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20141106070805.8 |
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140228s2014 enka ob 001 0 eng |
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|a 2014006422
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|a 9781118707074 (electronic bk. : Adobe PDF )
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|a 1118707079 (electronic bk. : Adobe PDF )
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|z 9781118707081 (ePub )
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|z 1118707087 (ePub )
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|z 9781118352243 (cloth)
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|a 9781118707050 (electronic bk.)
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|a 1118707052 (electronic bk.)
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|a 1118352246
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|a 9781118352243
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|a 9781306426954 (MyiLibrary)
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|a 1306426952 (MyiLibrary)
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|a (DLC)EBC1629348
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|a NhCcYBP
|c NhCcYBP
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|b .E428 2014
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|x 014000
|2 bisacsh
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|a 697/.78
|2 23
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|a Eicker, Ursula,
|e author.
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1 |
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|a Energy efficient buildings with solar and geothermal resources /
|c Ursula Eicker.
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| 264 |
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1 |
|a Chichester, West Sussex, United Kingdom :
|b Wiley,
|c 2014.
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| 300 |
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|a 1 online resource (x, 593 pages)
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| 336 |
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|a text
|b txt
|2 rdacontent
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| 337 |
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|a computer
|b c
|2 rdamedia
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| 338 |
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|a online resource
|b cr
|2 rdacarrier
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| 533 |
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|a Electronic reproduction.
|b Perth, W.A.
|n Available via World Wide Web.
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| 588 |
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|a Description based on online resource; title from digital title page (viewed on June 23, 2014).
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| 505 |
0 |
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|a Machine generated contents note:
|g 1.1.
|t Residential buildings --
|g 1.2.
|t Office and administrative buildings --
|g 1.3.
|t Air conditioning --
|g 1.4.
|t Lighting electricity consumption --
|g 1.5.
|t Influence of the urban form on energy consumption of buildings --
|g 1.6.
|t Office buildings in an urban context --
|g 1.7.
|t Residential buildings in an urban context --
|g 1.8.
|t Site density effect --
|g 1.9.
|t Climate effect --
|g 1.10.
|t Albedo effects --
|g 1.11.
|t Thermal properties of the building envelope --
|g 1.12.
|t Solar gains and glazing --
|g 1.13.
|t Building typology and urban form --
|g 1.14.
|t Conclusions --
|t References --
|t Part A: Passive solar --
|g 2.1.
|t Passive solar use by glazing --
|g 2.2.
|t Transparent thermal insulation (TTI) --
|g 2.3.
|t Heat storage by interior building elements --
|t Part B: Natural ventilation --
|g 2.4.
|t Analytical methods for volume-flow calculations --
|g 2.5.
|t Air flow network simulations --
|g 2.6.
|t Ventilation potentials --
|g 2.7.
|t Thermal comfort and energy savings in office rooms with controlled natural ventilation --
|g 2.8.
|t Weekly simulations with dynamic boundary conditions --
|g 2.9.
|t Natural single-sided ventilation with sliding windows --
|g 2.10.
|t Annual simulations --
|t Part C: Daylighting of buildings --
|g 2.11.
|t Luminance and illuminance --
|g 2.12.
|t Visual performance and quality of lighting --
|g 2.13.
|t Light measurements --
|g 2.14.
|t Sky luminous intensity models --
|g 2.15.
|t Daylight distribution in interior spaces --
|g 2.16.
|t Calculation of daylight availability in buildings --
|g 2.17.
|t Standardisation and calculation methods --
|g 2.18.
|t Determination of needed artificial light sources --
|t References --
|g 3.1.
|t Extra-terrestrial solar irradiance --
|g 3.2.
|t Sun-Earth geometry --
|g 3.3.
|t Equator coordinates --
|g 3.4.
|t Horizon coordinates --
|g 3.5.
|t Atmospheric transmission and spectral irradiance --
|g 3.6.
|t Statistical production of hourly irradiance data records --
|g 3.7.
|t Global irradiance and irradiance on inclined surfaces --
|g 3.8.
|t Shading --
|g 3.9.
|t Temperature time series modelling --
|g 3.10.
|t Geothermal resource --
|t References --
|g 4.1.
|t Markets and economics --
|g 4.2.
|t System overview --
|g 4.3.
|t Systems engineering --
|g 4.4.
|t Large solar plants for heating drinking water with short-term stores --
|g 4.5.
|t Solar district heating --
|g 4.6.
|t Modelling of thermal collectors --
|g 4.7.
|t Storage modelling --
|g 4.8.
|t Solar air collectors --
|g 4.9.
|t Calculation of the available thermal power of solar air collectors --
|g 4.10.
|t Design of the air circuit --
|t References --
|g 5.1.
|t Introduction to the technologies --
|g 5.2.
|t Technology trends --
|g 5.3.
|t absorption cooling process and its components --
|g 5.4.
|t Components of absorption chillers --
|g 5.5.
|t Physical principles of the absorption process --
|g 5.6.
|t Energy balances and performance figures of an absorption chiller --
|g 5.7.
|t Static absorption cooling model --
|g 5.8.
|t Parameter identification for the static absorption cooling machine model --
|g 5.9.
|t Open cycle desiccant cooling --
|g 5.10.
|t Physical and technological bases of sorption-supported air conditioning --
|g 5.11.
|t technology of heat recovery --
|g 5.12.
|t Technology humidifier --
|g 5.13.
|t Design limits and climatic boundary conditions --
|g 5.14.
|t Energy balance of sorption-supported air conditioning --
|g 5.15.
|t Closed cycle adsorption cooling --
|g 5.16.
|t Heat rejection and auxiliary electricity consumption --
|t References --
|g 6.1.
|t Direct geothermal energy use for cooling and preheating of buildings --
|g 6.2.
|t Indirect geothermal energy use --
|g 6.3.
|t Geothermal heat exchangers for chiller heat rejection --
|g 6.4.
|t Modeling of geothermal heat exchangers --
|g 6.5.
|t Economics of geothermal heat exchangers --
|g 6.6.
|t Performance summary on geothermal heat exchangers --
|t References --
|g 7.1.
|t Structure of grid-connected systems --
|g 7.2.
|t Solar cell technologies --
|g 7.3.
|t Module technology --
|g 7.4.
|t Building integration and costs --
|g 7.5.
|t Energy production and the performance ratio of PV systems --
|g 7.6.
|t Physical fundamentals of solar electricity production --
|g 7.7.
|t Current-voltage characteristics --
|g 7.8.
|t PV performance with shading --
|g 7.9.
|t Simple temperature model for PV modules --
|g 7.10.
|t Systems engineering --
|t References --
|g 8.1.
|t Overview of heat pump and chiller technologies --
|g 8.2.
|t Energy efficiency of heat pumps and chillers --
|g 8.3.
|t Heat pump and compression chiller modelling --
|g 8.4.
|t Case studies for photovoltaic compression versus thermal cooling --
|g 8.5.
|t Conclusions on case studies for photovoltaic and thermal cooling --
|t References --
|g 9.1.
|t Empirical thermal model of building-integrated photovoltaic --
|g 9.2.
|t Energy balance and stationary thermal model of ventilated double facades --
|g 9.3.
|t Heat transfer coefficients for the interior and facade air gap --
|g 9.4.
|t Building-integrated solar components (U and g values) --
|g 9.5.
|t Warm-air generation by photovoltaic facades --
|g 9.6.
|t Photovoltaic thermal collectors for heating and cooling generation --
|t References.
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| 504 |
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|a Includes bibliographical references and index.
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| 650 |
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0 |
|a Sustainable buildings.
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| 650 |
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0 |
|a Solar buildings.
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| 650 |
|
0 |
|a Geothermal space heating.
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| 650 |
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0 |
|a Air conditioning
|x Energy conservation.
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| 650 |
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0 |
|a Heating
|x Energy conservation.
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| 710 |
2 |
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|a Ebooks Corporation
|
| 776 |
0 |
8 |
|i Print version:
|a Eicker, Ursula.
|t Energy efficient buildings with solar and geothermal resources
|d Chichester, West Sussex, United Kingdom : John Wiley & Sons Inc., 2014
|z 9781118352243
|w (DLC) 2013049419
|
| 856 |
4 |
0 |
|u https://ebookcentral.proquest.com/lib/santaclara/detail.action?docID=1629348
|z Connect to this title online (unlimited simultaneous users allowed; 325 uses per year)
|t 1
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