Mathematical Model of Greenhouse Radiant Heating

The paper presents a methodology for calculating greenhouse radiant heating with regard to radiant heat transfer between the soil surface and greenhouse walls, multiple processes of heat reflection and self-irradiation, and mass transfer processes. Balance equations are obtained for heat and mass transfer between the greenhouse and soil surface and the heat transfer in greenhouse walls. The paper gives calculation formulae for determining certain elements of heat and mass balance equations. Joint numerical solution of these equations is required for calculating main indices of greenhouse radiant heating.

лучистое отопление, тепловой баланс, материальный баланс, теплица, инфракрасный излучатель, почва, radiant heating, heat balance, mass balance, greenhouse, infrared emitter, soil

1. Ivanov S.A., Kvyatkovskaya I.Yu., Dorokhov A.F., Shishkin N.D. Model' sistemy upravleniya kombinirovannym otopleniem teplitsy v usloviyakh zakrytogo grunta na baze mikrokontrollera Raspberry Pi [Model of the system of control of the combined heating of the greenhouse in conditions of the covered area based on the microcontroller Raspberry Pi]. Vestnik of Astrakhan State Technical University. 2015. No. 2. Pp. 32–37. (rus)

2. Bakanova S.V., Garina A.A. Vozdushnoe otoplenie teplits [Air heating greenhouses]. Proc. 15th Int. Sci. Conf. ‘Problems of Energy Saving in Industrial and Housing Utility Complexes’. Penza: Privolzhskii Dom znanii, 2014. Pp. 41–43. (rus)

3. Kubis V.A., Bakanova S.V., Eremkin A.I., Orlova N.A. Otsenka effektivnosti sistemy vozdushnogo otopleniya v teplitse [Efficiency estimation of air heating systems in greenhouses]. Gradostroitel'stvo i arkhitektura. 2014. No. 2 (15). Pp. 94–98. (rus)

4. Usanov A.Yu., Nikitina E.N. Construction algorithm of choice resource-saving technologies in vegetable protected ground. Proc. 1st Int. Conf. ‘Prospect Development of Innovative Economy’. Los Gatos, USA, 2016. Pp. 41–46.

5. Oleinichenko V.G., Velichko V.V. Vozdushnaya sistema otopleniya i konditsionirovaniya teplits s ispol'zovaniem geotermal'nogo istochnika energii [Air heating system and air-conditioning of greenhouses using geothermal energy source]. Mezhdunarodnyi nauchnyi zhurnal al'ternativnaya energetika i ekologiya. 2012. No. 7. Pp. 84–87. (rus)

6. Kubis V.A., Gudasheva E.S. Mnogofunktsional'naya energoeffektivnaya teplitsa dlya lichnykh podsobnykh khozyaistv [Multi-energy efficient for greenhouse smallholdings]. Proc. 15th Int. Sci. Conf. ‘Problems of Energy Saving in Industrial and Housing Utility Complexes’. Penza: Privolzhskii Dom znanii, 2014. Pp. 143–148. (rus)

7. NJ greenhouses bloom with radiant heating. Engineered Systems. Laguna Hills (CA), USA, 1999. V. 16. No. 1. Pp. 32–33.

8. Shiyanova N.I., Afanas'ev P.S. Infrakrasnaya sistema otopleniya dlya teplits [Infrared heating system for greenhouses]. Proc. Int. Sci. Conf. ‘Import substitution of Agro-Industrial Complex as a Basis of National Food Security’. Meleuz: BITU Publ., 2016. Pp. 142–147. (rus)

9. Khalimov A.G., Khairiddinov B.E., Kim V.D., Khalimov G.G. Modeling the heat balance of a solar greenhouse with a passive heat accumulator. Applied Solar Energy. New York, USA, Allerton Press, Inc., 2013. V. 49. No. 4. Pp. 211–214.

10. Bolotskikh N.N. Infrakrasnyi obogrev teplits s pomoshch'yu elektricheskikh dlinnovolnovykh nagrevatel'nykh panelei [Infrared heating of hothouses provided by electric long-wave heater panels]. Energosberezhenie. Energetika. Energoaudit. 2015. No. 9 (140). Pp. 43–52. (rus)