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International Journal of Engineering Research and Development
e-ISSN: 2278-067X, p-ISSN: 2278-800X, www.ijerd.com
Volume 10, Issue 12 (December 2014), PP.45-51
45
An Experimental Study on Compressive Strength of Fiber
Reinforced High Strength Concrete Using Recycled Coarse
Aggregate
V.Bala Krishna1
, M.K.M.V.Ratnam2
, Dr.U.Ranga Raju3
1
PG Student, D.N.R.College of Engineering & Technology, Bhimavaram
2
Assistant Professor, D.N.R.College of Engineering & Technology, Bhimavaram
Principal, D.N.R.College of Engineering & Technology, Bhimavaram
Abstract:- The use of Recycled Concrete Aggregate (RCA) is gaining importance throughout the globe due to
the depleting sources of natural aggregate and disposal problem of demolished waste. The advancement in the
prestressed concrete technology and multistoried structures has given impetus for making concrete of high
strength. Also, it is well established that the fibers make concrete ductile. The aim of this research work is to
determine the suitability of glass fibers for use in structural recycled aggregate concrete of high strength. The
fresh and hardened state properties of partially replaced recycled aggregate concrete, with varying percentages
of glass fibers, are compared with the corresponding conventional aggregate concrete. The compressive, split
tensile and flexural strengths of M50 grade concrete with various replacement levels of coarse aggregate were
done . The maximum values of all these strengths were obtained at 1.5% of fiber content
Keywords:- High Strength Concrete, Recycled Coarse Aggregate, Glass Fiber Reinforced Concrete
I. INTRODUCTION
Recycled aggregates are comprised of crushed, graded inorganic particles processed from the materials
that have been used in the constructions and demolition debris. The aim for this on – going project is to
determine the strength characteristic of recycled aggregates for application in high strength structural concrete,
which will give a better understanding on the properties of concrete with recycled aggregates, as an alternative
material to coarse aggregate in structural concrete.Recycling is the act of processing the used material for use in
creating new product. The usage of natural aggregate is getting more and more intense with the advanced
development in infrastructure area. In order to reduce the usage of natural aggregate, recycled aggregate can be
used as the replacement materials. Recycled aggregate are comprised of crushed, graded inorganic particles
processed from the materials that have been used in the constructions and demolition debris. These materials are
generally from buildings, roads, bridges, and sometimes even from catastrophes, such as wars and earthquakes.
Due to the critical shortage of natural aggregate, the availability of demolished concrete for use as recycled
concrete aggregate (RCA) is increasing. Using the waste concrete as RCA conserves natural aggregate, reduces
the impact on landfills, decreases energy consumption and can provide cost savings. Recycled aggregates are the
materials for the future. The application of recycled aggregate has been started in many countries for
construction projects.
1.1 Applications of Recycled Aggregates
Traditionally, the application of recycled aggregate is used as landfill. Nowadays, the applications of recycled
aggregate in construction areas are wide. The applications are different from country to country.
 Concrete Kerbs
 Granular Base Course Materials
 Embankment Fill Materials
 Paving Blocks
 Backfill Materials
 Building Blocks
II. LITERATURE REVIEW
Chetna M.Vyas, Prof. Jayesh kumar Pitroda (2013) [1] have studied about the sustainability of Fly
Ash and Recycled Coarse Aggregate in Concrete. In their study Fly Ash is used as a replacement to cement and
they obtained good results when compared to conventional concrete.
An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using
46
Muthupriya et al., (2011) [2] studied the behavior of short columns produced from High Performance
Concrete (HPC). In the investigation HPC grade M60 was manufactured with usual ingredients such as cement,
fine aggregate, coarse aggregate, water and mineral admixtures such as silica fume and fly ash at various
replacement levels and the super plasticizer(1.5% by weight of cement ). The water binder ratio adopted was 0.3.
Specimens such as cubes, cylinders and prisms were casted and tested for various mixes viz., seven mixes M1 to
M7 are casted with 0%,5%, 7.5% and 10% replacement of silica fume to cement and another replacement of fly
ash to study the mechanical properties such as compressive strength, split tensile strength and flexural strength
at different ages of concrete 3,7,28,56 and 90 days. The result showed that the optimum replacement of silica
fume is at 7.5%.
Neela Deshpande et al., (2011) [3] have studied the Effectiveness of using Coarse Recycled Concrete
Aggregate in Concrete. In their study concrete mixes were designed with 28 day compressive strength as
25MPa .The concrete mixes were designed using IS 10262:2009 with conventionally used coarse aggregates
and 100% replacement of coarse recycled aggregate. With reference to the experimental results, analysis of
important properties of both the types of concrete is done and the suitability of use of recycled concrete
aggregate for new concrete is judged.
Y. V. Akbari et al., (2011) [4] have studied the effect on recycled aggregate on concrete properties.
The experimental program includes variation in water cement ratio and replacement of natural aggregates by
recycled aggregates. Three different water ratios 0.60, 0.52 and 0.43 and aggregate replacement of 0%, 15% ,
30% , 50% were accounted in experimental program. Experimental results shows up to 25% reduction in
compressive strength, 23% reduction in flexural strength, 26% reduction in split tensile strength and a noticeable
reduction in workability was observed with the increase in percentage of aggregate replacement.
Kenai and Debieb (2010) [5] examined the possibility of using crushed clay bricks as coarse and fine
aggregate for a new concrete and found out that with the percentage of recycled aggregates limited to 25% and
50% for the coarse and fine aggregates respectively produce concrete with similar characteristics to those of
natural aggregates concrete. A substitution of coarse aggregate with crushed fine clay brick up to 40% in
concrete at 28 days curing had a higher mechanical strength compared to the natural aggregate concrete . The
applications of recycled aggregate as partial replacement of coarse aggregate in the range of 20 to 40% have
been reported to be successful.
K. Jagannadha Rao and T. Ahmed Khan (2009) [6] examined the suitability of glass fibers in High
Strength Recycled Aggregate Concrete. In this study the fresh and hardened state properties of partially replaced
recycled aggregate concrete, with varying percentages of glass fibers, are compared with the corresponding
conventional aggregate concrete. The compressive, split tensile and flexural strengths of M50 grade concrete
with 0% RCA and 50% RCA have increased as the fiber content increased. The maximum values of all these
strengths were obtained at 0.03% of fiber content for both the concretes of 0% RCA and 50% RCA. Large
deflections of beams before failure indicated improved ductility with the addition of fibers.
III. EXPERIMENTAL INVESTIGATION
3.1Materials
a) Cement
In the experimental investigations ordinary Portland cement (OPC) of 53 grade is used. The cements
procured were tested for physical properties in accordance with IS: 4031-1988 and IS: 8112-1989.
b) Fine Aggregate
Fine aggregate (river sand) obtained from local market was used in this study.
c) Coarse Aggregate
The properties of coarse aggregate like size of aggregate, shape, grading, surface texture etc play an
important role in workability and strength of concrete. These properties were determined as per IS: 2386-1963.
d) Water
Potable water confirming to IS: 456-2000 was used in the investigations for both mixing and curing.
3.2 Experimental Programme
In this experimental work the concrete specimens were casted. The specimens considered in this study
consisted of 150 mm x 150 mm x 150 mm cubes. The mix design of concrete was done according to Indian
standard guidelines for target mean strength 53 N/mm2
and the water cement ratios is 0.3. The present study was
carried out on Natural coarse aggregates by replacing with Recycled Coarse Aggregate. Recycled aggregate
was procured from an old demolished building of age 60 years. Silica Fume is used as an mineral admixture.
An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using
47
The experimental work is divided into three phases. First phase consists of casting and testing of cubes with
recycled coarse aggregate content of 20%.The second phase was aimed to get an optimum recycled coarse
aggregate content and it was found to be at a replacement of 50% replacement of RCA. In the third phase of
work glass fiber was added to the above said mix and the compressive strengths were studied.
In the first phase of work the following procedure was adopted: The cement has been replaced by
silica fume accordingly in the range of 0%, 5%, 7.5% & 10 accordingly and also the recycled aggregate in the
same ratios. Concrete mixtures were produced, tested and compared in terms of compressive strengths with the
Conventional concrete. These tests were carried out to evaluate the compressive strength properties for the test
results of 7, 28 days compressive strengths In the second phase of work the recycled coarse aggregate contents
were increased upto 100% replacements and the compressive strengths were studied after 7 days and 28 days. In
the third phase of work the glass fiber is used to produce the sustainable high strength concrete by using
recycled coarse aggregate.
IV. RESULTS AND DISCUSSIONS
4.1 Test Results of compressive strength High Strength Concrete using RCA at 7 days & 28 days
S.No Mix Designation % of
Recycled
Coarse
Aggregate
Compressive
Strength
(MPa)
7 days
Compressive
Strength (MPa)
28 days
1. M50 CM 0 34.66 58.22
2. M50
5%S.F+5% RCA
5 35.55 55.11
3. M50
(5%+10%)
10 35.11 53.77
4. M50
(5%+15%)
15 34.66 53.33
5. M50
(5%+20%)
20 33.77 52.44
6. M50
(7.5%+5%)
5 37.77 54.22
7. M50
(7.5%+10%)
10 36.44 54.66
8. M50
(7.5%+15%)
15 36.88 53.77
9. M50
(7.5%+20%)
20 37.33 56.88
10. M50
(10%+5%)
5 36.44 48.94
11. M50
(10%+10%)
10 35.55 47.11
12. M50
(10%+15%)
15 34.66 45.77
13. M50
(10%+20%)
20 31.11 42.66
An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using
48
Fig.1 Graph showing variations in compressive strengths
(i) From the above table & graph it is concluded that the 7 days maximum strength is obtained at partia
replacement of silica fume at 7.5% with 5% recycled coarse aggregate and the percentage increase is 10.80%
when compared with the control mix.
(ii) It is seen that, at 28 days the compressive strengths are decreasing with the increase in mineral admixture
content and recycled aggregate content.
4.2 Test Results of compressive strength of High Strength Concrete using Recycled Coarse Aggregate
S.No Mix Designation % of Recycled
Coarse
Aggregate
Compressive
Strength (7 days)
Mpa
Compressive
Strength (28days)
Mpa
1. M50
7.5%S.F+1.5%SP
30% RCA
30 36.88 55.11
2. M50
7.5%S.F+1.5%SP
40% RCA
40 36.00 54.22
3. M50
7.5%S.F+1.5%SP
50% RCA
50 34.66 52.00
4. M50
7.5%S.F+1.5%SP
75% RCA
75 33.33 48.94
5. M50
7.5%S.F+1.5%SP
100% RCA
100 31.55 41.22
An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using
49
Fig.2 Graph showing variations in compressive strengths
4.3 Test Results of compressive strength of High Strength Concrete using Recycled Coarse Aggregate at 7 & 28
days with glass fibers
Fig.3 Graph showing variations in compressive strengths
S.No Mix Designation % of glass
fibers
Compressive
Strength (7 days)
MPa
Compressive
Strength (28
days) MPa
1. M50
7.5%S.F+1.5%SP
50% RCA
0 34.66 52.00
2. M50
7.5%S.F+1.5%SP
50% RCA
0.5% 36.88 56.00
3. M50
7.5%S.F+1.5%SP
50% RCA
1.0% 39.55 58.66
4. M50
7.5%S.F+1.5%SP
50% RCA
1.5% 41.33 60.88
5. M50
7.5%S.F+1.5%SP
50% RCA
2.0% 40.44 60.00
An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using
50
Fig.4 High Strength Concrete Mix Fig.5 Slump Cone Test
Fig.6 Curing of Cubes Fig.7 Cube failure after testing
V. CONCLUSIONS
(i) With the increase in recycled coarse aggregate content, the compressive strength is decreasing.
(ii) Of all the trial mixes, M50 (7.5% SF) with a replacement of 20% RCA has showed better results and it is
taken as reference for the next phase of work.More than 50 MPa compressive strength has been achieved by
using 50% of recycled coarse aggregate with the trail mix M50 (7.5% SF).
An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using
51
(iii) It can be concluded that usage of 50% of recycled coarse aggregate in high strength concrete yields better
economy without using glass fibers and in aspect of reducing environmental pollution & it is taken as
reference for the next phase of work.
(iv) With the addition of glass fibers it was found to be an increase in compressive strength of the high strength
concrete with recycled coarse aggregate.
(v) Of all the trial mixes with glass fibers, the mix M50(7.5% SF) and 1.5% glass fiber, showed an increase in
compressive strength and the percentage increase was found to be 11.7% when compared with the mix
without glass fiber i.e M50(7.5% SF) (50% RCA).
REFERENCES
[1]. Chetna M.Vyas, Prof. Jayeshkumar Pitroda, “Fly Ash and Recycled Coarse Aggregate in Concrete:
New Era for Construction Industries - A Literature Review”, International Journal of Engineering
Trends and Technology (IJETT) - Volume4Issue5- May 2013 .
[2]. Neela Deshpande, S. S. Kulkarni, Nikhil Patil, “Effectiveness of using Coarse Recycled Concrete
Aggregate in Concrete”, International Journal of Earth Sciences and Engineering , ISSN 0974-5904,
Volume 04, No 06 SPL, October 2011, pp 913-919.
[3]. Y. V. Akbari, N. K. Arora, M. D. Vakil, “Effect on recycled aggregate on concrete properties”,
International Journal of Earth Sciences and Engineering ISSN 0974-5904, Volume 04, No 06 SPL,
October 2011, pp. 924-928.
[4]. Kenai and Debeib” Effect of Recycled Aggregate on Normal strength concrete”, Innovative world of
structural engineering conference, September-2010.
[5]. K.Jagannadha Rao , Ahmed Khan “Suitability of Glass Fibers in High Strength Recycled Aggregate
Concrete – An Experimental Investigation”, Asian Journal of Civil Engineering, Vol.10, No.6 (2009),
pages 681-689.
[6]. K.Madan Mohan Reddy, R.Bhavani, B.Ajitha,” Use of recycled concrete aggregates in high strength
concrete” Materials and structures, Vol-33,November-2000, pp.574-580.
[7]. Limbachiya MC, Leelawat T, Dhir RK. Use of recycled concrete aggregate in highstrength concrete,
Materials and Structures, 33(2000) 574-80.
[8]. ACI 363R State-of-the-Art Report on High Strength Concrete, ACI 363R-92 (Reapproved 1997).

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An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using Recycled Coarse Aggregate

  • 1. International Journal of Engineering Research and Development e-ISSN: 2278-067X, p-ISSN: 2278-800X, www.ijerd.com Volume 10, Issue 12 (December 2014), PP.45-51 45 An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using Recycled Coarse Aggregate V.Bala Krishna1 , M.K.M.V.Ratnam2 , Dr.U.Ranga Raju3 1 PG Student, D.N.R.College of Engineering & Technology, Bhimavaram 2 Assistant Professor, D.N.R.College of Engineering & Technology, Bhimavaram Principal, D.N.R.College of Engineering & Technology, Bhimavaram Abstract:- The use of Recycled Concrete Aggregate (RCA) is gaining importance throughout the globe due to the depleting sources of natural aggregate and disposal problem of demolished waste. The advancement in the prestressed concrete technology and multistoried structures has given impetus for making concrete of high strength. Also, it is well established that the fibers make concrete ductile. The aim of this research work is to determine the suitability of glass fibers for use in structural recycled aggregate concrete of high strength. The fresh and hardened state properties of partially replaced recycled aggregate concrete, with varying percentages of glass fibers, are compared with the corresponding conventional aggregate concrete. The compressive, split tensile and flexural strengths of M50 grade concrete with various replacement levels of coarse aggregate were done . The maximum values of all these strengths were obtained at 1.5% of fiber content Keywords:- High Strength Concrete, Recycled Coarse Aggregate, Glass Fiber Reinforced Concrete I. INTRODUCTION Recycled aggregates are comprised of crushed, graded inorganic particles processed from the materials that have been used in the constructions and demolition debris. The aim for this on – going project is to determine the strength characteristic of recycled aggregates for application in high strength structural concrete, which will give a better understanding on the properties of concrete with recycled aggregates, as an alternative material to coarse aggregate in structural concrete.Recycling is the act of processing the used material for use in creating new product. The usage of natural aggregate is getting more and more intense with the advanced development in infrastructure area. In order to reduce the usage of natural aggregate, recycled aggregate can be used as the replacement materials. Recycled aggregate are comprised of crushed, graded inorganic particles processed from the materials that have been used in the constructions and demolition debris. These materials are generally from buildings, roads, bridges, and sometimes even from catastrophes, such as wars and earthquakes. Due to the critical shortage of natural aggregate, the availability of demolished concrete for use as recycled concrete aggregate (RCA) is increasing. Using the waste concrete as RCA conserves natural aggregate, reduces the impact on landfills, decreases energy consumption and can provide cost savings. Recycled aggregates are the materials for the future. The application of recycled aggregate has been started in many countries for construction projects. 1.1 Applications of Recycled Aggregates Traditionally, the application of recycled aggregate is used as landfill. Nowadays, the applications of recycled aggregate in construction areas are wide. The applications are different from country to country.  Concrete Kerbs  Granular Base Course Materials  Embankment Fill Materials  Paving Blocks  Backfill Materials  Building Blocks II. LITERATURE REVIEW Chetna M.Vyas, Prof. Jayesh kumar Pitroda (2013) [1] have studied about the sustainability of Fly Ash and Recycled Coarse Aggregate in Concrete. In their study Fly Ash is used as a replacement to cement and they obtained good results when compared to conventional concrete.
  • 2. An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using 46 Muthupriya et al., (2011) [2] studied the behavior of short columns produced from High Performance Concrete (HPC). In the investigation HPC grade M60 was manufactured with usual ingredients such as cement, fine aggregate, coarse aggregate, water and mineral admixtures such as silica fume and fly ash at various replacement levels and the super plasticizer(1.5% by weight of cement ). The water binder ratio adopted was 0.3. Specimens such as cubes, cylinders and prisms were casted and tested for various mixes viz., seven mixes M1 to M7 are casted with 0%,5%, 7.5% and 10% replacement of silica fume to cement and another replacement of fly ash to study the mechanical properties such as compressive strength, split tensile strength and flexural strength at different ages of concrete 3,7,28,56 and 90 days. The result showed that the optimum replacement of silica fume is at 7.5%. Neela Deshpande et al., (2011) [3] have studied the Effectiveness of using Coarse Recycled Concrete Aggregate in Concrete. In their study concrete mixes were designed with 28 day compressive strength as 25MPa .The concrete mixes were designed using IS 10262:2009 with conventionally used coarse aggregates and 100% replacement of coarse recycled aggregate. With reference to the experimental results, analysis of important properties of both the types of concrete is done and the suitability of use of recycled concrete aggregate for new concrete is judged. Y. V. Akbari et al., (2011) [4] have studied the effect on recycled aggregate on concrete properties. The experimental program includes variation in water cement ratio and replacement of natural aggregates by recycled aggregates. Three different water ratios 0.60, 0.52 and 0.43 and aggregate replacement of 0%, 15% , 30% , 50% were accounted in experimental program. Experimental results shows up to 25% reduction in compressive strength, 23% reduction in flexural strength, 26% reduction in split tensile strength and a noticeable reduction in workability was observed with the increase in percentage of aggregate replacement. Kenai and Debieb (2010) [5] examined the possibility of using crushed clay bricks as coarse and fine aggregate for a new concrete and found out that with the percentage of recycled aggregates limited to 25% and 50% for the coarse and fine aggregates respectively produce concrete with similar characteristics to those of natural aggregates concrete. A substitution of coarse aggregate with crushed fine clay brick up to 40% in concrete at 28 days curing had a higher mechanical strength compared to the natural aggregate concrete . The applications of recycled aggregate as partial replacement of coarse aggregate in the range of 20 to 40% have been reported to be successful. K. Jagannadha Rao and T. Ahmed Khan (2009) [6] examined the suitability of glass fibers in High Strength Recycled Aggregate Concrete. In this study the fresh and hardened state properties of partially replaced recycled aggregate concrete, with varying percentages of glass fibers, are compared with the corresponding conventional aggregate concrete. The compressive, split tensile and flexural strengths of M50 grade concrete with 0% RCA and 50% RCA have increased as the fiber content increased. The maximum values of all these strengths were obtained at 0.03% of fiber content for both the concretes of 0% RCA and 50% RCA. Large deflections of beams before failure indicated improved ductility with the addition of fibers. III. EXPERIMENTAL INVESTIGATION 3.1Materials a) Cement In the experimental investigations ordinary Portland cement (OPC) of 53 grade is used. The cements procured were tested for physical properties in accordance with IS: 4031-1988 and IS: 8112-1989. b) Fine Aggregate Fine aggregate (river sand) obtained from local market was used in this study. c) Coarse Aggregate The properties of coarse aggregate like size of aggregate, shape, grading, surface texture etc play an important role in workability and strength of concrete. These properties were determined as per IS: 2386-1963. d) Water Potable water confirming to IS: 456-2000 was used in the investigations for both mixing and curing. 3.2 Experimental Programme In this experimental work the concrete specimens were casted. The specimens considered in this study consisted of 150 mm x 150 mm x 150 mm cubes. The mix design of concrete was done according to Indian standard guidelines for target mean strength 53 N/mm2 and the water cement ratios is 0.3. The present study was carried out on Natural coarse aggregates by replacing with Recycled Coarse Aggregate. Recycled aggregate was procured from an old demolished building of age 60 years. Silica Fume is used as an mineral admixture.
  • 3. An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using 47 The experimental work is divided into three phases. First phase consists of casting and testing of cubes with recycled coarse aggregate content of 20%.The second phase was aimed to get an optimum recycled coarse aggregate content and it was found to be at a replacement of 50% replacement of RCA. In the third phase of work glass fiber was added to the above said mix and the compressive strengths were studied. In the first phase of work the following procedure was adopted: The cement has been replaced by silica fume accordingly in the range of 0%, 5%, 7.5% & 10 accordingly and also the recycled aggregate in the same ratios. Concrete mixtures were produced, tested and compared in terms of compressive strengths with the Conventional concrete. These tests were carried out to evaluate the compressive strength properties for the test results of 7, 28 days compressive strengths In the second phase of work the recycled coarse aggregate contents were increased upto 100% replacements and the compressive strengths were studied after 7 days and 28 days. In the third phase of work the glass fiber is used to produce the sustainable high strength concrete by using recycled coarse aggregate. IV. RESULTS AND DISCUSSIONS 4.1 Test Results of compressive strength High Strength Concrete using RCA at 7 days & 28 days S.No Mix Designation % of Recycled Coarse Aggregate Compressive Strength (MPa) 7 days Compressive Strength (MPa) 28 days 1. M50 CM 0 34.66 58.22 2. M50 5%S.F+5% RCA 5 35.55 55.11 3. M50 (5%+10%) 10 35.11 53.77 4. M50 (5%+15%) 15 34.66 53.33 5. M50 (5%+20%) 20 33.77 52.44 6. M50 (7.5%+5%) 5 37.77 54.22 7. M50 (7.5%+10%) 10 36.44 54.66 8. M50 (7.5%+15%) 15 36.88 53.77 9. M50 (7.5%+20%) 20 37.33 56.88 10. M50 (10%+5%) 5 36.44 48.94 11. M50 (10%+10%) 10 35.55 47.11 12. M50 (10%+15%) 15 34.66 45.77 13. M50 (10%+20%) 20 31.11 42.66
  • 4. An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using 48 Fig.1 Graph showing variations in compressive strengths (i) From the above table & graph it is concluded that the 7 days maximum strength is obtained at partia replacement of silica fume at 7.5% with 5% recycled coarse aggregate and the percentage increase is 10.80% when compared with the control mix. (ii) It is seen that, at 28 days the compressive strengths are decreasing with the increase in mineral admixture content and recycled aggregate content. 4.2 Test Results of compressive strength of High Strength Concrete using Recycled Coarse Aggregate S.No Mix Designation % of Recycled Coarse Aggregate Compressive Strength (7 days) Mpa Compressive Strength (28days) Mpa 1. M50 7.5%S.F+1.5%SP 30% RCA 30 36.88 55.11 2. M50 7.5%S.F+1.5%SP 40% RCA 40 36.00 54.22 3. M50 7.5%S.F+1.5%SP 50% RCA 50 34.66 52.00 4. M50 7.5%S.F+1.5%SP 75% RCA 75 33.33 48.94 5. M50 7.5%S.F+1.5%SP 100% RCA 100 31.55 41.22
  • 5. An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using 49 Fig.2 Graph showing variations in compressive strengths 4.3 Test Results of compressive strength of High Strength Concrete using Recycled Coarse Aggregate at 7 & 28 days with glass fibers Fig.3 Graph showing variations in compressive strengths S.No Mix Designation % of glass fibers Compressive Strength (7 days) MPa Compressive Strength (28 days) MPa 1. M50 7.5%S.F+1.5%SP 50% RCA 0 34.66 52.00 2. M50 7.5%S.F+1.5%SP 50% RCA 0.5% 36.88 56.00 3. M50 7.5%S.F+1.5%SP 50% RCA 1.0% 39.55 58.66 4. M50 7.5%S.F+1.5%SP 50% RCA 1.5% 41.33 60.88 5. M50 7.5%S.F+1.5%SP 50% RCA 2.0% 40.44 60.00
  • 6. An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using 50 Fig.4 High Strength Concrete Mix Fig.5 Slump Cone Test Fig.6 Curing of Cubes Fig.7 Cube failure after testing V. CONCLUSIONS (i) With the increase in recycled coarse aggregate content, the compressive strength is decreasing. (ii) Of all the trial mixes, M50 (7.5% SF) with a replacement of 20% RCA has showed better results and it is taken as reference for the next phase of work.More than 50 MPa compressive strength has been achieved by using 50% of recycled coarse aggregate with the trail mix M50 (7.5% SF).
  • 7. An Experimental Study on Compressive Strength of Fiber Reinforced High Strength Concrete Using 51 (iii) It can be concluded that usage of 50% of recycled coarse aggregate in high strength concrete yields better economy without using glass fibers and in aspect of reducing environmental pollution & it is taken as reference for the next phase of work. (iv) With the addition of glass fibers it was found to be an increase in compressive strength of the high strength concrete with recycled coarse aggregate. (v) Of all the trial mixes with glass fibers, the mix M50(7.5% SF) and 1.5% glass fiber, showed an increase in compressive strength and the percentage increase was found to be 11.7% when compared with the mix without glass fiber i.e M50(7.5% SF) (50% RCA). REFERENCES [1]. Chetna M.Vyas, Prof. Jayeshkumar Pitroda, “Fly Ash and Recycled Coarse Aggregate in Concrete: New Era for Construction Industries - A Literature Review”, International Journal of Engineering Trends and Technology (IJETT) - Volume4Issue5- May 2013 . [2]. Neela Deshpande, S. S. Kulkarni, Nikhil Patil, “Effectiveness of using Coarse Recycled Concrete Aggregate in Concrete”, International Journal of Earth Sciences and Engineering , ISSN 0974-5904, Volume 04, No 06 SPL, October 2011, pp 913-919. [3]. Y. V. Akbari, N. K. Arora, M. D. Vakil, “Effect on recycled aggregate on concrete properties”, International Journal of Earth Sciences and Engineering ISSN 0974-5904, Volume 04, No 06 SPL, October 2011, pp. 924-928. [4]. Kenai and Debeib” Effect of Recycled Aggregate on Normal strength concrete”, Innovative world of structural engineering conference, September-2010. [5]. K.Jagannadha Rao , Ahmed Khan “Suitability of Glass Fibers in High Strength Recycled Aggregate Concrete – An Experimental Investigation”, Asian Journal of Civil Engineering, Vol.10, No.6 (2009), pages 681-689. [6]. K.Madan Mohan Reddy, R.Bhavani, B.Ajitha,” Use of recycled concrete aggregates in high strength concrete” Materials and structures, Vol-33,November-2000, pp.574-580. [7]. Limbachiya MC, Leelawat T, Dhir RK. Use of recycled concrete aggregate in highstrength concrete, Materials and Structures, 33(2000) 574-80. [8]. ACI 363R State-of-the-Art Report on High Strength Concrete, ACI 363R-92 (Reapproved 1997).