Solar Thermal Heating. Eicker, U. In Energy Efficient Buildings with Solar and Geothermal Resources, pages 203–296. John Wiley & Sons, Ltd, 2014.
Paper doi abstract bibtex Using primary solar energy for thermal heating is a logical application in buildings. However, efficient use of this energy source requires careful consideration and planning. The fourth chapter introduces all the different aspects involved, including the engineering and components, system design for decentral or district solar thermal heating and domestic hot water systems, storage as well as the economic repercussions.
@incollection{eicker_solar_2014,
title = {Solar {Thermal} {Heating}},
copyright = {© 2014 John Wiley \& Sons Ltd},
isbn = {978-1-118-70705-0},
url = {http://onlinelibrary.wiley.com/doi/10.1002/9781118707050.ch4/summary},
abstract = {Using primary solar energy for thermal heating is a logical application in buildings. However, efficient use of this energy source requires careful consideration and planning. The fourth chapter introduces all the different aspects involved, including the engineering and components, system design for decentral or district solar thermal heating and domestic hot water systems, storage as well as the economic repercussions.},
language = {en},
urldate = {2017-12-22TZ},
booktitle = {Energy {Efficient} {Buildings} with {Solar} and {Geothermal} {Resources}},
publisher = {John Wiley \& Sons, Ltd},
author = {Eicker, Ursula},
year = {2014},
doi = {10.1002/9781118707050.ch4},
keywords = {CPC reflector, Fresnel collectors, Fresnel formulae, Nußelt correlation, Prandtl number, Reynolds number, Rib efficiency, Stefan-Boltzmann constant, Trombe wall, absorption coefficient, air circuit, air collectors, air properties, antifreeze, auxiliary heating, circulation losses, collector efficiency equation, collector efficiency factor, convective heat transfer, corrosion, cover material, district heating, domestic hot water, expansion vessel, extinction coefficient, flat plate collectors, forced convection by wind, fresh water station, heat dissipation factor, heat storage, heat transfer, heating support, laminar flow, mixed-air, one node dynamic collector model, parabolic concentrating collectors, perpendicular irradiance, plane of incidence, pumping height, radiation exchange, refractive index, selective coating, sky temperature, solar air collectors, solar circuit hydraulics, solar collector, solar pool heating, solar thermal system costs, specific warm-water consumption, standing air layer, steady state collector model, storage modelling, temperature distribution absorber, thermal expansion, thermal intake length, transparent covers, turbulent flow, vacuum tube collectors, volume expansion coefficient},
pages = {203--296}
}
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