Determining the optimum insulation thicknesses of external envelopes for livestock buildings are one of the most effective metrics to decrease energy requirements. This study was carried out to determine the optimum insulation thicknesses for livestock buildings in different climate zones, to examine the effects of insulation thickness and material (foam glass, mineral wool, expanded polystyrene, foamed polyurethane, foamed polyvinyl chloride, and expanded polyethylene) on life cycle total cost, life cycle savings, and payback period. The finishing pig houses and laying hen buildings with sandwich wall structures (color steel laminboard) in five typical cities were studied using the degree-days method with economic models. Optimal insulation thicknesses ranged from 0.05 m to 0.25 m and 0.02 m to 0.24 m in finishing pig houses and poultry buildings, respectively; the life cycle total costs ranged from 16.49 to 37.98 $/m2 and 13.37 to 36.84 $/m2; the life cycle savings ranged from 29.13 to 220.60 $/m2 and 0 to 202.13 $/m2; and the payback period ranged from 1.11 to 5.81 years and 1.19 to 20.76 years, respectively. Foamed polyurethane provided the highest life cycle savings, while foam glass had the lowest. In this research, the insulation thicknesses for the sandwich structure livestock buildings external envelopes are optimized, and the energy saving can be obtained by using proper insulation thickness in different regions. Furthermore, it can increase the knowledge about energy consumption in the livestock buildings and the results can be also a useful tool for farmers.
Keywords: livestock building, insulation material, optimum insulation thicknesses, degree-days, life cycle total cost, life cycle saving, payback period
DOI: 10.25165/j.ijabe.20201301.5280

Citation: Wang Y, Li B M, Zheng W C. Optimum insulation thickness for the sandwich structure livestock buildings external envelopes in different climate regions of China. Int J Agric & Biol Eng, 2020; 13(1): 29–41.

optimum insulation thickness, insulation material, degree-days, life cycle total cost, life cycle saving, payback period

Al-Sanea S A, Zedan M F, Al-Hussain S N. Effect of thermal mass on performance of insulated building walls and the concept of energy savings potential. Applied Energy, 2012; 89(1): 430–442.

Olgun M, Elik M Y, Polat H E. Determining of heat balance design criteria for laying hen houses under continental climate conditions. Building and Environment, 2007; 42(1): 355–365.

Kaynakli O. A review of the economical and optimum thermal insulation thickness for building applications. Renewable and Sustainable Energy Reviews, 2012; 16(1): 415–425.

Wang Y, Zheng W, Li B, Li X. A new ventilation system to reduce temperature fluctuations in laying hen housing in continental climate. Biosystems Engineering, 2018; 181: 52–62.

Compiled by National Bureau of Statistics of China. China Statistics Yearbook 2017. China Statistics Press, 2017. (in Chinese)

Yu J, Yang C, Tian L, Liao D. A study on optimum insulation thicknesses of external walls in hot summer and cold winter zone of China. Applied Energy, 2009; 86(11): 2520–2529.

Wang Y, Zheng W, Shi H, Li B. Optimising the design of confined laying hen house insulation requirements in cold climates without using supplementary heat. Biosystems Engineering, 2018; 174 :282–294.

Daouas N. A study on optimum insulation thickness in walls and energy savings in Tunisian buildings based on analytical calculation of cooling and heating transmission loads. Applied Energy, 2011; 88(1): 156–164.

Wang Y, Li B. An optimized solar-air degree-day method to evaluate energy demand for poultry buildings in different climate zones. Frontiers of Agricultural Science and Engineering (FASE), 2019, https://doi.org/10.15302/J-FASE-2019289.

Ekici B B, Gulten A A, Aksoy U T. A study on the optimum insulation thicknesses of various types of external walls with respect to different materials, fuels and climate zones in Turkey. Applied Energy, 2012; 92(2): 211–217.

Bolattürk A. Optimum insulation thicknesses for building walls with respect to cooling and heating degree-hours in the warmest zone of Turkey. Building & Environment, 2008; 43(6): 1055–1064.

Duffie J A, Bechman W A. Solar Energy and Thermal Process, New York: Wiley. 1991, p. 475–478.

Kamaruzzaman S N, Edwards R, Zawawi E M A, Che-Ani A. Achieving energy and cost savings through simple daylighting control in tropical historic buildings. Energy and Buildings, 2015; 90: 85–93.

Yu J, Tian L, Yang C, Xu X, Wang J. Optimum insulation thickness of residential roof with respect to solar-air degree-hours in hot summer and cold winter zone of china. Energy & Buildings, 2011; 43(9): 2304–2313.

Zhao Y, Xin H, Shepherd T A, Hayes M D, Stinn J P. Modelling ventilation rate, balance temperature and supplemental heat need in alternative vs. conventional laying-hen housing systems. Biosystems Engineering, 2013; 115(3): 311–323.

GB 50736-2012. Design Code for Heating Ventilation and Air Conditioning of Civil Buildings. China Architecture and Building Press, 2012. (in Chinese)

Bolattürk A. Determination of optimum insulation thickness for building walls with respect to various fuels and climate zones in Turkey. Applied Thermal Engineering, 2006; 26(11): 1301–1309.

Costantino A, Fabrizio E, Ghiggini A, Bariani M. Climate control in broiler houses: A thermal model for the calculation of the energy use and indoor environmental conditions. Energy and Buildings, 2018; 169: 110–126.

Mahlia T M I, Taufiq B N, Ismail, Masjuki H H. Correlation between thermal conductivity and the thickness of selected insulation materials for building wall. Energy and Buildings, 2007; 39(2): 182–187.

Ucar A, Balo F. Effect of fuel type on the optimum thickness of selected insulation materials for the four different climatic regions of Turkey. Applied Energy, 2009; 86(5): 730–736.

Li B, Shi Z. Engineering Technology on Equipped Agriculture. Beijing: China Agricultural Press, 2005, p.69–72, 114–118. (in Chinese)

Lu Y. Handbook of Heating and Air Conditioning Design. China Architecture and Building Press, 1993. (in Chinese)

Liu X, Chen Y, Ge H, Fazio P, Chen G, Guo X. Determination of Optimum Insulation Thickness of Exterior Wall with Moisture Transfer in Hot Summer and Cold Winter Zone of China. Procedia Engineering, 2015; 121: 1008–1015.