The article “Review of energy efficiency in controlled environment agriculture” (Engler.N & Krarti.M, 2021) described controlled environmental agriculture (CEA) applications and its relationship with HVAC (Heating, Ventilation, and Air Conditioning) systems. HVAC system is the technology used in indoor farming to control the environment for growing crops. This system has played an important part in meeting the demand for food production in urban farming. In addition, HVAC systems emphasize on focusing energy efficiency to address challenges posed by global warming in agriculture (AGRIVI, n.d.). The features of HVAC systems include thermostats and controllers, sensors, energy efficiency, and lighting integration that work together to create a sustainable environment for growing crops. Furthermore, the main function is to develop optimal environmental conditions for cultivation which include temperature control, ventilation and humidity control. Hence, HVAC systems used in urban farming plays a crucial role in ensuring food safety and quality produce without being affected by the climate. By using HVAC systems in urban agriculture to meet the food demand while factoring in the impacts of climate change.
Customization is one of the keys to both the distinctive feature
and pivotal function of HVAC systems
HVAC systems play a crucial role when space is limited and it
allows countries like Singapore to grow its own food despite the limited space
However, HVAC systems used in indoor farming are hard to
maintain as compared to traditional settings. Due to all year-round operations,
the equipment wear and tear would be high which will lead to an eventual
shortening of its life span. One of the HVAC systems for indoor
agriculture that are very good at temperature control is Energy-efficient. In
addition, most HVAC equipment is designed with the assumption that it will not
need to function at maximum capacity 24 hours a day, 365 days a year
In conclusion, HVAC systems in indoor agriculture can help
to solve not only climate change but also the population's food demands faced
by the world. With regard to Singapore's “30 by 30” goals, the country does not
need to rely on imported food and can ensure the food shortage that we faced
during COVID-19 period will not happen again in the future
References
AGRIVI. (n.d.). Overcoming
Weather Limitations with Greenhouse Farming. Retrieved from Agrivi:
https://www.agrivi.com/blog/overcoming-weather-limitations-with-greenhouse-farming/
Bowery. (2023,
Feb 02). Vertical Farming: Why Growing Up Can Make a Difference.
Retrieved from Bowery: https://bowery.co/vertical-farming/
CultivaSystems.
(n.d.). Indoor Agriculture HVAC. Retrieved from Cultiva Systems:
https://cultivasystems.com/indoor-agriculture-hvac/
Engler.N &
Krarti.M. (2021, May). Review of energy effciency in controlled
environment agriculture. Retrieved from sciencedirect: https://www.sciencedirect.com/science/article/pii/S1364032121000812
Sabeh.N. (2022,
Jun 22). Why Is HVAC so Hard for Indoor Farms? Retrieved from
greenhousegrower:
https://www.greenhousegrower.com/production/why-is-hvac-so-hard-for-indoor-farms/
SingaporeFoodAgency.
(2022, Nov 11). SFA. Retrieved from Food For Thought:
https://www.sfa.gov.sg/food-for-thought/article/detail/a-sustainable-food-system-for-singapore-and-beyond
Singaporelife.
(2023, Mar 06). GuideMeSingapore.Hawksford. Retrieved from
guidemesingapore:
https://www.guidemesingapore.com/in-the-news/2023/singapores-agritech-sector
verticalfarmdaily.
(2023, Apr 14). HVAC importance in vertical farming. Retrieved from
verticalfarmdaily:
https://www.verticalfarmdaily.com/article/9520856/hvac-importance-in-vertical-farming/
Wijkvliet.N.V.
(2022, Nov 11). sustainableurbandelta. Retrieved from
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https://sustainableurbandelta.com/singapore-30-by-30-food-system/