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Year 2020, , 17 - 26, 26.03.2020
https://doi.org/10.17350/HJSE19030000167

Abstract

References

  • 1. Yumrutaş R, Kaşka Ö, Yıldırım E. Estimation of total equivalent temperature difference values for multilayer walls and flat roofs by using periodic solution. Building and Environment 42 (2007) 1878–1885.
  • 2. Bansal K, Chowdhury S, Gopal MR. Development of CLTD values for buildings located in Kolkata, India. Applied Thermal Engineering 28 (2008) 1127–1137.
  • 3. Yumrutas R, Unsal M, Kanoglu M. Periodic solution of transient heat flow through multilayer walls and flat roofs by complex finite Fourier transform technique. Building and Environment 40 (2005) 1117–1125.
  • 4. Wang SK. Handbook of air conditioning and refrigeration, McGraw-Hill, New York, 2001.
  • 5. ASHRAE. ASHRAE handbook-fundamentals, ASHRAE, Atlanta, 1993.
  • 6. Zainal OA, Yumrutas R. Validation of periodic solution for computing CLTD (cooling load temperature difference) values for building walls and flat roofs. Energy 82 (2015) 758–768.
  • 7. ACI Committee 213. Guide for Structural Lightweight Aggregate Concrete, American Concrete Institute ISBN: 978-0-87031-897-9, 2014.
  • 8. Yunsheng X, Chung DDL. Effect of sand addition on the specific heat and thermal conductivity of cement. Cement and Concrete Research 30 (2000) 59–61.
  • 9. Khan MI. Factors affecting the thermal properties of concrete and applicability of its prediction models. Building and Environment 37 (2002) 607–614.
  • 10. Kim K, Jeon S, Kim J, Yang S. An experimental study on thermal conductivity of concrete. Cement and Concrete Research 33 (2003) 363–371.
  • 11. Chi JM, Huang R, Yang CC, Chang JJ. Effect of aggregate properties on the strength and stiffness of lightweight concrete. Cement and Concrete Composites 25 (2003) 197–205.
  • 12. Howlader MK, Rashid MH, Mallick D, Haque T. Effects of aggregate types on thermal properties of concrete. ARPN Journal of Engineering and Applied Sciences 7 (2012) 900–907.
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  • 15. Kilincarslan Ş, Metin D, Mehmet A. The effect of pumice as aggregate on the mechanical and thermal properties of foam concrete. Arabian Journal of Geosciences 11 (2018) 289.
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  • 17. Yun TS, Jeong YJ, Han TS, Youm KS. Evaluation of thermal conductivity for thermally insulated concretes. Energy and Buildings 61 (2013) 125-132.
  • 18. Paki T, Yesilata B. Physico-mechanical and thermal performances of newly developed rubber-added bricks. Energy and Buildings 40 (2008) 679-688.
  • 19. Somayaji, S. Civil Engineering Materials, Upper Saddle River: Prentice Hall, ISBN 0-13-083906-X, p. 129, 2001.
  • 20. Oktay H, Yumrutaş R, Akpolat A. Mechanical and thermophysical properties of lightweight aggregate concretes. Construction and Building Materials 96 (2015) 217–225.
  • 21. BS 6073-1:1981. Precast concrete masonry units - Part 1: Specification for precast concrete masonry units, British Standards Institution, 1981.
  • 22. Duffie JA, Beckman WA. Solar engineering of thermal process, Wiley, New York, 1980.
  • 23. ASM International Materials Properties Database Committee, Thermal Properties of Metals, ISBN 0-87170-768-3, 2002.

Comparison of Thermal Performance of Newly Produced Lightweight Wall and Roof Elements for Energy-efficient Buildings

Year 2020, , 17 - 26, 26.03.2020
https://doi.org/10.17350/HJSE19030000167

Abstract

In this study, both experimental and theoretical investigations are performed to obtain new concrete types with high thermal insulating characteristics for energy-efficient buildings. In this regard, 102 new concrete wall samples were produced using different aggregates at different volume fractions, and their thermophysical properties were tested according to EN and ASTM standards. The experimental research focused on developing new wall or roof types with higher thermal insulation properties in order to reduce the energy consumption of buildings due to heating or cooling. In order to specify the thermal performance of developed lightweight concretes, an analytical solution method is developed by the Complex Finite Fourier Transform CFFT method to estimate heat gain utilizing measured thermophysical properties data of those samples. The results indicated that the reduction in heat gain value was obtained as 83.21 % for the PC100 wall corresponding to conventional concrete. Consequently, the thermal insulation effect of those samples shows excellent potential for development.

References

  • 1. Yumrutaş R, Kaşka Ö, Yıldırım E. Estimation of total equivalent temperature difference values for multilayer walls and flat roofs by using periodic solution. Building and Environment 42 (2007) 1878–1885.
  • 2. Bansal K, Chowdhury S, Gopal MR. Development of CLTD values for buildings located in Kolkata, India. Applied Thermal Engineering 28 (2008) 1127–1137.
  • 3. Yumrutas R, Unsal M, Kanoglu M. Periodic solution of transient heat flow through multilayer walls and flat roofs by complex finite Fourier transform technique. Building and Environment 40 (2005) 1117–1125.
  • 4. Wang SK. Handbook of air conditioning and refrigeration, McGraw-Hill, New York, 2001.
  • 5. ASHRAE. ASHRAE handbook-fundamentals, ASHRAE, Atlanta, 1993.
  • 6. Zainal OA, Yumrutas R. Validation of periodic solution for computing CLTD (cooling load temperature difference) values for building walls and flat roofs. Energy 82 (2015) 758–768.
  • 7. ACI Committee 213. Guide for Structural Lightweight Aggregate Concrete, American Concrete Institute ISBN: 978-0-87031-897-9, 2014.
  • 8. Yunsheng X, Chung DDL. Effect of sand addition on the specific heat and thermal conductivity of cement. Cement and Concrete Research 30 (2000) 59–61.
  • 9. Khan MI. Factors affecting the thermal properties of concrete and applicability of its prediction models. Building and Environment 37 (2002) 607–614.
  • 10. Kim K, Jeon S, Kim J, Yang S. An experimental study on thermal conductivity of concrete. Cement and Concrete Research 33 (2003) 363–371.
  • 11. Chi JM, Huang R, Yang CC, Chang JJ. Effect of aggregate properties on the strength and stiffness of lightweight concrete. Cement and Concrete Composites 25 (2003) 197–205.
  • 12. Howlader MK, Rashid MH, Mallick D, Haque T. Effects of aggregate types on thermal properties of concrete. ARPN Journal of Engineering and Applied Sciences 7 (2012) 900–907.
  • 13. Różycka A, Waldemar P. Effect of perlite waste addition on the properties of autoclaved aerated concrete. Construction and Building Materials 120 (2016) 65-71.
  • 14. Benazzouk A, Douzane O, Mezreb K, Laidoudi B, Que´neudec M. Thermal conductivity of cement composites containing rubber waste particles: Experimental study and modeling. Construction and Building Materials 22 (2008) 573–579.
  • 15. Kilincarslan Ş, Metin D, Mehmet A. The effect of pumice as aggregate on the mechanical and thermal properties of foam concrete. Arabian Journal of Geosciences 11 (2018) 289.
  • 16. Liu MYJ, Alengaram UJ, Jumaat MZ, Mo KH. Liu. Evaluation of thermal conductivity, mechanical and transport properties of lightweight aggregate foamed geopolymer concrete. Energy and Buildings 72 (2014) 238-245.
  • 17. Yun TS, Jeong YJ, Han TS, Youm KS. Evaluation of thermal conductivity for thermally insulated concretes. Energy and Buildings 61 (2013) 125-132.
  • 18. Paki T, Yesilata B. Physico-mechanical and thermal performances of newly developed rubber-added bricks. Energy and Buildings 40 (2008) 679-688.
  • 19. Somayaji, S. Civil Engineering Materials, Upper Saddle River: Prentice Hall, ISBN 0-13-083906-X, p. 129, 2001.
  • 20. Oktay H, Yumrutaş R, Akpolat A. Mechanical and thermophysical properties of lightweight aggregate concretes. Construction and Building Materials 96 (2015) 217–225.
  • 21. BS 6073-1:1981. Precast concrete masonry units - Part 1: Specification for precast concrete masonry units, British Standards Institution, 1981.
  • 22. Duffie JA, Beckman WA. Solar engineering of thermal process, Wiley, New York, 1980.
  • 23. ASM International Materials Properties Database Committee, Thermal Properties of Metals, ISBN 0-87170-768-3, 2002.
There are 23 citations in total.

Details

Primary Language English
Journal Section Research Article
Authors

Hasan Oktay This is me

Recep Yumrutas This is me

Zeki Argunhan This is me

Publication Date March 26, 2020
Published in Issue Year 2020

Cite

Vancouver Oktay H, Yumrutas R, Argunhan Z. Comparison of Thermal Performance of Newly Produced Lightweight Wall and Roof Elements for Energy-efficient Buildings. Hittite J Sci Eng. 2020;7(1):17-26.

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