LEADER 01268nam a2200325 i 4500 001 991000821109707536 005 20020507174018.0 008 960321s1982 ne ||| | eng 020 $a0444861971 035 $ab10761822-39ule_inst 035 $aLE01302818$9ExL 040 $aDip.to Matematica$beng 082 0 $a516.36 084 $aAMS 53-06 084 $aAMS 53-XX 100 1 $aSoós, Gy$0535150 245 10$aDifferential geometry /$cedited by Gy. Soós and J. Szenthe 260 $aAmsterdam :$bJános Bolyai Math. Soc.,$c1982 300 $a829 p. :$bill. ;$c25 cm. 490 0 $aColloquia mathematica Societatis Janos Bolyai, ISSN 01393383 ;$v31 500 $aIncludes bibliographies. 500 $aPapers presented at a Colloquium on Differential Geometry, Budapest, Sept. 3-7, 1979, which was organized by the János Bolyai Mathematical Society 650 4$aDifferential geometry$xCongresses 700 1 $aSzenthe, Janos 907 $a.b10761822$b23-02-17$c28-06-02 912 $a991000821109707536 945 $aLE013 53-XX SOO11 (1982)$g1$i2013000043999$lle013$o-$pE0.00$q-$rl$s- $t0$u0$v0$w0$x0$y.i10857126$z28-06-02 996 $aDifferential geometry$9923101 997 $aUNISALENTO 998 $ale013$b01-01-96$cm$da $e-$feng$gne $h0$i1 LEADER 07587nam 22006253u 450 001 9910566452703321 005 20250628110034.0 010 $a3-030-97556-8 035 $a(CKB)5700000000082622 035 $aEBL6963491 035 $a(AU-PeEL)EBL6963491 035 $a(MiAaPQ)EBC6963491 035 $a(oapen)https://directory.doabooks.org/handle/20.500.12854/81689 035 $a(PPN)262170418 035 $a(ODN)ODN0010067105 035 $a(Au-PeEL)EBL6963491 035 $a(OCoLC)1313607053 035 $a(oapen)doab81689 035 $a(EXLCZ)995700000000082622 100 $a20250630d2022 uy 0 101 0 $aeng 135 $aur|n|---||||| 181 $ctxt$2rdacontent 182 $cc$2rdamedia 183 $acr$2rdacarrier 200 10$aAssessment of energy-efficient building details for seismic regions /$fBoris Azinovic?, Vojko Kilar, David Koren 205 $a1st ed. 210 $aCham $cSpringer International Publishing AG$d2022 215 $a1 online resource (214 p.) $cillustrations (chiefly color) 225 1 $aSpringer tracts in civil engineering 300 $aDescription based upon print version of record. 311 1 $a3-030-97555-X 327 $aIntro -- Preface -- Contents -- 1 Introduction -- References -- 2 Design of the Thermal Insulation Envelope of Energy-Efficient Buildings -- 2.1 »L« Type Structural Assembly Connections -- 2.2 »T« Type Structural Assembly Connections -- 2.3 »+« Type Structural Assembly Connections -- References -- 3 Structural Details in Energy-Efficient Buildings -- 3.1 Foundations on the Thermal Insulation Layer -- 3.1.1 Possible Solutions for Foundations on Thermal Insulation -- 3.1.2 Specifics of Designing Thermally Insulated Foundation Slabs in Non-earthquake-Prone Areas -- 3.1.3 Influence of the Flexible Layer of Thermal Insulation on the Seismic Response of a Building -- 3.2 Base Insulation Blocks for Preventing Thermal Bridges in Walls in Contact with Cold Elements -- 3.2.1 Types of Base Insulation Blocks -- 3.2.2 Influence of Base Insulation Blocks on Better Environmental and Energy-Efficiency Parameters -- 3.2.3 Base Insulation Blocks as Parts of Masonry Structures for Bearing Vertical Static Loads -- 3.3 Details for Preventing Thermal Bridges in Cantilever Structures -- 3.3.1 Precast Element Solutions for Thermal Bridges in Cantilever Structures -- 3.3.2 Comparison of the Environmental and Energy-Efficiency Parameters of an Insulated and Uninsulated Reinforced Concrete Cantilever Slab -- 3.3.3 Selection Principles of Precast Load-Bearing Thermal Insulation Elements Subject to Vertical Static Loads -- 3.4 Building Connection Detail Between the Roof and Outer Wall -- 3.4.1 Environmental and Energy-Efficiency Aspects of the Building Connection Detail Between the Roof and an Outer Wall -- References -- 4 Evaluation of Critical Structural Assemblies -- 4.1 Detail Evaluation Methodology for Energy-Efficient Buildings -- 4.1.1 Importance of Environmental and Energy-Efficiency Parameters -- 4.1.2 Importance of Technical and Structural Parameters. 327 $a4.1.3 Importance of External Parameters -- 4.2 Environmental and Energy-Efficiency Parameters -- 4.2.1 Thermal Transmittance of Structural Assemblies (E1) -- 4.2.2 Continuity of Thermal Insulation (E2) -- 4.2.3 Condensation and Thermal Comfort (E3) -- 4.2.4 Influence on the Use of Energy (E4) -- 4.2.5 Airtightness (E5) -- 4.2.6 Life Cycle Assessment (E6) -- 4.2.7 Durability and Sustainability (E7) -- 4.3 Technical and Structural Parameters -- 4.3.1 Load-Bearing Capacity (K1) -- 4.3.2 Minimum Dimensions and Stiffness (K2) -- 4.3.3 Symmetry (K3) -- 4.3.4 Continuity or Uniformity of the Load-Bearing Structure (K4) -- 4.3.5 Eccentricity or a Shift in the Structure According to the Primary Load-Bearing Axis (K5) -- 4.3.6 Capacity Design Method (K6) -- 4.3.7 Connections of Primary and Secondary (Non-)Load-Bearing Elements (K7) -- 4.4 External Parameters -- 4.4.1 Location (Z1) -- 4.4.2 Importance of a Building (Z2) -- 4.4.3 Influence on the Global Analysis (Z3) -- 4.4.4 Complexity of Construction (Z4) -- 4.4.5 Penetrations and Openings (Z5) -- 4.4.6 Economic Aspect (Z6) -- 4.5 Assessment Based on Evaluation Parameters, Weighting Factors and External Parameters -- 4.6 Presentation of the Results -- References -- 5 Case Study: Using Methodology to Assess the Selected Details -- 5.1 Building Connection Detail Between an Outer Wall and the Foundation Slab -- 5.2 Building Connection Detail Between the Load-Bearing Balcony Structure and an Outer Wall -- 5.3 Building Connection Detail Between an Outer Wall and the Unheated Basement -- 5.4 Building Connection Detail Between an Outer Wall and the Roof -- References -- 6 Conclusions -- References -- Appendix Examples of the Use of the Methodology for Evaluating Structural Details. 330 $aThis open access book presents a methodology for the assessment of structural building details, taking into account the contemporary guidelines for earthquake-resistant and energy-efficient buildings. A review of structural details for energy-efficient buildings revealed that in some cases the structural system is interrupted, leading to solutions which are not suitable for earthquake-prone regions. Such typical examples would be the use of thermal insulation under the building foundation and reduction of the load-bearing elements? dimensions ? also at the potential locations of plastic hinges which are crucial for the dissipation of seismic energy. The proposed methodology of assessment favours a collaboration of architects, engineers, contractors and investors in the early stage of building design. By this the methodology enables efficient decision-making and contributes to a selection of optimal building structural details. The book starts by presenting the typical structural details of the thermal envelope of energy-efficient buildings together with the scientific background required for understanding the process of detail development from all the relevant aspects. Over 20 examples of most frequent details are described and analysed to raise awareness of the importance of earthquake resistance, sustainability, energy-efficiency and thermal comfort for users 410 0$aSpringer tracts in civil engineering 606 $aArchitecture and energy conservation 606 $aBuildings$xEarthquake effects 606 $aEarthquake resistant design 606 $aSustainable buildings 615 0$aArchitecture and energy conservation. 615 0$aBuildings$xEarthquake effects. 615 0$aEarthquake resistant design. 615 0$aSustainable buildings. 686 $aARC018000$aSCI019000$aTEC031010$2bisacsh 700 $aAzinovi?$b Boris$01237359 701 $aKilar$b Vojko$01237360 701 $aKoren$b David$01237361 801 0$bAU-PeEL 801 1$bAU-PeEL 801 2$bAU-PeEL 906 $aBOOK 912 $a9910566452703321 996 $aAssessment of Energy-Efficient Building Details for Seismic Regions$92872415 997 $aUNINA