INCREASING THE WORKING EFFICIENCY OF SOLAR POWER ABSORPTION REFRIGERATOR UNITS

Objectives.The aim of the study is to develop a cyclic absorption refrigerator unit that implements technology for producing cold from solar radiation energy. Its distinctive feature comprises a highly developed solar receiving unit, consisting of two parallel-connected absorber generators whose reactors are installed in individual heat-insulated “hot box” cabinets.

Method. The geometric characteristics of the absorber generator are based on the calculations of the optical and heat energy efficiency of the device models.

Results. The physicochemical characteristics of activated carbons (AC) of various production are studied. The absorption capacity of the following working pairs is determined: AC-ammonia, AC-methylamine, AC-ethylamine. The calculated coefficients for the Dubinin-Radushkevich structural equations are obtained. An experimental solar energy refrigerator unit is tested using a working pair of AC-ammonia in an open test area. The operability of the upgraded device is proven. Exergetic coefficient dependencies are determined according to the developed software algorithm based on a simplified thermodynamic cycle. The areas of possible application and use of solar power refrigerator units with the studied working pairs are determined.

Conclusion. The increased unit efficiency consists in the optimal layout of all elements of the absorber generator, including the reactor, two flat mirror concentrators, a thermal substrate, a reduced internal air space volume, a double-glazed window made of two sheets of glass and a calculated thickness of heat-insulating Ripor foamed polyurethane. 

1. Rudenko M.F. Kontseptsiya razvitiya ekologicheski bezopasnoy gelioenergeticheskoy tekhniki dlya proizvodstva tepla i kholoda // Bezopasnost' zhiznedeyatel'nosti. 2006. №10. S.46-50. [Rudenko M.F. The concept of development of environmentally friendly solar energy technology for the production of heat and cold // Life safety. 2006. No. 10. pp.46-50. (In Russ)]

2. Rudenko, M.F. Adsorbtsionnyye svoystva aktivnogo uglya dlya geliokholodil'nykh ustanovok / M.F. Rudenko, I.A.Palagina, ZH.A.Anikhuvi, S.V.Zolotokopova // Khimicheskoye i neftegazovoye mashinostroyeniye. 1999. №12. S.22-23. [Rudenko, M.F. Adsorption properties of activated carbon for solar refrigeration units / M.F. Rudenko, I.A. Palagina, J.A. Anihuvi, S.V. Zolotokopova // Chemical and oil and gas engineering. 1999. No. 12. pp.22-23. (In Russ)]

3. Rudenko, M.F. Razrabotka i issledovaniye effektivnosti ekologicheski bezopasnoy adsorbtsionnoy geliokholodil'noy ustanovki / M.F. Rudenko, YU.V. Chivilenko, V.I. Cherkasov // Khimicheskoye i neftegazovoye mashinostroyeniye. 2006. №8. S.26-28. [Rudenko, M.F. Development and study of the effectiveness of environmentally friendly adsorption solar refrigeration unit / M.F. Rudenko, Yu.V. Chivilenko, V.I. Cherkasov // Chemical and oil and gas engineering. 2006. No8. pp.26-28. (In Russ)]

4. Brites, G.J.V.N. Influence of the design parameters on the overall performance of a solar adsorption refrig-erator / G.J.V.N. Brites, J.J. Costa, V.A.F. Costa // Renewable Energy. 2016. Vol. 86.pp. 238-250

5. Pan, Q.W. Experimental investigation of an adsorption refrigeration prototype with the working pair of composite adsorbent-ammonia // Q.W. Pan, R.Z. Wang, Z.S. Lu, L.W. Wang // Applied Thermal Engineering. 2014. Vol. 72. pp. 275-282.

6. Patent RF № 2365676, S1 ot 27.08.2009. Elektrolit dlya osazhdeniya chernykh antikorrozionnykh oksidnykh pokrytiy na stal'. 2008. Byul.№24 [RF patent No. 2365676, C1 of 08.27.2009. Electrolyte for the deposition of black anticorrosive oxide coatings on steel. 2008. Bull.№24(In Russ)]

7. Rudenko, M.F. Effektivnost' geliopriyemnykh ustroystv s kontsentratorami dlya sistem teplo- i khladosnabzheniya / Saratov. Laboratoriya netraditsionnoy energetiki OEP SNTS RAN, 2001. 64 s. [Rudenko, M.F. Efficiency of solar receiving devices with concentrators for heat and cold supply systems / Saratov. Laboratory of Alternative Energy OEP SSC RAS, 2001. 64 p. (In Russ)]

8. Shipulina, YU.V. Metodika opredeleniya teplovykh nagruzok na reaktor generatora- adsorbera gelioenergeticheskoy kholodil'noy ustanovki / YU.V. Shipulina, M.SH. Karimov, M.F. Rudenko // Vestnik AGTU. Seriya: Morskaya tekhnika i tekhnologiya. 2013. No. 1. pp.148-154 [Shipulina, Yu.V. Methodology for determining thermal loads on the reactor of an adsorber generator of a solar energy refrigeration unit / Yu.V. Shipulina, M.Sh. Karimov, M.F. Rudenko // Bulletin of the ASTU. Series: Marine Engineering and Technology. 2013. No. 1. pp.148-154(In Russ)]

9. Rudenko, M.F. Opredeleniye fizicheskikh kharakteristik aktivnogo uglya dlya adsorbtsionnykh kholo-dil'nykh mashin / M.F. Rudenko, I.A. Palagina, ZH.A. Anikhuvi, S.V. Zolotokopova // Khimicheskoye i neftega-zovoye mashinostroyeniye. 2000. No.8. s. 39-40 [Rudenko, M.F. Determination of physical characteristics of activated carbon for adsorption refrigeration machines / M.F. Rudenko, I.A. Palagina, J.A. Anihuvi, S.V. Zolotokopova // Chemical and oil and gas engineering. 2000. No8. pp. 39-40. (In Russ)]

10. Wang, L.W. Solar driven air conditioning and refrigeration systems corresponding to various heating source temperatures // L.W. Wang, Z.Y.Xu, Q.W. Pan, S. Du, Z.Z.Xia. // Appl Energy. 2016.Vol. 169 pp. 846-856.

11. Xu, S.Z. Thermodynamic analysis of single-stage and multi-stage adsorption refrigeration cycles with acti-vated carbon – ammonia working pair / S.Z. Xu, L.W. Wang, R.Z. Wang // Energy Conversion and Management. 2016. Vol.117. pp. 31-42.

12. Shipulina, YU.V. Modelirovaniye termodinamicheskogo tsikla raboty adsorbtsionnogo gelioenerge-ticheskogo termotransformatora / YU.V. Shipulina, M.F. Rudenko // Vestnik AGTU. Morskaya tekhnika i tekhnologiya. 2011. No.3. s.136-140. [Shipulina, Yu.V. Modeling the thermodynamic cycle of the adsorption solar energy thermal transformer / Yu.V. Shipulina, M.F. Rudenko // Bulletin of the ASTU. Marine engineering and technology. 2011. No3. pp.136-140. (In Russ)]