POTENTIAL USE OF PHASE CHANGE MATERIALS IN GREENHOUSES HEATING: COMPARISON WITH A TRADITIONAL SYSTEM

In order to use solar radiation as thermal energy source, heat storage equipments result necessary in each application where continuous supply is required, because of the natural unsteady intensity of radiation during the day. Thermal solar collectors are especially suitable for low temperature appl...

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Bibliographic Details
Published in:Journal of agricultural engineering (Pisa, Italy) Italy), 2009-09, Vol.40 (3), p.25-32
Main Authors: Caprara, Claudio, Stoppiello, Giovanni
Format: Article
Language:English
Subjects:
Coils
Computational fluid dynamics
Computer applications
Demand
Energy demand
Energy sources
Energy storage
Enthalpy
Fluid flow
Fluids
Greenhouses
Heat
Heat exchange
Heat storage
Heat transfer
Heat transport
Heating
Inlet temperature
Latent heat
Low temperature
Melt temperature
Phase change materials
Rectangular plates
Sensible heat
Sodium sulfate
Solar collectors
Solar energy
Solar panels
Solar power
Solar radiation
Steady state models
Storage tanks
Temperature requirements
Thermal energy
thermal energy storage, phase change materials, heat exchange, greenhouse heating, thermal solar collectors
Water tanks
Water temperature
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Summary:In order to use solar radiation as thermal energy source, heat storage equipments result necessary in each application where continuous supply is required, because of the natural unsteady intensity of radiation during the day. Thermal solar collectors are especially suitable for low temperature applications, since their efficiency decreases when an high inlet temperature of fluid flowing through them is established. On the other hand, low temperatures and low temperature gaps, above all, make very difficult to use traditional sensible heat storing units (water tanks), because of the very large amounts of material required. In this work, a traditional sensible heat storage system is compared with a latent heat storing unit based on phase change materials (PCMs). As a case study, a 840 m3 greenhouse heating application was considered with an inside constant temperature of 18°C. It is thought to be heated by using single layer plate thermal solar collectors as energy source. Inlet temperature of the collectors fluid (HTF) was fixed at 35°C (little higher than melting temperature of PCMs) and a constant flux of 12 l/m2 hour was established as technical usual value. At these conditions, 215m2 solar panels exposed surface resulted necessary. The sensible heat storage system considered here is a traditional water tank storing unit equipped with two pipe coils, respectively for heat exchanges with HTF from collectors and water flux for greenhouse heating. Available DT for heat exchange is estimated as the difference of minimum HTF temperature (in outlet from the collectors) and the required water temperature for greenhouse heating. The latent heat storing unit is instead a series of copper rectangular plate shells which a phase change material is filled in (Na2SO4⋅10H2O). Heat transfer fluids flow through thin channels between adjacent plates, so that a large heat exchange available surface is achieved. The developed computational model (Labview software) permits to superimpose heat exchanges daily curves between heat storing materials and heat transport fluids (for both of the fluids and the heat storing equipments) on the energy supply/demand ones, respectively calculated on the basis of greenhouse energy demand and solar collectors dimensions, characteristics and efficiency. In this manner, units design is achieved by changing thermal energy storing units dimensions, in order that the corresponding heat exchange curves coincide with the previously calculated on
ISSN:1974-7071
2239-6268
DOI:10.4081/jae.2009.3.25