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Investigation of The Effect of Aggregate Type on Concrete Cost: Example of Adıyaman

Year 2020, Volume: 16 Issue: 3, 281 - 284, 29.09.2020
https://doi.org/10.18466/cbayarfbe.729086

Abstract

Concrete is a building material that is considered as a granular composite. The factor in its acceptance as granular is the aggregate in its content. In addition to forming the vast majority of aggregate concrete volume, it is also extremely important in the development of strength and durability factors. Although cement is the most costly input of concrete, it can affect the cost of concrete in changes in aggregate type. For this purpose, in this study, concrete samples were produced with different types of aggregates from different quarries operating in Adıyaman province. Only the type of aggregate was changed and cost calculations were made, provided that the cement type and amount and other components in the mixture remained constant. In addition, cost and strength comparisons were made by measuring pressure resistance values for 7 and 28 days.

References

  • 1. Meyer, C, 2009. The greening of the concrete industry, Cement& Concrete Composite. 31: 601–605.
  • 2. Mehta, P.K, Monteiro, P. Concrete: Microstructure, Properties, and Materials; McGraw-Hill Publishing: New York, NJ, USA, 2006, pp 21-47.
  • 3. Ghorbani, S, Sharifi, S, Ghorbani, S, Tam, V, Brito, J.D, Kurda, R, 2019. Effect of crushed concrete waste’s maximum size as partial replacement of T natural coarse aggregate on the mechanical and durability properties of concrete, Resources, Conservation & Recycling, 149: 664–673.
  • 4. Neville, A.M. Properties of concrete: 5th edition, Pearson: England, 2011, pp 17-267.
  • 5. Alexander, M., Mindess, S. Aggregates in concrete: Taylor and Francis: England, 2010, pp 16-65.
  • 6. Thomas M.D.A, Folliard, K.J, Concrete aggregates and the durability of concrete: Page C.L, and Page M.M (ed) Durability of concrete and cement composites, CRC Press, England, 2007, pp 247-277
  • 7. Petrounias, P, Giannakopoulou, P.P, Rogkala, A, Stamatis, P.M, Tsikouras, B, Papoulis, D, Lampropoulou, P, Hatzipanagiotou, K, 2018. The influence of alteration of aggregates on the quality of the concrete: A case study from serpentinites and andesites from central Macedonia (North Greece), Geosciences, 8:115.
  • 8. Yilmaz, M, Turul, A, 2012. The effects of different sandstone aggregates on concrete strength, Construction and Building. Materials, 35: 294–303.
  • 9. Mays G. Durability of concrete structures: Taylor and Francis, England, 2003, pp 3-9.
  • 10. Khatib M.J. Sustainability of construction materials: CRC Press, England, 2009, pp 2-20.
  • 11. Shetty M.S. Concrete technology theory and practice: S. Chand Company Ltd., India, 2005, pp 66-118.
  • 12. Erdoğan T. Beton: ODTÜ Yayıncılık, Türkiye, 2015, pp 66-115.
  • 13. Güçlüer, K, 2020. Investigation of the effects of aggregate textural properties on compressive strength (CS) and ultrasonic pulse velocity (UPV) of concrete, Journal of Building Engineering , 27: 100949.
  • 14. Beshr, H, Almusallam, A, Maslehuddin, M, 2003. Effect of coarse aggregate quality on the mechanical properties of high-strength concrete, Construction and Building Materials, 17:97–103.
  • 15. Ozturan, T, Cecen, C, 1997. Effect of coarse aggregate type on mechanical properties of concretes with different strengths, Cement and Concrete Research, 27:165–170.
  • 16. Yilmaz, M, Turul, A, 2012. The effects of different sandstone aggregates on concrete strength, Construction and building Materials, 35:294–303.
  • 17. Ahmad, S, Alghamdi, S.A, 2012. A study on effect of coarse aggregate type on concrete performance. Arabian Journal of Science and Engineering, 37:1777–1786.
  • 18. TS EN 197–1, Çimentoların Bileşim, özellikler ve uygunluk Kriterleri, Türk Standartları Enstitüsü, Ankara, 2002.
  • 19. TS EN 206-1, Beton-Bölüm 1: Özellik, performans, imalat ve uygunluk, Türk Standartlar Enstitüsü, Ankara, 2002.
  • 20. TS EN 12390–3, Beton-Sertleşmiş beton deneyleri-Deney numunelerinde basınç dayanımı tayini, Türk Standartlar Enstitüsü, Ankara, 2003.
  • 21. Kahraman, S, Alber M, Fener, M, Gunaydın, O, 2008. Evaluating the geomechanical properties of Misis fault breccia (Turkey), International Journal Rock Mechanics and Mining Sciences, 45: 1469–1479.
Year 2020, Volume: 16 Issue: 3, 281 - 284, 29.09.2020
https://doi.org/10.18466/cbayarfbe.729086

Abstract

References

  • 1. Meyer, C, 2009. The greening of the concrete industry, Cement& Concrete Composite. 31: 601–605.
  • 2. Mehta, P.K, Monteiro, P. Concrete: Microstructure, Properties, and Materials; McGraw-Hill Publishing: New York, NJ, USA, 2006, pp 21-47.
  • 3. Ghorbani, S, Sharifi, S, Ghorbani, S, Tam, V, Brito, J.D, Kurda, R, 2019. Effect of crushed concrete waste’s maximum size as partial replacement of T natural coarse aggregate on the mechanical and durability properties of concrete, Resources, Conservation & Recycling, 149: 664–673.
  • 4. Neville, A.M. Properties of concrete: 5th edition, Pearson: England, 2011, pp 17-267.
  • 5. Alexander, M., Mindess, S. Aggregates in concrete: Taylor and Francis: England, 2010, pp 16-65.
  • 6. Thomas M.D.A, Folliard, K.J, Concrete aggregates and the durability of concrete: Page C.L, and Page M.M (ed) Durability of concrete and cement composites, CRC Press, England, 2007, pp 247-277
  • 7. Petrounias, P, Giannakopoulou, P.P, Rogkala, A, Stamatis, P.M, Tsikouras, B, Papoulis, D, Lampropoulou, P, Hatzipanagiotou, K, 2018. The influence of alteration of aggregates on the quality of the concrete: A case study from serpentinites and andesites from central Macedonia (North Greece), Geosciences, 8:115.
  • 8. Yilmaz, M, Turul, A, 2012. The effects of different sandstone aggregates on concrete strength, Construction and Building. Materials, 35: 294–303.
  • 9. Mays G. Durability of concrete structures: Taylor and Francis, England, 2003, pp 3-9.
  • 10. Khatib M.J. Sustainability of construction materials: CRC Press, England, 2009, pp 2-20.
  • 11. Shetty M.S. Concrete technology theory and practice: S. Chand Company Ltd., India, 2005, pp 66-118.
  • 12. Erdoğan T. Beton: ODTÜ Yayıncılık, Türkiye, 2015, pp 66-115.
  • 13. Güçlüer, K, 2020. Investigation of the effects of aggregate textural properties on compressive strength (CS) and ultrasonic pulse velocity (UPV) of concrete, Journal of Building Engineering , 27: 100949.
  • 14. Beshr, H, Almusallam, A, Maslehuddin, M, 2003. Effect of coarse aggregate quality on the mechanical properties of high-strength concrete, Construction and Building Materials, 17:97–103.
  • 15. Ozturan, T, Cecen, C, 1997. Effect of coarse aggregate type on mechanical properties of concretes with different strengths, Cement and Concrete Research, 27:165–170.
  • 16. Yilmaz, M, Turul, A, 2012. The effects of different sandstone aggregates on concrete strength, Construction and building Materials, 35:294–303.
  • 17. Ahmad, S, Alghamdi, S.A, 2012. A study on effect of coarse aggregate type on concrete performance. Arabian Journal of Science and Engineering, 37:1777–1786.
  • 18. TS EN 197–1, Çimentoların Bileşim, özellikler ve uygunluk Kriterleri, Türk Standartları Enstitüsü, Ankara, 2002.
  • 19. TS EN 206-1, Beton-Bölüm 1: Özellik, performans, imalat ve uygunluk, Türk Standartlar Enstitüsü, Ankara, 2002.
  • 20. TS EN 12390–3, Beton-Sertleşmiş beton deneyleri-Deney numunelerinde basınç dayanımı tayini, Türk Standartlar Enstitüsü, Ankara, 2003.
  • 21. Kahraman, S, Alber M, Fener, M, Gunaydın, O, 2008. Evaluating the geomechanical properties of Misis fault breccia (Turkey), International Journal Rock Mechanics and Mining Sciences, 45: 1469–1479.
There are 21 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Kadir Güçlüer

Osman Günaydın

Samet Göymen

Publication Date September 29, 2020
Published in Issue Year 2020 Volume: 16 Issue: 3

Cite

APA Güçlüer, K., Günaydın, O., & Göymen, S. (2020). Investigation of The Effect of Aggregate Type on Concrete Cost: Example of Adıyaman. Celal Bayar Üniversitesi Fen Bilimleri Dergisi, 16(3), 281-284. https://doi.org/10.18466/cbayarfbe.729086
AMA Güçlüer K, Günaydın O, Göymen S. Investigation of The Effect of Aggregate Type on Concrete Cost: Example of Adıyaman. CBUJOS. September 2020;16(3):281-284. doi:10.18466/cbayarfbe.729086
Chicago Güçlüer, Kadir, Osman Günaydın, and Samet Göymen. “Investigation of The Effect of Aggregate Type on Concrete Cost: Example of Adıyaman”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 16, no. 3 (September 2020): 281-84. https://doi.org/10.18466/cbayarfbe.729086.
EndNote Güçlüer K, Günaydın O, Göymen S (September 1, 2020) Investigation of The Effect of Aggregate Type on Concrete Cost: Example of Adıyaman. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 16 3 281–284.
IEEE K. Güçlüer, O. Günaydın, and S. Göymen, “Investigation of The Effect of Aggregate Type on Concrete Cost: Example of Adıyaman”, CBUJOS, vol. 16, no. 3, pp. 281–284, 2020, doi: 10.18466/cbayarfbe.729086.
ISNAD Güçlüer, Kadir et al. “Investigation of The Effect of Aggregate Type on Concrete Cost: Example of Adıyaman”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi 16/3 (September 2020), 281-284. https://doi.org/10.18466/cbayarfbe.729086.
JAMA Güçlüer K, Günaydın O, Göymen S. Investigation of The Effect of Aggregate Type on Concrete Cost: Example of Adıyaman. CBUJOS. 2020;16:281–284.
MLA Güçlüer, Kadir et al. “Investigation of The Effect of Aggregate Type on Concrete Cost: Example of Adıyaman”. Celal Bayar Üniversitesi Fen Bilimleri Dergisi, vol. 16, no. 3, 2020, pp. 281-4, doi:10.18466/cbayarfbe.729086.
Vancouver Güçlüer K, Günaydın O, Göymen S. Investigation of The Effect of Aggregate Type on Concrete Cost: Example of Adıyaman. CBUJOS. 2020;16(3):281-4.