Application of dynamic thermal engineering principles to improve the efficiency of resource use in UK pork production chains

This paper investigates the potential for incorporation of human commercial building design modelling into the pig production industry. During the last decades pig building design has relied heavily on building manufacturers compared to human commercial buildings that regulate standards to improve t...

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Published in	Energy and buildings Vol. 139; pp. 53 - 62
Main Authors	Jackson, Paul, Guy, Jonathan, Edwards, Sandra A., Sturm, Barbara, Bull, Steve
Format	Journal Article
Language	English
Published	Lausanne Elsevier B.V 15.03.2017 Elsevier BV
Subjects	Air quality Animal care Building design Climate change Commercial buildings Design Design improvements Efficiency Extreme cold Feed conversion Feed efficiency Finishing Indoor air pollution Indoor air quality Indoor environments Livestock housing Low temperature Mathematical models Modelling Pig building Pork Resource efficiency Sustainability Sustainable Sustainable design Swine Swine houses Swine production Temperature Temperature effects Thermal analysis Thermal conductivity Thermal engineering Thermal properties Thermodynamic properties Ventilation United Kingdom > UK Ventilation Thermal conductivity Modelling Pig building Sustainable
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ISSN	0378-7788 1872-6178
DOI	10.1016/j.enbuild.2016.12.090

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Abstract	This paper investigates the potential for incorporation of human commercial building design modelling into the pig production industry. During the last decades pig building design has relied heavily on building manufacturers compared to human commercial buildings that regulate standards to improve the sustainability of the building. Thus, the aim of this paper was to gain a greater understanding of the design requirements for sustainable forms of pig housing, which could potentially improve the welfare of the pig and promote greater resource use efficiency. Part of an existing mechanically ventilated UK pig production building, which represents three adjacent fully-slatted units each capable of holding approximately 292 pigs and measuring approximately 18m x 14m, was used as a basis to create a dynamic thermal model of the building. The model takes into account the possibility of future rises in environmental temperature and the effect of this climate change on building performance and pig growth, feed efficiency and welfare. The results of the model showed that as the finishing pigs increased in size they have the potential to be subject to increasingly poor indoor air quality, during the winter months. The model also shows that improving the thermal properties of the building not only helps with reducing the amount of time that the pigs could potentially spend at extreme low temperatures, by approximately 1115h (46days), but can also help with reducing the number of hours the pigs spend above 26°C during the summer months, by approximately 8h.
AbstractList	This paper investigates the potential for incorporation of human commercial building design modelling into the pig production industry. During the last decades pig building design has relied heavily on building manufacturers compared to human commercial buildings that regulate standards to improve the sustainability of the building. Thus, the aim of this paper was to gain a greater understanding of the design requirements for sustainable forms of pig housing, which could potentially improve the welfare of the pig and promote greater resource use efficiency. Part of an existing mechanically ventilated UK pig production building, which represents three adjacent fully-slatted units each capable of holding approximately 292 pigs and measuring approximately 18 m x 14m, was used as a basis to create a dynamic thermal model of the building. The model takes into account the possibility of future rises in environmental temperature and the effect of this climate change on building performance and pig growth, feed efficiency and welfare. The results of the model showed that as the finishing pigs increased in size they have the potential to be subject to increasingly poor indoor air quality, during the winter months. The model also shows that improving the thermal properties of the building not only helps with reducing the amount of time that the pigs could potentially spend at extreme low temperatures, by approximately 1115 h (46 days), but can also help with reducing the number of hours the pigs spend above 26 °C during the summer months, by approximately 8 h. This paper investigates the potential for incorporation of human commercial building design modelling into the pig production industry. During the last decades pig building design has relied heavily on building manufacturers compared to human commercial buildings that regulate standards to improve the sustainability of the building. Thus, the aim of this paper was to gain a greater understanding of the design requirements for sustainable forms of pig housing, which could potentially improve the welfare of the pig and promote greater resource use efficiency. Part of an existing mechanically ventilated UK pig production building, which represents three adjacent fully-slatted units each capable of holding approximately 292 pigs and measuring approximately 18m x 14m, was used as a basis to create a dynamic thermal model of the building. The model takes into account the possibility of future rises in environmental temperature and the effect of this climate change on building performance and pig growth, feed efficiency and welfare. The results of the model showed that as the finishing pigs increased in size they have the potential to be subject to increasingly poor indoor air quality, during the winter months. The model also shows that improving the thermal properties of the building not only helps with reducing the amount of time that the pigs could potentially spend at extreme low temperatures, by approximately 1115h (46days), but can also help with reducing the number of hours the pigs spend above 26°C during the summer months, by approximately 8h.
Author	Jackson, Paul Guy, Jonathan Bull, Steve Sturm, Barbara Edwards, Sandra A.
Author_xml	– sequence: 1 givenname: Paul surname: Jackson fullname: Jackson, Paul email: p.jackson4@newcastle.ac.uk organization: School of Agriculture, Food and Rural Development, Newcastle University, Newcastle upon Tyne, UK – sequence: 2 givenname: Jonathan surname: Guy fullname: Guy, Jonathan organization: School of Agriculture, Food and Rural Development, Newcastle University, Newcastle upon Tyne, UK – sequence: 3 givenname: Sandra A. surname: Edwards fullname: Edwards, Sandra A. organization: School of Agriculture, Food and Rural Development, Newcastle University, Newcastle upon Tyne, UK – sequence: 4 givenname: Barbara surname: Sturm fullname: Sturm, Barbara organization: School of Agriculture, Food and Rural Development, Newcastle University, Newcastle upon Tyne, UK – sequence: 5 givenname: Steve surname: Bull fullname: Bull, Steve organization: School of Chemical Engineering and Advanced Materials, Newcastle University, Newcastle upon Tyne, UK
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SubjectTerms	Air quality Animal care Building design Climate change Commercial buildings Design Design improvements Efficiency Extreme cold Feed conversion Feed efficiency Finishing Indoor air pollution Indoor air quality Indoor environments Livestock housing Low temperature Mathematical models Modelling Pig building Pork Resource efficiency Sustainability Sustainable Sustainable design Swine Swine houses Swine production Temperature Temperature effects Thermal analysis Thermal conductivity Thermal engineering Thermal properties Thermodynamic properties Ventilation
Title	Application of dynamic thermal engineering principles to improve the efficiency of resource use in UK pork production chains
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