Phase 3 & Batch-3 testing program:

Cement : Sand (100% coarse sand): stone chips = 1:1.5:3 and w/c = 0.50

MATERIAL Weight(kg)
Stone chips 39.27
Sylhet sand 19.63
local sand 0
cement 13.09
water 6.54

Phase 3 & Batch-4 testing program:

Cement : Sand (100% coarse sand): stone chips and 1% Admixture = 1:1.5:3 and w/c = 0.40 with ad-mixture

MATERIAL Weight(kg)
Stone chips 39.27
Sylhet sand 19.63
local sand 0
cement 13.09
water 5.23

3.5 Mixing, Placement, and Curing Procedures:

Mixture machine was used for casting of concrete. Trial mix was done for every case before the final mix. Before batching out the materials, moisture content of coarse and fine aggregates were measured, and moisture adjustment were made. The sides of the mixture machine were buttered with mortar before mixing. To ensure the quality strength in the matrix, the following format was followed for mixing concrete.

· Add coarse aggregate and some of the mixing water before starting the mixer.

· Start the mixer and add the fine aggregates, cement and any mineral admixture used. Finish by adding the remainder of mixing water.

· Mix the ingredients for 3 minutes. Then after a rest period of 30 seconds, mix the ingredients for another 2 minutes.

Fig: 3.1: Casting of concrete

After this initial mixing, the concrete was generally tested for its fresh properties. The slump of the concrete was determined by standard procedure. For batches where the slump was found unacceptable after initial mixing, the slump test was reincorporated for extra 15 to 30 seconds, and concrete was ready for placement.

Fig: 3.2: Slump test of the concrete mix design.

Concrete of the specimens had been properly compacted. Each and every cylindrical and cubic specimen was compacted by two layers. In each layer, vibrator was used for compaction. After the compaction of these specimens, scaling and hammering were done to get a void free surface of the specimens. . The compaction of the concrete clearly visualized by the fig.3.3

Fig: 3.3: Compaction procedure

Fig 3.4 : Concrete pouring in cylinders.

Curing of the specimens was completely ensured after the casting. Normal tape water was used for the curing procedure. Over saturated jute bags were used for ensuring the 100% moisture condition around the specimen. Before crashing of those specimens, all the specimens were places into the water tank for under water curing and the duration were 28 days. The total curing procedures can be easily visualized by the fig. 3.5.

Fig: 3.5: Curing of concrete

3.6 Testing procedure:

3.6.1 Compressive strength test:

The Universal Testing machine was used to do compressive strength test for al the concrete specimens. Before the test of the cylindrical specimens, capping was done over those specimens to get uniform and smooth surface for concentrated loading. Loading was 4 KN/sec applied by the Universal Testing Machine over the specimens. Crashing pattern and crack surface picture were also taken for the specimens.

Fig : 3.6: Compressive strength test

3.6.2 Determination of depth of penetration:

3.6.2.1 Preparation of the test specimen

Immediately after the specimen is de-moulded, the surface to be exposed to water pressure was roughened with a wire brush.

3.6.2.2 Application of water pressure

The test was started when the specimen is at least 28 days old. The water pressure was not applied to a trowelled surface of the specimen. The specimen was placed in the apparatus and a water pressure of (500 ± 50) kPa was applied for (72 ± 2) h. During the test, the appearance of the surfaces of the test specimen not exposed to the water pressure was observed periodically to note the presence of water.

Fig 3.7: Air Compressor

3.6.2.3 Examination of specimen

After the pressure had been applied for the specified time, the specimen was removed from the apparatus. The face on which the water pressure was applied was wiped to remove excess of water. The specimen was

Fig 3.8: Specimen on the testing machine

Fig 3.9: Water volume measuring scale

spited in half, perpendicularly to the face on which the water pressure was applied. When splitting the specimen, and during the examination, place the face of the specimen exposed to the water pressure on the bottom. As soon as the split face has dried to such an extent that the water penetration front can be clearly seen, the water front was marked on the specimen. The maximum depth of penetration under the test area was measured and recorded to the nearest millimeter.

Fig 3.10: Pressure dial

Fig 3.11: Depth of penetration

Analysis and Discussion of Test Results

4.1 General:

The following chapter presents all test results of all phases. For all phases, strength and depth of penetration data are given in tabulated form.

Water penetration test:

Water penetration into the concrete to a certain depth, and an expression has been developed by Valenta.

To convert the depth of penetration into the co-efficient of permeability, K (m/sec) equivalent to that used in Darcy’s law:

K=(e2v)/(2ht)

Where,

e= depth of penetration of concrete (m)

h=hydraulic head (m)

t=time under pressure (sec)

v=the fraction of the volume of concrete occupied by pores

The value of the v represents discrete pores ,such as air bubbles , which do not become filled with water except under pressure ,sand can be calculated from the increase in the mass of concrete during the test ,bearing in mind that only the voids in the part of the specimen penetrated by water should be considered .typically v lies between 0.02 ~ 0.06. but for brick aggregate this value could be higher. And in this stud

The hydraulic head is applied by pressure which usually ranges between 0.1 and 0.7 MPa. The depth of penetration is found by observation of the split surface of the test specimen (moist concrete being darker) after a given length of time. This is the value of e in Valenta’s expression given above.

It is also possible to use the depth of penetration of water as a qualitative assessment of concrete:

i) a depth of less than 50 mm classifies the concrete as “impermeable ”

ii) a depth of less than 30 mm classifies the concrete as “impermeable under aggressive conditions ”

4.2 Phase 1 test result:

The following section provides the test results of Phase 1 testing. The batch number, mixing proportions, w/c ratio and corresponding coefficient of permeability and strength are given in Table 4.1. Graphical representation of these test results are shown in Fig 4.1 and 4.2 accordingly.

Table 4.1: Test results from Phase 1 casting

Batch No. w/c ratio mix ratio coefficient of permeability(m/s) Strength(psi)
1 0.5 1:2:4 3.05×10-11 2750
2 0.5 1:2:4 2.94×10-11 2905
3 0.5 1:1.5:3 2.53×10-11 3512
4 0.4 1:1.5:3 2.20×10-11 4050

From the test results and graphical illustration we can see that, for the same w/c ratio of .5, permeability value of batch 1 casting is higher than that of batch 2 and 3, this could be accounted by presence of fine sand in batch 1 and rich proportion of cement in batch 3. It is also seen that for the same ingredients, use of admixture and higher percentage of cement produces more impermeable concrete.

Fig 4.1: Test result of phase 1

From Fig 4.2, we can see that for a lower strength, the permeability is high, and the permeability value is the maximum for batch 1, which could be marked by the use of 50% fine sand in concrete mixture.

Fig 4.2: Strength test result of phase 1

4.3 Phase 2 test results:

The following section provides the test results of Phase 2 testing. The batch number, mixing proportions, w/c ratio and corresponding coefficient of permeability and strength are given in Table 4.2. Graphical representation of these test results are shown in Fig 4.3 and 4.4 accordingly.

Table 4.2: Test results from Phase 2 casting

Batch No. w/c ratio mix ratio coefficient of permeability(m/s) Strength(psi)
1 0.5 1:2:4 4.86×10-11 2023
2 0.5 1:2:4 4.30×10-11 2252
3 0.5 1:1.5:3 3.85×10-11 2474
4 0.4 1:1.5:3 3.30×10-11 2675

From the test results and graphical illustration we can see that, for the same w/c ratio of .5, permeability value of batch 1 casting is higher than that of batch 2 and 3, but the values are very close. Due to poor quality of brick aggregate, use of admixture and higher percentage of cement could bring a little change in permeability of hardened concrete.

Fig 4.3: Test result of phase 2

Fig 4.4: Strength test result of phase 2

From strength test result, we can see that, decrease in strength gradually increases the permeability.

4.4 Phase 3 test results:

The following section provides the test results of Phase 3 testing. The batch number, mixing proportions, w/c ratio and corresponding coefficient of permeability and strength are given in Table 4.3. Graphical representation of these test results are shown in Fig 4.5 and 4.6 accordingly.

Batch No. w/c ratio mix ratio coefficient of permeability(m/s) Strength(psi)
1 0.5 1:2:4 2.62 x10-12 4205
2 0.5 1:2:4 2.02 x10-12 4325
3 0.5 1:1.5:3 1.04 x10-12 4823
4 0.4 1:1.5:3 9.47×10-13 6006

Table 4.3: Test results from Phase 3 casting

From the test results and graphical illustration we can see that, for the same w/c ratio of .5, permeability value of batch 1 casting is higher than that of batch 2 and 3. But a close inspection shows that the difference of permeability of batch 3 and 4 is insignificant. And the rich proportion of cement again reduces the permeability of concrete which is close to the result of using admixture.

And from the strength graph, it can be said that permeability increases with decrease in strength.

Fig 4.5: Test result of phase 3

Fig 4.6: Strength test result of phase 3

4.5 Analysis of test result:

Fig 4.7: effect of absorption on permeability

The graph plotted above was established to show the change in permeability of concrete cubes made from different aggregates for same percentage of cement. From this graph, it can be stated that, a rich proportion of cement will definitely reduce the permeability.

4.5.2 Effect of admixture on different aggregates:

Fig 4.8: Effect of admixture on permeability.

From the above figure, we can see that, use of admixture can bring about a remarkable change in permeability of concrete if it is used with good quality crushed stone chips.

4.5.3 Effect of strength on permeability:

Fig 4.8: effect of strength on permeability.

From the above figure, it could be said that, for any type of coarse aggregate used, coefficient of permeability increases for lower strength of concrete.

4.5.4 Effect of Coarse aggregate used:

From fig 4.9 we can see the effect of coarse aggregate used in concreting on the permeability of concrete. And the result shows that the good the quality of aggregate, the better impermeable the concrete is produced. The water cement ratio was maintained to 0.5 and the effect was observed.

Fig 4.9: For same w/c ratio of 0.5 change of permeability due to aggregate used.

4.5.5 Effect of w/c ratio:

From the test results, we can see that, decrease in w/c ratio reduces the permeability of concrete. And for 3rd class brick its highest and lowest for stone chips. Its also noticed that the change for stone chips aggregate is noticeable. It is shown in the following figure 4.10 and 4.11.

Fig 4.10: Effect of w/c ratio on permeability.

Fig 4.11: Effect of w/c ratio on two successive batches.

4.5.6 Effect of volume of brick in concrete:

Volume of brick in total concrete batching affects the permeability. From fig 4.12 it can be seen that increase in % of brick used for same batching condition increases the permeability of concrete.

Fig 4.12: Effect of brick % used on permeability.

Conclusion and Recommendation

5.1 General:

This study involved an experimental investigation of permeability of hardened concrete and a performance based comparison between brick aggregates and stone aggregates to prevent permeability. The test program was divided into three phases and each phase consists of four batches of concrete casting. Phase 1 involved evaluating performance of first class bricks by introducing changes in mix proportion. Similarly phase 2 testing was done by third class bricks. Finally to mark a difference between brick aggregates and crushed stone aggregates, the third phase testing was done by stone chips. This chapter highlights the conclusions that were drawn from the test results obtained and the recommendations that were developed concerning the performance of used coarse aggregates.

5.2 Conclusion:

Based upon the tests conducted, the following conclusions are at the forefronts:

1. Several tests were performed in each phases of the study. From the obtained test results, it can be said that for a certain type of aggregate, use of lower water cement ratio and higher percentage of cement can definitely reduce the permeation of water.

2. Use of admixture for workability is a good approach to reduce water penetration through concrete.

3. The higher the strength achieved, the lower the permeability is obtained.

4. Permeability of concrete is greatly affected by the absorption of aggregate used. For the same % of cement used, permeability increases for higher absorption of aggregates.

5. For same w/