Utilization of hair fibre and M-sand in Concrete as a Replacement of Natural Sand : A Review

Authors

  • Aditya Pranami M. Tech. Scholar, Department of Civil Engineering, Radharaman Engineering College, Bhopal, Madhya Pradesh, India Author
  • Ajeet Saxena Assistant Professor,Department of Civil Engineering, Radharaman Engineering College, Bhopal, Madhya Pradesh, India Author
  • Rahul Pandey Assistant Professor,Department of Civil Engineering, Radharaman Engineering College, Bhopal, Madhya Pradesh, India Author

Keywords:

Concrete, Fibers, Compressive Strength, Flexure Strength, Improvement, Grade, Waste

Abstract

In the current world, concrete has become a very important part of the construction industry and the materials which are used in making concrete have evolved due to better quality of cement and better grade of coarse aggregates. The sand is an important part of concrete. It is mainly procured from natural sources. Thus the grade of sand is not under our control. The concrete cubes of M-25 grade were threw in this trial explore work and tried to analyze different properties of concrete like compressive quality, workability. In this study we are reviewing literatures related to advances in concrete technologies, and utilization of fibers and materials in construction industry.              

Downloads

Download data is not yet available.

References

Huang L, Xu L, Chi Y, Xu H. Experimental investigation on the seismic performance of steel–polypropylene hybrid fber reinforced concrete columns. Construction and Building Materials. 2015;87:16-27

Bentur A. Microstructure, interfacial e?ects, and micromechanics of cementitious composites. Ceramic Transactions. 1990;16:523-550

Burati N, Mazzoti C, Savoia M. Post-cracking behaviour of steel and macro-synthetic fbre-reinforced concretes. Construction and Building Materials. 2011;25(5):2713-2722

Ramakrishnan V. Materials and Properties of Fibre Reinforced Concrete. London: Civil Engineering; 1988. pp. 29-40

ACIFC. An Introduction Guide: Steel Fibre Reinforced Concrete Industrial Ground Floors. Warwickshire: ACIFC; 1999

Brandt AM. Fibre reinforced cement-based (FRC) composites after over 40 years of development in building and civil engineering. Composite Structures. 2008;86(1-3):3-9

Di Prisco M, Plizzari G, Vandewalle L. Fibre reinforced concrete: New design perspectives. Materials and Structures. 2009;42(9):1261-1281

Aoude H, Belghiti M, Cook WD, Mitchell D. Response of steel fber-reinforced concrete beams with and without stirrups. ACI Structural Journal. 2012;109(3):359

Barros JA, Lourenço LA, Soltanzadeh F, Taheri M. Retracted article: Steel fbre reinforced concrete for elements failing in bending and in shear. European Journal of Environmental and Civil Engineering. 2014;18(1):33-65

Susetyo J, Gauvreau P, Vecchio FJ. Steel fber-reinforced concrete panels in shear: Analysis and modeling. ACI Structural Journal. 2013;110(2):285

Caggiano V, Fogassi L, Rizzolati G, Casile A, Giese MA, Thier P. Mirror neurons encode the subjective value of an observed action. Proceedings of the National Academy of Sciences. 2012;109(29):11848-11853

de Montaignac R, Massicote B, Charron JP, Nour A. Design of SFRC structural elements: Post-cracking tensile strength measurement. Materials and Structures. 2012;45(4):609-622

Safeer-ul-Hassan M, Munir M, Mujahid MY, Kisana NS, Akram Z, Nazeer AW. Genetic analysis of some biometric characters in bread wheat (Triticum aestivum L.). Journal of Biological Sciences. 2004;4(4):480-485

Ventura-Gouveia A. Constitutive models for the material nonlinear analysis of concrete structures including time dependent e?ects PhD thesis]. Department of Civil Engineering; 2011

Granju JL, Balouch SU. Corrosion of steel fbre reinforced concrete from the cracks. Cement and Concrete Research. 2005;35(3):572-577 .

Jiang Z, Banthia N. Size e?ects in ?exural toughness of fber reinforced concrete. Journal of Testing and Evaluation. 2010;38(3):332-338

Shi C, Qian J. High performance cementing materials from industrial slags—A review. Resources, Conservation and Recycling. 2000;29(3):195-207

Aiello A, Lindlein N, Marquardt C, Leuchs G. Transverse angular momentum and geometric spin Hall e?ect of light. Physical Review Leters. 2009;103(10):100401

Grae? C, Durante M, Bert C. Motion mitigation in intensity modulated particle therapy by internal target volumes covering range changes. Medical Physics. 2012;39(10):6004-6013

Neocleous K, Tlemat H, Pilakoutas K. Design issues for concrete reinforced with steel fibers, including fbers recovered from used tires. Journal of Materials in Civil Engineering. 2006;18(5):677-685

Newman J, Choo B. Advanced Concrete Technology (Processes). Oxford: Elsevier Ltd; 2003

ACI Commitee 544.1R. Fibre Reinforced Concrete. Michigan, USA: American Concrete Institute; 1996

ACI Commitee 544. State-of-art report on fbre reinforced concrete. In: ACI Manual of Concrete Practice, Part 5 – 1990. Michigan, USA: American Concrete Institute

Downloads

Published

04-03-2020

Issue

Vol. 4 No. 2 (2020): March-April

Section

Research Articles

License

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

https://creativecommons.org/licenses/by/4.0

How to Cite

Pranami, A., Saxena, A., & Pandey, R. (2020). Utilization of hair fibre and M-sand in Concrete as a Replacement of Natural Sand : A Review . International Journal of Scientific Research in Civil Engineering, 4(2), 24-31. https://ijsrce.com/index.php/home/article/view/IJSRCE20426

Similar Articles

1-10 of 167

You may also start an advanced similarity search for this article.