A Solar Powered Liquid-Desiccant Cooling System for Greenhouses

Lychnos, George; Davies, Philip A.

doi:10.17660/actahortic.2008.797.11

Cited by 8 publications

(8 citation statements)

References 15 publications

(11 reference statements)

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“…The shown desiccator integrates cellulose pads with embedded heat exchange pipes. It is based on the design described by Lychnos and Davies [15,25]. The cellulose pad provides the surface area for air to desiccant contact and humidity removal.…”

Section: Direct Contact Desiccatormentioning

confidence: 99%

Liquid desiccant dehumidification and regeneration process to meet cooling and freshwater needs of desert greenhouses

Lefers

Bettahalli

Nunes

et al. 2016

Desalination and Water Treatment

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20Agriculture accounts for ~70% of freshwater usage worldwide. Seawater desalination alone cannot meet 21 the growing needs for irrigation and food production, particularly in hot, desert environments. 22Greenhouse cultivation of high-value crops uses just a fraction of fresh water per unit of food produced 23when compared with open field cultivation. However, desert greenhouse producers face three main 24 challenges: fresh water supply, plant nutrient supply and cooling of the greenhouse. The common 25 practice of evaporative cooling for greenhouses consumes large amounts of fresh water. In Saudi 26Arabia, the most common greenhouse cooling schemes are fresh water-based evaporative cooling, 27 often using fossil groundwater or energy-intensive desalinated water, and traditional refrigeration-28 based direct expansion cooling, largely powered by the burning of fossil fuels. The coastal deserts have 29 ambient conditions that are seasonally too humid to support adequate evaporative cooling, 30 necessitating additional energy consumption in the dehumidification process of refrigeration-based 31cooling. This project evaluates the use of a combined-system liquid desiccant dehumidifier and 32 membrane distillation unit that can meet the dual needs of cooling and fresh water supply for a 33 greenhouse in a hot and humid environment. 34

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Section: Direct Contact Desiccatormentioning

confidence: 99%

Liquid desiccant dehumidification and regeneration process to meet cooling and freshwater needs of desert greenhouses

Lefers

Bettahalli

Nunes

et al. 2016

Desalination and Water Treatment

View full text Add to dashboard Cite

show abstract

“…Commonly used desiccants include aqueous solutions of lithium chloride, calcium chloride, lithium bromide and triethylene glycol. Other desiccants include seawater bitterns, MgCl 2 [16], KCOOH, glycols like triethylene glycol (TEG), diethylene glycol (DEG), MEG, propylene glycol, and mixtures of desiccants LiCl + LiBr or LiCl + CaCl 2 [15,17].…”

Section: Liquid Desiccant Materialsmentioning

confidence: 99%

Solar pond powered liquid desiccant evaporative cooling

Elsarrag

Igobo

Alhorr

et al. 2016

Renewable and Sustainable Energy Reviews

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Liquid desiccant cooling systems (LDCS) are energy efficient means of providing cooling, especially when powered by low-grade thermal sources. In this paper, the underlying principles of operation of desiccant cooling systems are examined, and the main components (dehumidifier, evaporative cooler and regenerator) of the LDCS are reviewed. The evaporative cooler can take the form of direct, indirect or semi-indirect. Relative to the direct type, the indirect type is generally less effective. Nonetheless, a certain variant of the indirect type -namely dew-point evaporative cooler -is found to be the most effective amongst all. The dehumidifier and the regenerator can be of the same type of equipment: packed tower and falling film are popular choices, especially when fitted with an internal heat exchanger. The energy requirement of the regenerator can be supplied from solar thermal collectors, of which a solar pond is an interesting option especially when a large scale or storage capability is desired.

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“…This approach applies heat and mass balance to a differential control volume at some position x from the inlet of the regenerator to formulate an ordinary differential equation, the solution to which gives an expression for the rate of evaporation per unit area of the surface. The regenerator theory is presented in detail in Appendix A and reference [51]. Fig.2 shows the detailed arrangement of the desiccator which contains several sections of porous medium (CELdek®) each inserted between bundles of cooling tubes.…”

Section: Regeneratormentioning

confidence: 99%

“…Some experiments were carried out under drier conditions (RH 60-63%) but showed a significant drop of the performance and are not reported here (see ref. [51] for more details). Table 1 shows the conditions of the five experiments of this study.…”

Section: Desiccatormentioning

confidence: 99%

“…is the liquid desiccant mass flow rate per unit width, des m is the salt mass flow rate per unit width, h m is the mass transfer coefficient based on pressure gradient, P 0 and P amb are the initial vapour pressure of the solution and the ambient pressure respectively, U L is the overall heat loss coefficient,in s, X is the initial liquid desiccant concentration and ps C is the specific heat capacity of the liquid desiccant.The following linear expression is used to approximate the variation of vapour pressure with temperature and concentration over small intervals: and c are calculated from experimental values[59] seeTable A.1. The detailed derivation of the above analytical solution can be found in ref [51]…”

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confidence: 99%

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Modelling and experimental verification of a solar-powered liquid desiccant cooling system for greenhouse food production in hot climates

Lychnos

Davies

2012

Energy

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Experiments and theoretical modelling have been carried out to predict the performance of a solar-powered liquid desiccant cooling system for greenhouses. We have tested two components of the system in the laboratory using MgCl 2 desiccant: (i) a regenerator which was tested under a solar simulator and (ii) a desiccator which was installed in a test duct. Theoretical models have been developed for both regenerator and desiccator and gave good agreement with the experiments. The verified computer model is used to predict the performance of the whole system during the hot summer months in Mumbai, Chittagong, Muscat, Messina and Havana. Taking examples of temperate, subtropical, tropical and heat-tolerant tropical crops (lettuce, soya bean, tomato and cucumber respectively) we estimate the extensions in growing seasons enabled by the system. Compared to conventional evaporative cooling, the desiccant system lowers average daily maximum temperatures in the hot season by 5.5-7.5°C, sufficient to maintain viable growing conditions for lettuce throughout the year. In the case of tomato, cucumber and soya bean the system enables optimal cultivation through most summer months. It is concluded that the concept is technically viable and deserves testing by means of a pilot installation at an appropriate location.

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A Solar Powered Liquid-Desiccant Cooling System for Greenhouses

Cited by 8 publications

References 15 publications

Liquid desiccant dehumidification and regeneration process to meet cooling and freshwater needs of desert greenhouses

Liquid desiccant dehumidification and regeneration process to meet cooling and freshwater needs of desert greenhouses

Solar pond powered liquid desiccant evaporative cooling

Modelling and experimental verification of a solar-powered liquid desiccant cooling system for greenhouse food production in hot climates

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