Ground Thermal Inertia for Energy Efficient Building Design: A Case Study on Food Industry

The search for energy efficient construction solutions is still pending in the agro-food industry, in which a large amount of energy is often consumed unnecessarily when storing products. The main objective of this research is to promote high energy efficiency built environments, which aim to reduce energy consumption in this sector. We analyze the suitability of using the thermal inertia of the ground to provide an adequate environment for the storage and conservation of agro-food products. This research compares different construction solutions based on the use of ground thermal properties, analyzing their effectiveness to decrease annual outdoor variations and provide adequate indoor conditions. The analysis undertaken is based on over five million pieces of data, obtained from an uninterrupted four year monitoring process of various constructions with different levels of thermal mass, ranging from high volume constructions to others lacking this resource. It has been proven that constructive solutions based on the use of ground thermal inertia are more effective than other solutions when reducing the effects of outdoor conditions, even when these have air conditioning systems. It is possible to reach optimal conditions to preserve agro-food products such as wine, with a good design and an adequate amount of terrain, without having to use air conditioning systems. The results of this investigation could be of great use to the agro-food industry, becoming a reference when it comes to the design of energy efficient constructions.

[1]  Véronique Cheynier,et al.  Effect of oxygenation on polyphenol changes occurring in the course of wine-making , 2002 .

[2]  H. Asan,et al.  Investigation of wall's optimum insulation position from maximum time lag and minimum decrement factor point of view , 2000 .

[3]  Douglas John Harris,et al.  A guideline for assessing the suitability of earth-sheltered mass-housing in hot-arid climates , 2004 .

[4]  F. R. Mazarrón,et al.  Exponential sinusoidal model for predicting temperature inside underground wine cellars from a Spanish region , 2008 .

[5]  Gerhard Troost,et al.  Tecnología del vino , 1985 .

[6]  Tadj Oreszczyn,et al.  Energy efficiency in building envelopes through ground integration , 1994 .

[7]  A. J. Anselm,et al.  Passive annual heat storage principles in earth sheltered housing, a supplementary energy saving system in residential housing , 2008 .

[8]  Fernando R. Mazarrón,et al.  Seasonal analysis of the thermal behaviour of traditional underground wine cellars in Spain , 2009 .

[9]  Teresa Garde-Cerdán,et al.  Review of quality factors on wine ageing in oak barrels , 2006 .

[10]  S. Martin,et al.  A Comparison Between Underground Wine Cellars and Aboveground Storage for the Aging of Spanish Wines , 2006 .

[11]  F. V. Dunkel Underground and earth sheltered food storage: historical, geographic, and economic considerations , 1985 .

[12]  L. M. López,et al.  A Fickian model for calculating wine losses from oak casks depending on conditions in ageing facilities , 2005 .

[13]  Fan Wang,et al.  Thermal environment of the courtyard style cave dwelling in winter , 2002 .

[14]  Karolos-Nikolaos Kontoleon,et al.  The influence of wall orientation and exterior surface solar absorptivity on time lag and decrement factor in the Greek region , 2008 .

[15]  Fernando R. Mazarrón,et al.  The effect of traditional wind vents called zarceras on the hygrothermal behaviour of underground wine cellars in Spain , 2009 .

[16]  Yeon-Jun Park,et al.  Test running of an underground food storage cavern in Korea , 2000 .

[17]  I. Guerrero,et al.  Study of the thermal behaviour of traditional wine cellars: the case of the area of ¿Tierras Sorianas del Cid¿ (Spain) , 2005 .