| 000 | 02148nam a2200181Ia 4500 | ||
|---|---|---|---|
| 008 | 240829s9999 xx 000 0 und d | ||
| 082 |
_aMBEP TH-0108 _bZAK |
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| 100 |
_aZakai, Zoya (PBE22407) _998851 |
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| 245 | 0 | _aCorrelation between structural member's embodied carbon and energy with changing built-up area using LCA (Softcopy is also available) | |
| 260 | _c2024 | ||
| 300 | _axxii,67p. | ||
| 505 | _aTable Of Contents Abstract I Undertaking V Certificate Vii Acknowledgement Ix Table Of Contents Xi List Of Tables Xv List Of Figures Xvii Abbreviations Xxi 1. Introduction 1 1.1. Overview 1 1.2. Embodied Energy And Operational Energy 2 1.3. Distinction Between Energy And Carbon In The Context Of Embodied And Operational Emissions 3 1.4. Component Wise Contribution To Embodied Energy And Embodied Carbon In Rc Buildings 3 1.5. Gap In Practice And Motivation 4 1.6. Research Objective 5 2. Literature Review 7 2.1. Embodied Energy And Embodied Carbon Values For Varying Built-Up Areas 7 2.2. Lca Database -Emission Coefficients For Embodied Energy And Embodied Carbon 8 2.3. Energy Consumption In Cement And Steel Manufacturing 11 2.4. Energy Consumption In Transportation Of Building Materials 13 2.5. Co-Relation Analysis 14 3. Research Methodology 15 3.1. Research Question 15 3.2. Objective: 15 3.3. Planning Norms For Ahmedabad, Gujrat 15 3.4. Building For Study And Rationale For Selection: 17 3.5. Scope And Limitations Of Work : 19 3.6. Structural Quantities Estimation 20 3.7. Lifecycle Assessment 22 4. Results And Discussions 25 4.1. Component-Wise Breakup Of Concrete And Steel Quantities 26 4.2. Percentage Share Of Materials 28 4.3. Embodied Carbon 30 4.3.1. Steel 30 4.3.2. Concrete 33 4.4. Embodied Energy 36 4.4.1. Steel 36 4.4.2. Concrete 38 5. Conclusion 41 Bibliography 43 Annexures 49 | ||
| 700 | _aRawal, Rajan (Guide) | ||
| 890 | _aIndia | ||
| 891 | _a2022 Batch | ||
| 891 | _aFT-PG | ||
| 891 | _aMasters of Technology in Building Energy Performance | ||
| 999 |
_c72518 _d72518 |
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