The IEECB&SC’24 and the European ESCO conference, held in Frankfurt on 6 and 7 March 2024, brought together all the key players in energy efficiency and decarbonisation of commercial buildings and district, such as investors and property managers, academia and experts, equipment manufacturers, service providers (ESCOs), utilities, facilities management companies, data centre operators, urban planners and local and national policy makers, with a view to exchange information. In particular the conference aimed to attract property owner, investors, architects, local authorities and urban planners to present and discuss synergies and cooperation in removing existing barriers to energy efficiency, renewable energy and smart and NZE buildings and districts, on the role of ESCOs and on the impact of digitalisation and AI. Its objective was attracting high level presentations showing new technologies, techniques, services, policies, programmes and strategies to increase energy efficiency, renewable energy sources and to reduce greenhouse gases emissions in non-residential buildings, ICT and data centres and district/communities and cities. The Proceedings contains articles based on the presentations.
Authors
Bertoldi Paolo, Joint Research Centre, European Commission, Clementi, Enrico
- Catalogue number
- KJ-02-24-450-EN-N
- DOI
- https://data.europa.eu/doi/10.2760/716916
- ISBN
- 978-92-68-14947-8
- Pages
- 136
- Published in
- Belgium
- Themes
- Technical regulations , Energy research
Table of Contents
- Contents 3
- Abstract 4
- 1 Analysis of a novel compact integrated thermal energy storage system (MiniStor) in European sites 5
- Alexandros Tsimpoukis, Georgios Martinopoulos and Nikolaos Nikolopoulos 5
- Centre for Research & Technology Hellas /Chemical Process and Energy Resources Institute, 57001, Thessaloniki, Greece 5
- Abstract 5
- Introduction 5
- 1.1 MiniStor system description 6
- 1.1.1 PVT and solar thermal collectors 8
- 1.1.2 Thermochemical Reactor and ammonia cycle operation 9
- 1.1.3 Heat Pump and Phase Change Material storage 11
- 1.1.4 Safety Equipment 12
- 1.2 Simulation results and discussion 13
- Conclusions 16
- References 17
- 2 NABERS Nearly 25 years on - Program Overview 19
- Dr Paul Bannister, DeltaQ Pty Ltd 19
- Carlos Flores, NABERS 19
- Abstract 19
- 2.1 Background 19
- 2.1.1 Building Energy Efficiency and Rating Schemes 19
- 2.2 What is NABERS? 20
- 2.2.1 History 20
- 2.2.2 Rating types 21
- 2.2.3 Rating Methodology 22
- 2.2.4 Coverage 22
- 2.2.5 NABERS NZ 23
- 2.2.6 NABERS UK 23
- 2.2.7 NABERS and New Buildings 24
- 2.3 NABERS Operations 24
- 2.3.1 Governance 24
- 2.3.2 Operations 24
- 2.4 Uptake of NABERS 25
- 2.4.1 Australia: Energy/emissions Ratings FY 2023 25
- Australia – Water/Indoor environment/Waste ratings 26
- 2.4.2 Australia – Commitment Agreements 27
- 2.5 NABERSNZ 27
- 2.6 NABERS UK 28
- 2.7 Impact of NABERS 28
- 2.8 Discussion 30
- 2.8.1 Success Factors 30
- 2.8.2 Issues, Challenges and Lessons Learnt 31
- 2.9 Moving Forward 32
- Conclusions 33
- References 34
- 3 Commercial Building Energy Efficiency Measures for the Australian National Construction Code: Preliminary Results 35
- Dr Paul Bannister, DeltaQ Pty Ltd 35
- Eser Monty, DeltaQ Pty Ltd 35
- Grace Foo, DeltaQ Pty Ltd 35
- Hongsen Zhang, Enerefficiency Pty Ltd 35
- Sam Moffitt, Moffitt Consulting Pty Ltd 35
- Abstract 35
- Introduction 35
- 3.1 Australian Climate Zones 36
- 3.2 Outline Analysis Process 36
- 3.2.1 Stringency levels 36
- 3.2.2 Analysis process 37
- 3.3 Summary of Key Analyses and Recommendations 38
- 3.3.1 Glazing 38
- 3.3.2 Chillers 39
- 3.3.3 Unitary Air-Conditioning 40
- 3.3.4 PV And Batteries 41
- 3.3.5 Other HVAC Measures 41
- 3.3.6 Other Building Envelope Measures 42
- 3.3.7 Lighting 44
- 3.3.8 Electrification 44
- 3.4 Whole Building Results 45
- 3.4.1 Stringency 1 – energy efficiency measures only 45
- 3.4.2 Stringency 2 – Stringency 1 plus rooftop PV 46
- 3.4.3 Stringency 3 – Stringency 2 plus electrification 47
- 3.5 Discussion and Next Steps 48
- Discussion 48
- Next steps 48
- Conclusions 48
- References 49
- 4 Machine Learning algorithms for Urban Building Energy Modeling 50
- Ahad Montazeri1, Guglielmina Mutani1,* 50
- 1 Department of Energy, Politecnico di Torino, Corso Duca degli Abruzzi 24, Torino, Italy, +390110904528, name.surname@polito.it 50
- *Corresponding author: guglielmina.mutani@polito.it 50
- Abstract 50
- Introduction 50
- 4.1 Case study 51
- 4.2 Methodology 52
- 4.3 Discussion and results 56
- Conclusion 62
- Acknowledgments 63
- References 64
- 5 Quantifying the Growing Gap Between Brown and Green Buildings 65
- Lucienne Mosquera 65
- CEO and Founder SustainCRE 65
- Abstract 65
- Introduction 65
- 5.1 How big is the threat and opportunity? 65
- 5.2 How time, business models, occupiers, investors, and valuers will drive the growing gap. 67
- 5.2.1 Diminishing premiums 67
- 5.2.2 Business models 68
- 5.2.3 Occupier Demand 68
- 5.2.4 Investor Demand 70
- 5.2.5 Valuation 71
- 5.3 Quantifying the brown discount 72
- 5.4 Main value drivers 73
- 5.4.1 Higher revenue 73
- 5.4.2 Lower operating costs 73
- 5.5 Impact Coordination 74
- 5.5.1 Cash Flow and Valuations 74
- Conclusion 75
- 6 Risk aware resource planning for microgrid connected edge data center with renewable energy production operating under grid power constraints 77
- Rickard Brännvall1, Sebastian Fredriksson1, Jonas Gustafsson1, Lackis Eleftheriadis2 77
- 1RISE, Research Institutes of Sweden, Luleå, Sweden, 77
- 2Ericsson Research, Sweden 77
- Abstract 77
- Introduction 77
- 6.1 Related Work 78
- 6.2 Problem formulation 79
- 6.3 Method 80
- 6.3.1 Theoretical models for irradiance 80
- 6.4 Data sources 80
- 6.5 Datacenter model 83
- 6.6 Results 83
- 6.7 Discussion 85
- Acknowledgment 85
- REFERENCES 86
- Appendix A. Theoretical irradiation models 87
- Appendix B. Deriving the Markov chain 88
- Appendix C. Alternative Planning Method 90
- 7 Smart Lighting systems: Dream or reality? 91
- Georges Zissis1, Paolo Bertoldi2 91
- 1Université de Toulouse, LAPLACE, UMR 5213 (CNRS, INPT, UPS) 91
- 2European Commission, JRC - Ispra, Italy 91
- Abstract 91
- 7.1 The context 91
- 7.2 Smart Lighting Penetration Progress Assessment 93
- 7.3 Smart Lighting Market 95
- 7.4 Smart lighting, energy and market impacts 99
- Conclusions 102
- References 104
- 8 Energy efficiency in lighting based on the implementation of MEPS 107
- F.Z. El Wardi 1, B. El Bannadry 2, A. Dahani 2, C. Benqlilou 2 107
- 1 Physics Department, LPMAT Laboratory, Faculty of Sciences Ain Chock, Hassan II University, Casablanca, Morocco 107
- 2 Research team energy sustainability and mathematical modelling (ES2M), Rabat School of Mines 107
- Abstract 107
- Introduction 107
- 8.1 Materials and Methods 109
- 8.1.1 Cost-benefit analysis 109
- 8.2 Results and Discussion 112
- 8.2.1 Proposal of minimum energy performance standards for lighting 112
- 8.2.2 Analysis of energy, economic, and environmental impact of MEPS lighting 114
- Conclusion 116
- References 118
- 9 Lessons learned from analysing PED case studies 120
- Matthias Haase, Ursula Eicker, Caroline Hachem-Vermette; Genku Kayo, Hassam ur Rehman 120
- ZHAW, Switzerland; Concordia University, Canada; Tokyo City University, Japan; VTT Technical Research Center of Finland, Finland 120
- Abstract 120
- Introduction 120
- 9.1 State of the art in PED databases 121
- 9.2 Case studies of energy communities 122
- 9.3 Methodology 122
- 9.4 Results 124
- 9.4.1 Example from Finland 125
- 9.4.2 Example from Canada 126
- 9.4.3 Example from Japan 127
- 9.5 Comparison 128
- 9.6 Discussion 129
- Conclusions 130
- Future developments and conclusions 130
- Widening the perspective to global scale 130
- Replication potential of cases in database 131
- References 132
- Back cover.pdf 1
- Getting in touch with the EU 135
- Finding information about the EU 135
