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101 0 $aeng
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181   $ctxt
182   $cc
183   $acr
200 10$aBuilding Energy Performance Assessment in Southern Europe /$fby Simone Ferrari, Valentina Zanotto
205   $a1st ed. 2016.
210  1$aCham :$cSpringer International Publishing :$cImprint: Springer,$d2016.
215   $a1 online resource (135 p.)
225 1 $aPoliMI SpringerBriefs,$x2282-2577
300   $aDescription based upon print version of record.
311   $a3-319-24134-6 
320   $aIncludes bibliographical references at the end of each chapters.
327   $aPreface; Contents; 1 Building Envelope and Thermal Balance; Abstract; 1.1 Building Thermal Balance; 1.1.1 Heat Flow from Envelope; 1.1.2 Ventilation; 1.1.3 Internal Heat Sources; 1.1.4 Solar Gain Through the Transparent Elements; 1.2 Heat Transfer Through Building Elements; 1.2.1 Steady-State Analysis; 1.2.2 Transient Analysis; 1.2.2.1 Analysis Through Discretization; 1.2.2.2 Conduction Transfer Functions; 1.2.2.3 Periodic Analysis; 1.2.3 Steady-State Versus Transient Prediction; References; 2 Approximating Dynamic Thermal Behaviour of the Building Envelope; Abstract
327   $a2.1 Heat Transmittance Correction Values2.1.1 Mass Factor; 2.1.2 Effective U-Value; 2.2 Temperature Difference Correction Values; 2.2.1 Total Equivalent Temperature Differential (TETD); 2.2.2 Cooling Load Temperature Difference (CLTD); 2.2.3 Overall Thermal Transfer Value (OTTV); 2.2.4 Fictitious Ambient Temperature; 2.3 Applications; 2.3.1 M Factor; 2.3.2 CLTD; 2.3.3 FAT; 2.3.4 Lessons Learned; References; 3 Implications of the Assumptions in Assessing Building Thermal Balance; Abstract; 3.1 European Standard for Assessing the Building Thermal Behaviour
327   $a3.2 Comparison Between Simplified Method and Detailed Simulation3.2.1 Input Parameters Selection: The Effect on the Thermal Balance; 3.2.1.1 Set-Point Temperature; 3.2.1.2 Air-Change Rate; 3.2.1.3 Internal Loads; References; 4 Thermal Comfort Approaches and Building Performance; Abstract; 4.1 The Standard Approach; 4.2 The Adaptive Approach; 4.2.1 ASHRAE Equation; 4.2.2 ACA Equation; 4.2.3 ATG Equation; 4.2.4 CEN Equation; 4.3 Approaches Application on a Case Study; 4.4 Building Performance Implications; References; 5 Defining Representative Building Energy Models; Abstract
327   $a5.1 Definition of the Basis Building Model5.1.1 Building Shape; 5.1.2 Internal Heat Loads; 5.1.3 Air Change Rate; 5.2 Definition of the Characterizing Parameters; 5.2.1 Building Locations; 5.2.2 Building Constructions; 5.2.2.1 New Conventional; 5.2.2.2 New Glazed; 5.2.2.3 60/80 Conventional; 5.2.2.4 60/80 Sandwich Largely Glazed; 5.2.2.5 Traditional; References; 6 Energy Performance Analysis of Typical Buildings; Abstract; 6.1 The Set of the Simulations; 6.1.1 Passive Cooling Strategies; 6.1.1.1 Shading; 6.1.1.2 Night Ventilation; 6.1.2 Indoor Set-Point Temperature
327   $a6.2 Comparison of Buildings Performances6.2.1 Winter Week; 6.2.2 Summer Week, Basis; 6.2.3 Summer Week, with External Shading; 6.2.4 Summer Week, with Night Ventilation; 6.2.5 Summer Week, with External Shading and Night Ventilation; 6.3 Effect of a Climate-Connected Set-Point to the Seasonal Cooling Needs; References; 7 Climate-Related Assessment of Building Energy Needs; Abstract; 7.1 Assessing Building Energy Needs; 7.2 Climate-Related Analysis; 7.3 Data Sheets of the Case-Studies Results; References; 8 Buildings Performance Comparison: From Energy Need to Energy Consumption; Abstract
327   $a8.1 HVAC Systems and Primary Energy Consumption
330   $aThis book discusses the issues relevant to the evaluation of the thermal energy balance of buildings in southern Europe and equips readers to carry out optimal building energy-performance assessments taking into account the peculiarities of the climatic context. Evaluation of building energy performance in this region is complex, since the significant need for cooling means that the effect of thermal capacity, glazed surfaces and ventilation and shading strategies have to be carefully considered when determining the indoor operative temperatures. This is fully explained, and critical issues in the application of the commonly employed, simplified procedures and assumptions are identified. In addition to the theoretical analysis, there are case studies that explore the energy performances of a set of typical building typologies within the variability of the Italian climate, considered as representative of conditions in southern Europe. These descriptions will support energy consultants and other stakeholders in assessing building energy performances beyond the mere simplified standard assumptions. Furthermore, the numerous graphs and tables documenting data can be easily adopted to serve as design advice tools for both new constructions and retrofits.
410  0$aPoliMI SpringerBriefs,$x2282-2577
606   $aEnergy consumption
606   $aBuilding construction
606   $aThermodynamics
606   $aHeat engineering
606   $aHeat$xTransmission
606   $aMass transfer
606   $aEnergy Efficiency$3https://scigraph.springernature.com/ontologies/product-market-codes/118000
606   $aBuilding Physics, HVAC$3https://scigraph.springernature.com/ontologies/product-market-codes/T23080
606   $aEngineering Thermodynamics, Heat and Mass Transfer$3https://scigraph.springernature.com/ontologies/product-market-codes/T14000
615  0$aEnergy consumption.
615  0$aBuilding construction.
615  0$aThermodynamics.
615  0$aHeat engineering.
615  0$aHeat$xTransmission.
615  0$aMass transfer.
615 14$aEnergy Efficiency.
615 24$aBuilding Physics, HVAC.
615 24$aEngineering Thermodynamics, Heat and Mass Transfer.
676   $a696
700   $aFerrari$b Simone$4aut$4http://id.loc.gov/vocabulary/relators/aut$0312241
702   $aZanotto$b Valentina$4aut$4http://id.loc.gov/vocabulary/relators/aut
712 02$aPolitecnico di Milano.
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910253994203321
996   $aBuilding Energy Performance Assessment in Southern Europe$92089220
997   $aUNINA