Study of Properties of High Strength Concrete Prepared by Replacement of Fine Aggregate with Weathered Crystalline Rock Sand & Partial Replacement of Cement with GGBS

DOI : 10.17577/IJERTV5IS090193

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Study of Properties of High Strength Concrete Prepared by Replacement of Fine Aggregate with Weathered Crystalline Rock Sand & Partial Replacement of Cement with GGBS

Roshan Sasidharan M.Tech Student ICET

Muvattupuzha,India

Ranjan Abraham Asst Professor ICET

Muvattupuzha

Abstract Concrete is a composite construction material composed of cement, fine aggregate, coarse aggregate and water. Aggregate occupy 70-75% of the total volume of concrete. Concrete is designated as high strength concrete on the basis of its compressive strength measured at a given age. Concrete mix that show 40MPa or more compressive strength at 28-days are designated as high-strength concrete. Now a days, 60-100 MPa concrete mixes are commercially developed. Unfortunately, production of cement involves emission of large amounts of carbon-dioxide gas a major contributor for green house effect and global warming. Hence it is inevitable to search either for a substitute to cement or partially replace it by some other material. Mineral admixtures such as blast furnace slag powder can be used as partial replacement to cement by 5 to 30%. From earlier days onwards river sand is used as fine aggregate. Nowadays, M-sand, pit sand etc. are also used. Since pit sand is available only at certain regions and due to the scarcity of river sand and M-sand, it has become necessary to find an alternative material, as fine aggregate. The alternative material selected here is fine aggregate from Weathered Crystalline Rock. This type of rock is abundantly available at low cost in tropical areas. This paper discusses the fresh state & mechanical properties of high strength concrete using weathered crystalline rock sand as fine aggregate.

Keywords High strength concrete, Weathered crystalline rock sand, M-Sand.

  1. INTRODUCTION

    Concrete is a widely used construction material around the world, and its properties have been undergoing changes through technological advances. So far, numerous types of Concrete have been developed. Concrete is designated as high-strengthconcrete on the basis of its compressive strength measured at a given age. Any concrete mixtures that showed 40 MPa or more compressive strength at 28-days are designed as high-strength concrete. Now a days 60-100MPa concrete mixtures are commercially developed and used in the construction of high-rise buildings and long-span bridges in many parts of the world. With natural aggregates, it is possible to make concretes up to 120MPa compressive strength by improving the strength of the cement paste, which is controlled through the choice of cement ratio and type and dosage of admixtures. These developments have led to increased applications of high-strength concrete (HSC) all

    around the globe. HSC offers many advantages over conventional concrete. The high compressive strength can be advantageously used in compression members like columns and piles. Higher compressive strength of concrete results reduction in column size and increases available floor space. HSC can also be effectively used in structures such as domes, folded plates, shells and arches where large in-plane compressive stresses exist. The inherent techniques of producing HSC generate a dense microstructure making ingress of deleterious chemicals from the environment into the concrete core difficult, thus enhancing the long-term durability and performance of the structure. Ordinary Portland Cement (OPC) is one of the main ingredients used for the production of concrete. Unfortunately, production of cement involves emission of large amounts of carbon-dioxide gas a major contributor for green house effect and global warming into the atmosphere. Hence it is inevitable to search either for another material or partially replace it by some other material. The search for any such material which can be used as an alternative for cement, should lead to global sustainable development and lowest possible environmental impact. Mineral admixtures such as blast furnace slag powder can be used as partial replacement of cement by 5 to 30%. Compressive strength of blast furnace slag concrete with different dosage of slag was studied as a partial replacement of cement. From the experimental investigations, it has been observed that, the optimum replacement of Ground Granulated Blast Furnace Slag Powder to cement without much change in compressive strength is 15%.

    In the present scenario, scarcity of river sand and increasing cost of M- sand are the major issues in the construction field. Hence an alternative construction material which can fully or partially replace the fine aggregate without affecting the property of High strength concrete would be advantageous. Nowadays, M-sand, & pit sand. are also used as fine aggregate. Since pit sand is available only at certain regions and due to the scarcity of river sand and M-sand, it has become necessary to find an alternative material, as fine aggregate. The alternative material selected here is sand from Weathered Crystalline Rock. And this type of rock is abundantly available at low cost in tropical areas. This paper discusses the use of Weathered Crystalline Sand as fine

    aggregate in concrete. Comparison of properties like fineness, specific gravity, bulking of sand, bulk density, compressive strength of mortar cubes and compressive strength of concrete cubes using different fine aggregates is also conducted.

    1. High Strength Concrete

      Concrete, a composite consisting of aggregates enclosed in a matrix of cement paste including possible pozzolans, has two major components cement paste and aggregates. The strength of concrete depends upon the strength of these components, their deformation properties, and the adhesion between the paste and aggregate surface (Berntsson et al., 1990). With most natural aggregates, it is possible to make concretes up to 120 MPa compressive strength by improving the strength of the cement paste, which can be controlled through the choice of water-content ratio and type and dosage of admixtures (Mehta and Aitcin, 1990). However, with the recent advancement in concrete technology and the availability of various types of mineral and chemical admixtures, and special superplasticizer, concrete with a compressive strength of up to 100 MPa can now be produced commercially with an acceptable level of variability using ordinary When the general performance of concrete is substantially higher than that of normal type concrete, such

      used as a pozzolanic material. However, if slag is slowly air cooled then it is hydraulically inert and such crystallized slag cannot be used as pozzolanic material. Though the use of GGBS in the form of Portland slag cement is not uncommon in India, experience of using GGBS as partial replacement of cement in concrete in India is scanty. GGBS essentially consists of silicates and alumina silicates of calcium and other bases that are developed in a molten condition simultaneously with iron in a blast furnace. The chemical composition of oxides in GGBS is similar to that of Portland cement but the proportion varies. This paper deals with the use of the blast furnace slag powder as a partial replacement of OPC and its effect on strength of cement concrete mix

      Fig.1 Granulated blast furnace slag

      concrete is regarded as high performance concrete (HPC).C. Weathered Crystalline Rock

      Three of the key attributes to HPC are discussed. They are: strength, ductility and durability. In order to know the intrinsic differences between normal type concrete and high performance concrete, micro-structure and composition of HPC are studied. Stress strain behvior of HPC under biaxial and triaxial loading are described. Finally, the application of HPC in tall building construction is discussed. A general overview of the development of HPC, covering the topic from the laboratory testing to the industrial application.

    2. Granulated Blast Furnace Slag

    Blast furnace slag is a solid waste discharged in large quantities by the iron and steel industry in India. The re- cycling of these slags will become an important measure for the environmental protection. Iron and steel are basic materials that underpin modern civilization, and due to many years of research the slag that is generated as a by-product in iron and steel production is now in use as a material in its own right in various sectors. Slag enjoys stable quality and proper- ties that are difficult to obtain from natural materials and in the 21st century is gaining increasing attention as an environ- mentally friendly material from the perspectives of resource saving, energy conservation and CO2 reduction. The primary constituents of slag are lime (CaO) and silica (SiO2). Portland cement also contains these constituents. The primary constituent of slag is soluble in water and exhibits an alkalinity like that of cement or concrete. And as it is removed at high temperatures of 1,200°C and greater, it contains no organic matter whatsoever. Ground Granulated Blast furnace slag (GGBS) is a by-product for manufacture of pig iron and obtained through rapid cooling by water or quenching molten slag. Here the molten slag is produced which is instantaneously tapped and quenched by water. This rapid quenching of molten slag facilitates formation of Granulated slag. Ground Granulated Blast furnace Slag (GGBS) is processed from Granulated slag. If slag is properly processed then it develops hydraulic property and it can effectively be

    Weathered Crystalline Rocks are metamorphic rocks seen in the tropical areas like Kerala. They are formed by the weathering action on the rocks. Weathered crystalline rock is the outer layer of the underlying hard rock. Hence excessive mining is not required to obtain these types of rocks. In Kerala, weathered crystalline rock is used for the construction of small compound walls instead of random rubble and Laterite bricks. Generally, weathered crystalline rock sand is used for plastering works. Chemical combination of the weathered crystalline rock is almost similar to the chemical combination of naturally occurring rocks. Silica is the major constituent in natural sand and weathered crystalline rock. Other constituents like oxides of Manganese, Magnesium, Iron, Aluminium etc. are in the safe limits. Other trace elements are in the range of ppm those are not at all affects the chemical activity of fine aggregate. From earlier days onwards river sand is used as fine aggregate. Nowadays, M-sand, pit sand etc. are also used. Since pit sand is available only at certain regions and due to the scarcity of river sand and M- sand, it has become necessary to find an alternative material, as fine aggregate. The alternative material selected here is sand from Weathered Crystalline Rock. And this type of rock is abundantly available at low cost in tropical areas. This paper discusses the use of Weathered Crystalline Sand as fine aggregate in concrete. A comparison of properties like fineness, specific gravity, bulking of sand, bulk density, compressive strength of mortar cubes and compressive strength of concrete cubes using different fine aggregates is also conducted.

    Fig.2 Weathered Crystalline Rock Sand

  2. METHODOLOGY

    The methodology adopted for the present experimental investigation is as follows:

    1. Literature Review

    2. Selection Of Materials

      • Cement(Ordinary Portland Cement), Blast Furnace Slag, Coarse Aggregate, Weathered crystalline Rock Sand as fine aggregate, Super Plasticizer.

    3. Determination of Material Properties

      • Cement:-Specific gravity, initial setting time, final setting time, standard consistency

      • Blast furnace slag:- Physical and chemical properties, specific gravity

      • Fine aggregate:- Specific Gravity, water absorption, sieve analysis, bulk density and percentage of voids

      • Coarse Aggregate:-Specific gravity, water absorption, sieve analysis, aggregate crushing value

      • Water

      • Super Plasticizer

    4. Preparation Of Specimen

      • Preparation of M40 Mix

      • Preparation of mix with coarse aggregate and fine aggregate as weathered crystalline rock sand and find the optimum percentage of coarse and fine aggregate for M40 mix.

      • Preparation of concrete with optimum percentage of coarse and fine aggregate with partial replacement of cement with blast furnace slag(40%,50%,60%)

      • Cube of size 150×150×150mm, Beam of size100×100×500mm, and cylinder of size300×150mm are casted to conduct test for compressive strength, flexural strength, splitting tensile strength of mixes. Age for compressive strength is 3,7,and 28 days and for flexural and splitting tensile strength 7 and 28 days

    5. Laboratory Tests

      • Study on fresh state properties by conducting slump and compaction factor test.

      • Study of hardened state properties by conducting tests for Compressive strength, splitting tensile strength, flexure strength, water absorption.

  3. MATERIAL CHARACTERIZATION

  1. Cement

    OPC 53 grade concrete was used in this study

    TABLE.1 PROPERTIES OF CEMENT

    Test

    Values

    Standard Consistency

    35%

    Initial Setting Time

    240 min

    Specific Gravity

    3.125

    Fineness

    5%

  2. Fine Aggregate

    M-Sand was used for the study

    TABLE.2 PROPERTIES OF FINE AGGREGATE

    Test Conducted

    Values Obtained

    Specific Gravity

    2.69

    Fineness

    2.59%

    Water Absorption

    1.5%

    Bulk Density

    1.13 kg/l

    Percentage voids

    54.44%

    Water Content

    2.2%

  3. Coarse Aggregate

    Coarse aggregate conforms to table 2 of IS 383-1970

    TABLE.3 PROPERTIES OF FINE AGGREGATE

    Test

    Values

    Specific Gravity

    2.67

    Fineness

    7.45%

    Water Absorption

    0.8%

    Bulk Density

    1.25 kg/l

    Percentage Voids

    50.41%

    Aggregate Crushing Value

    28.66%

  4. WEATHERED CRYSTALLINE ROCK SAND

TABLE.4 PROPERTIES OF WEATHERED CRYSTALLINE ROCK SAND

  1. TEST FOR HARDENED STATE PROPERTIES

    A. CONTROL MIX

    Test

    Values

    Specific Gravity

    2.65

    Fineness

    2.75%

    Water Absorption

    3%

    1. GROUND GRANULATED BLAST FURNACE SLAG

      Propety

      Value

      Specific gravity

      2.93

      Fineness

      3.89%

      Particle size

      97.10 microns

      Propety

      Value

      Specific gravity

      2.93

      Fineness

      3.89%

      Particle size

      97.10 microns

      TABLE.5 PROPERTIES OF GROUND GRANULATED BLAST FURNACE SLAG

      TABLE.9 CONTROL MIX

      Test

      3 Days (N/mm2)

      7 Days (N/mm2)

      28 Days (N/mm2)

      Compressive Strength

      28.89

      40.00

      50.37

      Splitting Tensile Strength

      2.26

      2.74

      Flexural Strength

      7.29

      9.56

    2. SUPER PLASTICIZER

    TABLE.6 PROPERTIES OF SUPER PLASTICIZER

    Property

    Value

    Aspect

    Light brown liquid

    Relative Density

    1.08 ± 0.01 at 25°C

    pH

    > 6

    Chloride ion content

    < 0.2%

    1. MIX DESIGN

      60

      Strength (N/mm )

      Strength (N/mm )

      50

      40

      30

      20

      10

      0

      3

      Strength (N/mm )

      Strength (N/mm )

      2.5

      0 10 20 30

      Curing periods(days)

      Fig. 3 Compressive Strength

      1. CONTROL MIX

        Mix Proportion

        Cement

        414.74 kg/m³

        Water

        157.60 kg/m³

        Super Plasticizer

        1.24 kg/m³

        Fine Aggregate

        801.23 kg/m³

        Coarse Aggregate

        1096.50 kg/m³

        Mix Proportion

        Cement

        414.74 kg/m³

        Water

        157.60 kg/m³

        Super Plasticizer

        1.24 kg/m³

        Fine Aggregate

        801.23 kg/m³

        Coarse Aggregate

        1096.50 kg/m³

        TABLE.7 CONTROL MIX

        2

        1.5

        1

        0.5

        0

        0 10 20 30

        Curing period (days)

    2. TEST FOR FRESH STATE PROPERTIES

TABLE.8 FRESH PROPERTIES OF CONCRETE

Fig.4 Splitting Tensile Strength

Test

Control Mix

Wcrs Mix

GGBS Mix

40%

50%

60%

Slump

100mm

120m

m

110mm

110m

m

110m

m

Compacti on Factor

0.91

0.89

0.90

0.90

0.90

3.3

3.2

3.1

3

2.9

2.8

2.7

3.3

3.2

3.1

3

2.9

2.8

2.7

Strength (N/mm²)

Strength (N/mm²)

10

Strength (N/mm

Strength (N/mm

)

)

8

6

4

Curing periods(days)

Curing periods(days)

2

0

10

20

30

0

10

20

30

0

0 C10

g periods( 20 ) 30

  1. WCRS MIX

    urin

    Fig.5 Flexural Strength

    TABLE.10 RESULTS

    days

    Fig. 7 Splitting Strength

    Test 3 Days

    (N/mm2)

    7 Days (N/mm2)

    12

    10

    8

    6

    4

    2

    0

    12

    10

    8

    6

    4

    2

    0

    Strength(N/mm²)

    Strength(N/mm²)

    28 Days (N/mm2)

    Compressive

    Strength 32.44 35.85 53.33

    Splitting Tensile Strength

    Flexural

    — 2.773 3.268

    0

    5

    10

    15

    Curing Days

    20

    25

    30

    0

    5

    10

    15

    Curing Days

    20

    25

    30

    60

    50

    40

    30

    20

    10

    0

    60

    50

    40

    30

    20

    10

    0

    (N/mm²)

    (N/mm²)

    Strength — 7.456 9.677

    0

    10

    20

    30

    0

    10

    20

    30

    Curing period(days)

    Curing period(days)

    Stremgth

    Stremgth

    Fig. 6 Compressive Strength

    Fig.8 Flexural Strength

    Strength(N/mm²)

    Strength(N/mm²)

  2. COMPARISON OF CONTROL MIX & WCRS MIX

    60

    50

    40

    30

    20

    10

    0

    3

    days 7

    days

    28

    days

    60

    50

    40

    30

    20

    10

    0

    3

    days 7

    days

    28

    days

    CM WCRS MIX

    CM WCRS MIX

    Fig. 9 Compressive Strength

    3.5

    3

    2.5

    2

    1.5

    1

    0.5

    0

    3.5

    3

    2.5

    2

    1.5

    1

    0.5

    0

    7

    days 28

    days

    7

    days 28

    days

    CM WCRS MIX

    CM WCRS MIX

    60

    50

    40

    30

    20

    10

    0

    60

    50

    40

    30

    20

    10

    0

    40%GGBS

    40%GGBS

    50%GGBS

    60%GGBS

    0

    50%GGBS

    60%GGBS

    0

    10

    10

    20

    20

    30

    30

    Strength (N/mm²)

    Strength (N/mm²)

    Strength (N/mm²)

    Strength (N/mm²)

    Strength (N/mm²)

    Strength (N/mm²)

    Fig. 10 Splitting Strength

    3.5

    3

    2.5

    2

    1.5

    1

    0.5

    0

    7

    days 28

    days

    3.5

    3

    2.5

    2

    1.5

    1

    0.5

    0

    7

    days 28

    days

    CM WCRS MIX

    CM WCRS MIX

    Fig.11 Flexural Strength

  3. WCRS mix with cement partially replaced with GGBS

    Test

    Curing Period

    GGBS Added In Percentage

    40%

    50%

    60%

    COMPRESSIVE STRENGTH

    3 days

    10.67N/mm2

    11.65N/mm2

    10.88N/

    mm2

    7 days

    27N/mm2

    29.25N/mm2

    27.29N/

    mm2

    28 days

    42N/mm2

    48.60N/mm2

    40.29N/

    mm2

    SPLITTING TENSILE STRENGTH

    7 days

    1.88N/mm2

    2.44N/mm2

    1.60N/m

    m2

    28 days

    2.85N/mm2

    3.28N/mm2

    3.01N/m

    m2

    FLEXURAL STRENGTH

    7 days

    4.08N/mm2

    5.33N/mm2

    4.69N/m

    m2

    28 days

    4.55N/mm2

    6.83N/mm2

    5.38N/m

    m2

    Test

    Curing Period

    GGBS Added In Percentage

    40%

    50%

    60%

    COMPRESSIVE STRENGTH

    3 days

    10.67N/mm2

    11.65N/mm2

    10.88N/

    mm2

    7 days

    27N/mm2

    29.25N/mm2

    27.29N/

    mm2

    28 days

    42N/mm2

    48.60N/mm2

    40.29N/

    mm2

    SPLITTING TENSILE STRENGTH

    7 days

    1.88N/mm2

    2.44N/mm2

    1.60N/m

    m2

    28 days

    2.85N/mm2

    3.28N/mm2

    3.01N/m

    m2

    FLEXURAL STRENGTH

    7 days

    4.08N/mm2

    5.33N/mm2

    4.69N/m

    m2

    28 days

    4.55N/mm2

    6.83N/mm2

    5.38N/m

    m2

    TABLE.11 RESULTS

    Curing period(days)

    Curing period(days)

    3.5

    3

    2.5

    2

    1.5

    1

    0.5

    0

    3.5

    3

    2.5

    2

    1.5

    1

    0.5

    0

    40%GGBS

    40%GGBS

    50%GGBS

    60%GGBS

    0

    50%GGBS

    60%GGBS

    0

    Strength (N/mm²)

    Strength (N/mm²)

    Fig. 12 Compressive Strength

    Curing period(days)

    Curing period(days)

    10

    10

    20

    20

    30

    30

    8

    7

    6

    5

    4

    3

    2

    1

    0

    8

    7

    6

    5

    4

    3

    2

    1

    0

    40%GGBS

    40%GGBS

    50%GGBS

    60%GGBS

    0

    50%GGBS

    60%GGBS

    0

    Strength (N/mm²)

    Strength (N/mm²)

    Fig. 13 Splitting Strength

    Curing period(days)

    Curing period(days)

    10

    10

    20

    20

    30

    30

    Fig.14 Flexural Strength

  4. Control mix with cement partially replaced with GGBS

    Test

    Curing Period

    GGBS Added In Percentage

    40%

    50%

    60%

    COMPR ESSIVE STRENG TH

    3 days

    2

    15.05N/mm

    2

    16.09N/mm

    2

    15.38N/mm

    7 days

    2

    37.81N/mm

    2

    40.00N/mm

    2

    37.85N/mm

    28 days

    2

    50.21N/mm

    2

    53.33N/mm

    2

    51.40N/mm

    SPLITTING TENSILE STRENGTH

    7 days

    2

    2.42N/mm

    2

    2.85N/mm

    2

    2.66N/mm

    28 days

    2

    3.19N/mm

    2

    3.90N/mm

    2

    3.57N/mm

    FLEXURAL STRENGTH

    7 days

    2

    5.02N/mm

    2

    5.85N/mm

    2

    5.33N/mm

    28 days

    2

    6.83N/mm

    2

    7.75N/mm

    2

    7.00N/mm

    Test

    Curing Period

    GGBS Added In Percentage

    40%

    50%

    60%

    COMPR ESSIVE STRENG TH

    3 days

    2

    15.05N/mm

    2

    16.09N/mm

    2

    15.38N/mm

    7 days

    2

    37.81N/mm

    2

    40.00N/mm

    2

    37.85N/mm

    28 days

    2

    50.21N/mm

    2

    53.33N/mm

    2

    51.40N/mm

    SPLITTING TENSILE STRENGTH

    7 days

    2

    2.42N/mm

    2

    2.85N/mm

    2

    2.66N/mm

    28 days

    2

    3.19N/mm

    2

    3.90N/mm

    2

    3.57N/mm

    FLEXURAL STRENGTH

    7 days

    2

    5.02N/mm

    2

    5.85N/mm

    2

    5.33N/mm

    28 days

    2

    6.83N/mm

    2

    7.75N/mm

    2

    7.00N/mm

    TABLE.12 MIX PROPORTION

    9

    8

    7

    6

    5

    4

    3

    2

    1

    0

    40%GGBS

    50%GGBS

    60%GGBS

    9

    8

    7

    6

    5

    4

    3

    2

    1

    0

    40%GGBS

    50%GGBS

    60%GGBS

    0 10 20 30

    Curing period(days)

    0 10 20 30

    Curing period(days)

    Strength (N/mm²)

    Strength (N/mm²)

    Fig.17 Flexural Strength

    60

    50

    40

    30

    20

    10

    0

    60

    50

    40

    30

    20

    10

    0

    Strength (N/mm²)

    Strength (N/mm²)

    Strength (N/mm²)

    Strength (N/mm²)

  5. COMPARISON OF TWO MIXES WCRS MIX AND MSAND MIX WITH CEMENT REPLACED WITH GGBS

60

50

40

30

20

40%GGBS

50%GGBS

60%GGBS

3

days 7

days

28

days

60

50

40

30

20

40%GGBS

50%GGBS

60%GGBS

3

days 7

days

28

days

0

10

20

30

0

10

20

30

Curing period(days)

Curing period(days)

10

0

10

0

Strength (N/mm²)

Strength (N/mm²)

Fig. 15 Compressive Strength

4.5

4

3.5

3

2.5

2

1.5

1

0.5

0

40%G

GBS

50%G GBS

4.5

4

3.5

3

2.5

2

1.5

1

0.5

0

40%G

GBS

50%G GBS

0 10 20 30

Curing period(days)

0 10 20 30

Curing period(days)

Fig. 16 Splitting Strength

4.5

4

Strength (N/mm²)

Strength (N/mm²)

3.5

3

2.5

2

1.5

1

0.5

0

Fig. 18 Compressive Strength

Fig. 19 Splitting Strength

7

days

28

days

12

10

8

6

4

2

0

7 days

28 days

12

10

8

6

4

2

0

7 days

28 days

Strength (N/mm²)

Strength (N/mm²)

Fig.20 Flexural Strength

VII. CONCLUSIONS

  • On comparison of control mix with WCRS mix, WCRS mix showed much higher strength than the target strength of control mix by about 10.53%.

  • On comparing the two mix, those replaced with fine aggregate as Msand and 50%GGBS attained higher target strength of control mix by about 10.52%.

  • Mix with cement partially replaced with 50% GGBS and WCRS as fine aggregate to an extent attained higher target strength of control mix by about 0.73%.

  • Use of M40 mix in which cement is replaced with 50% GGBS can reduce the consumption, thus reducing production of cement and emission of carbon dioxide to atmosphere.

  • WCRS can be used as an alternative to fine aggregate, thus reducing the consumption of river sand and Msand.

REFERENCES

  1. Yogendra O.Patil Prof Pn Pattil Ggbs As Partial Replacement Of Opc In Cement Concrete An Experimental Study International Journal Of Scientific Volume : 2 | Issue : 11 | November 2013.

  2. Atul Dubey, Dr. R. Chandak, Prof. R.K.Yadav Effect of blast furnace slag powder on compressive strength of concrete International Journal of Scientific & Engineering Research Volume 3, Issue 8, August-2013.

  3. Chander Garg, Ankush Khadwal Behavior of Ground Granulated Blast Furnace Slag and Limestone Powder as Partial Cement Replacement International Journal of Engineering and Advanced Technology (IJEAT) ISSN: 2249 8958, Volume-3 Issue-6, August 2013

  4. Eldhose M Mathew, Shaji M Jamal, Ranjan Abraham Weathered Crystalline Rock: Suitability As Fine Aggregate In Concrete A Comparative Study International Journal of Innovative Research in Science, Engineering and Technology Vol. 2, Issue 4, April 2013

  5. T. Vijaya Gowri, P. Sravana, P. Srinivasa Rao Studies On Strength Behavior Of High Volumes Of Slag Concrete International Journal of Research in Engineering and Technology Volume: 03 | Apr-2014.

  6. Sonali K. Gadpalliwar, R. S. Deotale, Abhijeet R. Narde To Study the Partial Replacement of Cement by GGBS & RHA and Natural Sand by Quarry Sand In Concrete IOSR Journal of Mechanical and Civil Engineering Volume 11, Issue 2 Ver. II (Mar- Apr. 2014.

  7. A.Annadurai, A. Ravichandran Development of mix design for high strength Concrete with Admixtures IOSR Journal of Mechanical and Civil Engineering (IOSR-JMCE) e-ISSN: 2278-1684,p-ISSN: 2320- 334X, Volume 10, Issue 5 (Jan. 2014).

  8. S. Arivalagan Sustainable Studies on Concrete with GGBS As a Replacement Material in Cement Jordan Journal of Civil Engineering, Volume 8, No. 3, 2014.

  9. Vinayak Awasare, Prof. M. V. Nagendra Analysis Of Strength Characteristics Of Ggbs Concrete International Journal of Advanced Engineering Technology Vol. V/Issue II/April-June,2014.

  10. Eldhose M Manjummekudy, Anju K Govind, Shibi Varghese Comparative Study on the Effect of Concrete using Eco Sand, Weathered Crystalline Rock Sand and GBS as fine Aggregate Replacement International Journal of Engineering Research & Technology (IJERT)Vol. 3 Issue 10, October- 2014

  11. Jyothis Mary C.J , Ranjan Abraham Study of Fresh State Properties & Durability of Self Compacting Concrete with Weathered Crystalline Rock Sand as Fine Aggregate International Journal of Engineering Trends and Technology (IJETT) Volume 28 Number 8 -October 2015.

  12. Anusha Suvarna, Prof .P.J. Salunke, Prof. N.G.Gore,Prof. T.N.Narkehde Silica Fume & Ground Granulated Blast Furnace Slag as Cement Replacement in Fiber Reinforced Concrete International Research Journal of Engineering and Technology (IRJET) Volume: 02 Oct-2015.

  13. S.Murali Krishnan, Dr.T.Felix Kala Dr.T.Felix Kala Investigation on Durability Properties of Concrete Using Manufactured Sand and Admixtures International Journal of Mechanical Civil and Control Engineering Vol.1, Issue.4, September 2015.

  14. Sharandeep Singh, Dr.Hemant Sood Evaluation of M35 and M40 grades of concrete by ACI, DOE, USBR and BIS methods of mix design International Research Journal of Engineering and Technology (IRJET) Volume: 02 Issue: 06 | Sep-2015.

  15. M.Pavan Kumar,Y.Mahesh The Behaviour of Concrete by Partial Replacement of Fine Aggregate with Copper Slag and Cement with GGBS – An Experimental Study IOSR Journal of Mechanical and Civil Engineering (IOSR-JMCE) Volume 12, Issue 3 (May. – Jun. 2015).

  16. P.Vignesh, K.Vivek An Experimental Investigation On Strength

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