Investigative Analysis on The Properties of Concrete Replacing Fine Aggregate with Bottom ASH and Quarry Dust

Authors

  • D. R. Sasirekha  M. Tech Student, Civil Engineering, PVKK Institute of Technology, Anantapur, Andhra Pradesh, India
  • S. Thejaswini  Assistant Professor, M. Tech, Department of Civil Engineering, PVKK Institute of Technology, Anantapur, Andhra Pradesh, India

DOI:

https://doi.org//10.32628/IJSRST19619

Keywords:

Raspberry pi, USB camera, motor driver, motor, LCD display, road side speed sign controlling.

Abstract

In present condition to full-fill the demand of sustainable construction, concrete made with different materials is the best choice for the construction industry. Generally, we use materials which are required for conventional concrete and addition to those we replace the low-cost materials such as bottom ash in this project we replace the coal bottom ash & quarry dust to the fine aggregate by variable percentages. Coal bottom ash is the by-product of coal combustion. The rock detritus filled in the fishers of coal become separator from the coal during pulverization. In the furnace, carbon, other combustible matter burns, & the non-combustible matter result in coal ash. The coal ash collector from the electro static precipitators is called fly ash. coal bottom ash constitutes about 20% of coal ash and the result is fly ash. The perfect substitute for reverse sand is quarry dust it is the one of the ingredients in manufacture of concrete the crusher dust is known as quarry dust can be used as alternative material to the river sand. quarry dust possesses similar properties as that of river sand, hence accepted as a building material. The aggregate replaced with concrete in various percentages as both BA and QD (10%,20%&30%). All replacements where done to the m30 grade of concrete. the concrete has been replaced by coal bottom ash accordingly to the percentage, and fine aggregate has been replaced by quarry dust in percentage. concrete mixtures where produced, tested & compared in terms of compressive strength, tensile, flexural strength are evaluated. The curing of cubes, cylinders, & beams is 7days 28days & 90days.

References

  1. Abdelaty, M. a. a., (2014). “Compressive strength prediction of Portland cement concrete with age using a new model.” Housing and Building National Research Center(HBRC) Journal; 10: 145-155
  2. Aggarwal P., Aggarwal Y. and Gupta S.M. (2007), “Effect of bottom ash as replacement offine aggregates in concrete.” Asian Journal of Civil Engineering (Building andHousing); 8: 49-62
  3. Al-Amoudi, O.S.B., Al-Kutti, W. A., Ahmad, S. and Maslehuddin, M., (2009).“Correlation between compressive strength and certain durability indices of plain andblended cement concretes” Cement & Concrete Composites; 31: 672–676
  4. American Coal Ash Association (ACAA). 2006 coal combustion product (CCP)production and use. Aurora, CO: American Coal Ash Association; 2007.
  5. Andrade L.B., RockaJ.C.andCheriaf M. (2007), “Aspects of moisture kinetics of coalbottom ash in concrete." Cement and Concrete Research; 37: 231-241
  6. Behim M., Cyr M., and Clastres P., (2011), “Physical and chemical effects of El Hadjarslag used as an additive in cement-based materials.” European Journal ofEnvironmental and Civil Engineering; 15(10): 1413-32
  7. Brown PW. (1981), “An evaluation of the sulphate resistance of cements in a controlledenvironment.” Cement and Concrete Research; 11:719–27.239
  8. Cachim P., Velosa AL, and Ferraz E. (2014), “Substitution Materials for sustainableconcrete production in Portugal.” KSCE Journal of Civil Engineering; 18(1): 60-66
  9. Cachim, P. B. (2009), “Mechanical properties of brick aggregate concrete.” Constructionand Building Materials; 23 (3): 1292-1297.
  10. CharkradharaRao M., Bhattacharyya S. K. and Barai S. V. (2011), “Behaviour ofrecycled aggregate concrete under drop weight impact load.” Construction andBuilding Material; 25(1): 69-80
  11. Cheriaf M., Rocka J.C. and Pera J. (1999), “Pozzolanic properties of pulverized coalcombustion bottom ash.” Cement and Concrete Research, 29:1387-1391
  12. Chun L.B., Sung K. J., Sang K. T. and Chae S.T. (2008), “A study on the fundamentalproperties of concrete incorporating pond-ash in Korea.” The 3rd ACF InternationalConference-ACF/VCA, 401-408
  13. Cwrizen A., Penttala V. and Vornanen C. (2008), “Reactive powder based concretes:Mechanical properties, durability and hybrid use with OPC.” Cement and concreteResearch; 38:1217-26
  14. Cyr M., Aubert JE., Husson B., and Clastres P. (2006), “Management of mineral wastes in cement- based materials.” Revue Europeenne de Genie Civil, 10(3):323-37
  15. Evangelista L and Brito JD, (2007), “Mechanical behaviour of concrete made with finerecycled aggregate.” Cement and Concrete Research; 29:397-401
  16. Figueiredo C. P., Santos F. B., Cascudo O., Carasek H., Cachim P. and Velosa A. (2014),“The role of metakaolin in the protection of concrete against the deleterious action of chlorides.” IBRACON Structures and Materials Journal; 7(4): 685-708
  17. Fernandez-Turiel J.L., Georgakopoulos A., Gimeno D., Papastergios G. and Kolovos N.(2004), “Ash Deposition in a Pulverized Coal-Fired Power Plant after High-CalciumLignite Combustion.” Energy and Fuels; 18:1512-1518
  18. Folagbade, Samuel Olufemi (2012), “Effect of fly ash and silica fume on the sorptivityofconcrete.” International Journal of Engineering Science and Technology (IJEST);4(9):4238-46
  19. Folagbade, Samuel Olufemi (2012), “Sorptivity of Cement Combination ConcretesContaining Portland Cement, Fly Ash AndMetakaolin.” International Journal ofEngineering Research and Applications (IJERA); 2(5):1953-59
  20. Ghafoori N. and Bucholc J. (1996), “Investigation of Lignite Based Bottom Ash forStructural concrete.” Journal of Materials in Civil Engineering; 8(3):128-137
  21. Ghafoori N. and Bucholc J. (1997), “Properties of High-Calcium Dry Bottom Ashconcrete.” ACI Materials Journal; 94(2): 90-101

International Journal of Scientific Research in Science and Technology

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Published

2019-01-30

Issue

Volume 6, Issue 1, January-February-2019

Section

Research Articles

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How to Cite

[1]
D. R. Sasirekha, S. Thejaswini, " Investigative Analysis on The Properties of Concrete Replacing Fine Aggregate with Bottom ASH and Quarry Dust , International Journal of Scientific Research in Science and Technology(IJSRST), Online ISSN : 2395-602X, Print ISSN : 2395-6011, Volume 6, Issue 1, pp.22-44, January-February-2019. Available at doi : https://doi.org/10.32628/IJSRST19619