Assessing heating and cooling demands of closed greenhouse systems in a cold climate

Semple, Lucas; Carriveau, Rupp; Ting, David S.‐K.

doi:10.1002/er.3752

Cited by 20 publications

(18 citation statements)

References 27 publications

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“…For calculation of the heating load, in order to normalize the model, 1 acre of the greenhouse is simulated. This acre consists of 10 bays, each with a width of 5 m. To evaluate the thermal conditions near and far from the crop, two lower and upper thermal zones were considered 49 . The height of the lower zone is 3.5 m. A plug‐in called TRNSYS3d for Google SketchUp is used to input the geometric information into the building model.…”

Section: Methodsmentioning

confidence: 99%

Hybrid solar thermal/photovoltaic‐battery energy storage system in a commercial greenhouse: Performance and economic analysis

et al. 2020

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Performance and economic analyses of a hybrid solar thermal/photovoltaic‐battery energy storage (ST/PV‐BES) system for a commercial greenhouse were developed. One of the objectives of the study is to evaluate the best configuration of photovoltaic (PV) and solar thermal (ST) modules, and battery energy storage size to have the minimum levelized cost of energy. The system was economically optimized. Moreover, to assess the influence of economic parameters such as ST system cost, PV system cost, natural gas price, electricity price, and large renewable procurement (LRP) rate, a series of sensitivity analyses were undertaken. The results showed that the ST system cost and natural gas price were the most effective parameters on both levelized cost of energy and payback period. The role of future evolution of electricity, fuel cost, and financial incentives (LRP rate and carbon tax) in the economic performance of the system were also analyzed.

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Section: Methodsmentioning

confidence: 99%

Hybrid solar thermal/photovoltaic‐battery energy storage system in a commercial greenhouse: Performance and economic analysis

et al. 2020

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“…In order to normalize the model, 1 acre of the greenhouse was simulated. This acre is made up of 10 bays, each with a width of 5 m. Lower and upper thermal zones were considered to evaluate the thermal conditions near and far from the crop . The height of the lower zone was 3.5 m. A plug‐in called TRNSYS3d for Google SketchUp was used to input the geometric information into the building model.…”

Section: Methodsmentioning

confidence: 99%

“…In addition, based on the data, morning pre‐heating is supplied between the hours of 3 and 6 am year‐round, regardless of the indoor temperature. From mid‐November to January, there are no crops in the greenhouse, thus the indoor temperature is only maintained above freezing at about 5°C . The heating system of the reference greenhouse consists mainly of hot water piping located near the floor and the top of the fully grown crops.…”

Section: Methodsmentioning

confidence: 99%

“…The heating system of the reference greenhouse consists mainly of hot water piping located near the floor and the top of the fully grown crops. An overall heating efficiency of 75% has been assumed for the heating system . When the inside temperature exceeds 25°C or the relative humidity exceeds 85%, the ventilation system activates providing 60 ACH.…”

Section: Methodsmentioning

confidence: 99%

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Improving clean energy greenhouse heating with solar thermal energy storage and phase change materials

2019

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Greenhouses consume a great deal of energy to heat their building envelopes.The strategic integration of solar energy and thermal energy storage (TES) can help to boost energy performance and reduce the carbon emission in the sector. In this paper, the benefits of adding phase change materials (PCM) to the water tank of a solar heating system have been evaluated using the Transient System Simulation (TRNSYS) program. Initially, the hourly heating load of a reference greenhouse was evaluated using TRNSYS software. The results were validated with natural gas consumption data. The validated simulation was then used to investigate the impact of PCM on the performance of a large-scale solar energy system. Four system configurations were evaluated; no PCM materials in the tank, then 20%, 40%, and 60% of the water tank volume occupied by PCM. Energy performance improvements of 10% to 14% were observed by increasing the proportion of PCM amounts over the baseline conventional system. Finally, an economic study was conducted to investigate the cost feasibility of different PCM concentrations. It was shown that PCM price, cost of natural gas, and carbon tax are the principal influence factors on the payback period. K E Y W O R D Sgreenhouse, phase change material (PCM), solar heating system

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“…The most important characteristic of closed greenhouses is their role in water and energy conservation. 98,99,101 The water consumed for irrigation can be reduced by 50% to 80% in these greenhouses while the total EC can be reduced by 19%. 98,99 A greenhouse can also be partly closed.…”

Section: Closed Greenhousesmentioning

confidence: 99%

A comprehensive review of solar‐driven desalination technologies for off‐grid greenhouses

Shekarchi

Shahnia

2018

Int J Energy Res

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Summary This paper is motivated by the crisis of freshwater in remote areas around the world and responds to the growing need for sustainable food production in arid lands. It focuses on utilizing solar energy to yield freshwater from the sea or brackish water with less environmental impacts, for greenhouses, which can produce sustainable food all over the year. The integration of various solar‐driven desalinations such as solar still, humidification‐dehumidification, reverse osmosis, electrodialysis, and multieffect and multistage flash with greenhouses are evaluated, for better sustainability towards greenization. The paper first discusses the specifications of solar‐driven desalinations and compares their advantages and limitations. Then, different types of greenhouses are introduced, and their total water requirement is discussed based on their locations, crop type, greenhouse technology, irrigation type, and environmental conditions, as well as their cooling and heating strategies. Later, the existing integration of solar‐driven desalinations with greenhouses are reviewed, and their advantages and limitations are deliberated. Finally, the paper discusses the criteria to be considered when selecting solar‐driven desalinations for greenhouses and presents a detailed comparison between the water production rate and cost as well as the energy consumption of these systems. In the end, the most appropriate combinations of solar‐driven desalinations with greenhouses are recommended based on their water requirement and production cost.

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Assessing heating and cooling demands of closed greenhouse systems in a cold climate

Cited by 20 publications

References 27 publications

Hybrid solar thermal/photovoltaic‐battery energy storage system in a commercial greenhouse: Performance and economic analysis

Hybrid solar thermal/photovoltaic‐battery energy storage system in a commercial greenhouse: Performance and economic analysis

Improving clean energy greenhouse heating with solar thermal energy storage and phase change materials

A comprehensive review of solar‐driven desalination technologies for off‐grid greenhouses

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