Analysing the influence of growing conditions on both energy load and crop yield of a controlled environment agriculture space

Talbot, Marie-Hélène et Monfet, Danielle. 2024. « Analysing the influence of growing conditions on both energy load and crop yield of a controlled environment agriculture space ». Applied Energy, vol. 368.

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Résumé

Controlled environment agriculture, such as vertical farming, consists of stacking crops in a controlled environment and is transforming agriculture by providing a highly productive solution for year-round production. However, vertical farms are also energy-intensive due to precise control of the growing conditions (temperature, humidity, carbon dioxide, and lighting). While many studies focus on optimising indoor conditions to enhance yield, the impact of those growing conditions on energy is often overlooked. This study aims to provide a comprehensive analysis, using a dynamic model, of the influence of growing conditions typically used to cultivate lettuces on energy and crop yield. Several combinations of air temperatures (20, 24 and 28 °C), vapour pressure deficits (0.54 and 0.85 kPa), lighting intensities (200 to 700 μmol·m−2·s−1) and photoperiods (12 to 24 h) are studied. The dynamic model, developed using a building performance simulation tool, supports the simultaneous assessment of energy load and crop yield. It includes a model of a small-scale vertical farm that integrates a dynamic crop model to estimate heat gains/losses from crops and crop growth rate according to growing conditions. The results indicated that the best compromise between energy load and yield is at an air temperature of 24 °C. Moreover, lowering lighting intensity and extending the photoperiod positively impacted both energy load and yield. Certain growing conditions, such as lowering the vapour pressure deficit, can reduce the need for dehumidification. Additionally, for lighting intensities exceeding 500 μmol∙m−2∙s−1, although the energy load continued to increase linearly with the lighting intensity, the growth rate was limited, resulting in reduced production efficiency. These extensive results and thorough analyses offer valuable insights into the influence of the growing conditions on energy load and yield.

Type de document:	Article publié dans une revue, révisé par les pairs
Professeur:	Professeur Monfet, Danielle
Affiliation:	Génie de la construction
Date de dépôt:	05 juin 2024 18:38
Dernière modification:	07 juin 2024 16:57
URI:	https://espace2.etsmtl.ca/id/eprint/28767

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