The Use Of Cell Polyurethane Foams In Air-Type Solar Collectors As The Heat Absorbing Element için kapak resmi
The Use Of Cell Polyurethane Foams In Air-Type Solar Collectors As The Heat Absorbing Element
Başlık:
The Use Of Cell Polyurethane Foams In Air-Type Solar Collectors As The Heat Absorbing Element
Yazar:
Değirmencioğlu, Can.
Yazar Ek Girişi:
Yayın Bilgileri:
[s.l.]: [s.n.], 2006.
Fiziksel Tanımlama:
xiv, 109 leaves.: ill.+ 1 computer laser optical disc.
Genel Not:
Keywords: Solar energy, solar collectors, solar energy systems, air heating, polyurethane foam.
Özet:
After the energy crisis in early 1970.s, the priority of alternative energy resources is expanded. There have been many researches, to increase the efficiency of solar energy utilization systems, for domestic and industrial usage since early 1980.s up to now. In many fields air-type solar collectors are applicable. They generally used in food industry to dry agricultural products, textile industry to dry fabrics and space heating. Drying grains (wheat, barley, maize, etc.), fruits (grape, fig, apricot etc.), vegetables, tea are examples for food industry. Greenhouse heating and hospital heating to obtain fresh air are examples of space heating. These examples show that improving their performance is indispensable for commercial acceptance. In this study, the open-cell polyurethane foam as an absorber material, placed in a south facing, flat plate air-type solar collector at fixed tilt angle and effect of this material on collector efficiency has been investigated. The collector designed specially, in order to get maximum heat gain from the useful solar intensity falling on the glazing and insulated to loose minimum heat from collector case and transfer channels. Collector is tested under the regulations of ASHRAE 93-1986 standard named .Methods of Testing to Determine The Thermal Performance of Solar Collectors.. Air passing through the collector has been provided by a fan. Tests are repeated with three air speeds 1.266 m/s, 1.5825 m/s and 1.899 m/s. Maximum average efficiency is calculated on 1.5825 m/s. Maximum average temperature difference of air between inlet and outlet sections observed on 1.266 m/s. Maximum outlet temperature that we get is on the same day with maximum average temperature difference.
Yazar Ek Girişi:
Tek Biçim Eser Adı:
Thesis (Master)--İzmir Institute of Technology: Energy Engineering.

İzmir Institute of Technology: Energy Engineering--Thesis (Master).
Elektronik Erişim:
Access to Electronic Version.
Ayırtma: Copies: