On the cooler machine power heat, performance machine efficiency (COP-Coefficient of Performance) is
affected by adsorber capacity in adsorbing numbered refrigerant and releasing in fast periode. the velocity will
increase if it has velocity transfered heat and high mass.
This research focused on knowing variation effect adsorbed of solid porousity adsorber versus head transfer rate
and high mass. Research methods used many relevance references.
The result of this research is that more increasing porousity volume caused high rate of mass transferred
and high heat. Yet if to many porousity made volume of adsorber smaller so that mass transferred achieve optimum
and decreased.

Aidoun Z, dan Ternan M. 2002. Salt impregnated carbon fibres as the reactive medium in a chemical heat

pump: the NH3–CoCl2 system. Appl Therm Eng;22:1163–73.

Critoph RE, Metcalf SJ. 2004. Specific cooling power intensification limits in ammonia–carbon

adsorption refrigeration systems. Appl Therm Eng;24(5–6):661–78.

Critoph, R.E. 1988. Performance limitations of adsorption cycles for solar cooling, Solar Energy 41 ; 21–

Dai Y.J., R.Z. Wang, Y.X. Xu. 2002. Study of a solar powered solid adsorption–desiccant cooling system

used for grain storage. Renewable Energy 25. hal 417–430.

Dieng A.O., dan Wang R.Z., 2001. Literature review on solar adsorption technologies for icemaking and

air-conditioning purposes and recent developments in solar technology, Renewable &

Sustainable Energy Reviews 5 (4) hal. 313–342.

Hartmann, N., Glueck, C., Schmidt, F.P., 2011. Solar cooling for small office buildings: Comparison of

solar thermal and photovoltaic options for two different European climates. Renewable Energy

pg. 1329-1338.

Henning H-M. 2007. Solar assisted air conditioning of buildings - an overview. Applied Thermal

Engineering;27:1734-49

Hidayat, Syarif. 2011. Sifat Thermal Bahan. Jakarta : Pusat Pengembangan Bahan Ajar Universitas

Mercubuana

Hussein, W.K.S., 2008. Solar Energy Refrigeration by Liquid-Solid Adsorption Technique, Master Thesis,

An-Najah University, Palestine.

Kaczmarski, K. dan Bellot, J. Ch., 2003. Effect Of Particle-Size Distribution and Particle Porosity

Changes on Mass-Transfer Kinetics. Acta Chromatographica, No. 13.

Kato Y, Yamada M, Kanie T, Yoshizawa Y. 2001. Calcium oxide/carbon dioxide reactivity in a packed

bed reactor of a chemical heat pump for high-temperature gas reactors. Nucl Eng Des;210:1–8.

Li Z.F., dan Sumathy, K. 1999. A solar powered ice-maker with the solid adsorption pair of activated

carbon and methanol, International Journal of Energy Research 23 (6) ; 517–527.

Li, G., Hwang, Y., Radermacher, R., 2012. Review of cold storage materials for air conditioning

application, International Journal of Refrigeration, doi: 10.1016/j.ijrefrig.2012.06.003.

Li, M, Huang, H.B., Wang, R.Z., Wang, L.L., Cai, W.D., Yang, W.M. 2004b. Experimental study on

adsorber of activated carbon with refrigerant of methanol and ethanol for Solar Ice Maker.

Renewable Energy 29. hal 2235–2244.

Li, M, Sun, C.J., Wang,R.Z. dan Cai, W.D. 2004a. Development of no valve Solar Ice Maker. Applied

Thermal Engineering 24. hal 865–872.

Maggio G, L.G. Gordeeva, A. Freni, Yu.I. Aristov, G. Santori, F. Polonara, G. Restuccia. 2009.

Simulation of a solid sorption ice-maker based on the novel composite sorbent ‘‘lithium

chloride in silica gel pores”. Applied Thermal Engineering 29 hal. 1714–1720.

Ponec V, Knor Z, Cerny S. 1974. Adsorption on solids. London, England: Butterworth Group;.

Pons, M. dan Guillemiont, J.J. 1986. Design of an experimental solar-powered, solid-adsorption ice

maker, Trans. ASME, J. Solar Energy Eng. 108 (4) ; 332–337.

Saha BB, Akisawa A, Kashiwagi T. 2001. Solar/waste heat driven two-stage adsorption chiller: the

prototype. Renew Energy;23(1):93–101.

Sudibandriyo. M, Lydia. 2011. Karakteristik Luas Permukaan Karbon Aktif Dari Ampas Tebu dengan

Aktivasi Kimia. Jakarta : Universitas Indonesia.

Wang K, Wu JY, Wang RZ,Wang LW. 2006. Effective thermal conductivity of expanded graphite–CaCl2

composite adsorber for chemical adsorption chillers. Energy Convers Manage;47(13–14):1902–

Wang LW, Wang RZ, Wu JY, Wang K. 2004. Compound adsorber for adsorption ice maker on fishing

boats. Int J Refrig;27:401–8.

Wang, L.W., Wang, R.Z., Oliveira, R.G., 2009. A review on adsorption working pairs for refrigeration.

Renewable and Sustainable Energy Reviews. 13(3), 518-534.

Widy, Stefano. 2012. Faktor yang Mempengaruhi Adsorpsi Hidrogen pada Karbon Aktif.

http://fannowidy.blogspot.com/2012/03/faktor-yang-mempengaruhi-adsorpsi.html. Diakses

pada tanggal 5 Juni 2013.

Widyastuti, A., Sitorus, B., Jayuska, A., 2013. Karbon Aktif Dari Limbah Cangkang Sawit Sebagai

Adsorben Gas Dalam Biogas Hasil Fermentasi Anaerobik Sampah Organik. JKK, tahun 2013,

volume 2 (1), halaman 30-33.

Zhai, X.Q., dan Wang, R.Z., 2009. A review for absorbtion and adsorbtion solar cooling systems in China.

Renewable and Sustainable Energy Reviews 13 hal 1523–1531

Zhang YH. 1989. Adsorption function. Shanghai, China: Publishing House of Scientific and

Technological Literature in Shanghai.