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3. 16 energiforskere fra fem universiteter: Lad os få mere fakta i atomkraftdebatten:Der er ikke behov for atomkraft for at sikre stabilitet i elforsyningen. Det vil kun gøre den dyrere og samtidig forsinke den grønne omstilling, skriver en række forskere i et svar til kernefysikere, som har efterlyst mere helstøbt og åben vurdering af atomkraft i Danmark

Author

Lund, Henrik, Zinck Thellufsen, Jakob, Vad Mathiesen, Brian, Thøis Madsen, Poul, Østergaard, Poul Alberg, Nielsen, Steffen, Sorknæs, Peter, Wenzel, Henrik, Sørensen, Peter Birch, Bruun Andresen, Gorm, and Victoria, Marta

Published
2022

4. Peta : the Pan-European Thermal Atlas : version 5.2 : developed as part of the sEEnergies project

Author

Möller, Bernd, Wiechers, Eva, Persson, Urban, Nielsen, Steffen, Werner, Sven, Connolly, David, Wilke, Ole Garcia, Sánchez-García, Luis, Moreno, Diana, Grundahl, Lars, Lund, Rasmus Søgaard, Vad Mathiesen, Brian, Lund, Henrik, Möller, Bernd, Wiechers, Eva, Persson, Urban, Nielsen, Steffen, Werner, Sven, Connolly, David, Wilke, Ole Garcia, Sánchez-García, Luis, Moreno, Diana, Grundahl, Lars, Lund, Rasmus Søgaard, Vad Mathiesen, Brian, and Lund, Henrik

Abstract

The Pan-European Thermal Atlas version 5.2 (Peta, version 5.2). Peta is an online visualization tool for spatial data relating to energy efficiency in buildings, industry, and transport sectors. Developed as part of the sEEnergies project. Copyright Flensburg, Halmstad and Aalborg Universities 2022.

Published
2022

5. Sustainable Energy Planning and Management Vol 38.

Author

Alberg Østergaard, Poul, Magni Johannsen, Rasmus, Duic, Neven, Lund, Henrik, Vad Mathiesen, Brian, Soares, Isabel, and Ferreira, Paula

Subjects
RENEWABLE energy standards, SUSTAINABLE development, CARBON offsetting, HEAT storage, ENERGY consumption
Abstract

This 38th volume of the International Journal of Sustainable Energy Planning and Management presents some of the newest work within the energy planning, energy systems analyses and district heating area. Articles focus on multi objective optimisation for a community in the Alps, carbon neutrality in Estonia, the prospects of heat pumps combined with thermal energy storage in maximising self-consumption from a photovoltaic field and methods for assessing district heating options. Other works focus on gamification tools for assessing energy efficiency measures, country analyses of economic and environmental indicators, the adaption of alternative fuel vehicles, and the use of waste heat sources for district heating. [ABSTRACT FROM AUTHOR]

Published
2023
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6. Danmark skal investere massivt i energisektoren for at nå klimamål - men ikke i atomkraft

Author

Aagaard, Lars and Vad Mathiesen, Brian

Subjects
atomkraftværker, atomenergi, kronikker, grøn omstilling, Danmark, energipolitik, energiforsyning, klimaændringer, klimamål, klimapolitik
Abstract

Ængstelsen for de hastigt stigende energipriser må ikke få os til at gå i panik og lede efter løsninger, der ikke er realistiske, for den faktuelle sandhed er, at snakken om dansk atomkraft er varm luft, og bliver ved med at være det

Published
2022

11. Heat Roadmap Europe : Towards EU-Wide, local heat supply strategies

Author

Möller, Bernd, Wiechers, Eva, Persson, Urban, Grundahl, Lars, Søgaard Lund, Rasmus, Vad Mathiesen, Brian, Möller, Bernd, Wiechers, Eva, Persson, Urban, Grundahl, Lars, Søgaard Lund, Rasmus, and Vad Mathiesen, Brian

Abstract

The present paper describes a quantitative method for preparing local heat supply strategies. Detailed spatial data on heat demand and supply are generated using combined top-down and bottom-up modelling for 14 member states of the European Union, which constitute 91% of its heat demand in buildings. Spatial analysis is used for zoning of heat supply into individual and collective heating. Continuous cost curves are used to model economically feasible district heating shares within prospective supply districts. Excess heat is appraised and allocated to prospective district heating systems by means of a two-stage network allocation process. Access to renewable energy sources such as geothermal, large-scale solar thermal, as well as sustainable biomass, is analysed. The result is a comprehensive and detailed set of heat supply strategies in a spatially discrete manner. The findings indicate that in the 14 European Union member states, up to 71% of building heat demand in urban areas can be met with district heating. Of this, up to 78% can be covered with excess heat, while the remainder can be covered with low enthalpy renewable energy sources. The conclusion shows the possibility of a largely de-carbonised heat sector as part of a smart energy system for Europe. © 2019 Elsevier Ltd, Heat Roadmap Europe

Published
2019
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13. Heat Roadmap Europe 4 : Quantifying the Impact of Low-Carbon Heating and Cooling Roadmaps: Deliverable 6.4

Author

Paardekooper, Susana, Søgaard Lund, Rasmus, Vad Mathiesen, Brian, Chang, Miguel, Petersen, Uni Reinert, Grundahl, Lars, David, Andrei, Dahlbæk, Jonas, Kapetanakis, John, Lund, Henrik, Bertelsen, Nis, Hansen, Kenneth, Drysdale, David, Persson, Urban, Paardekooper, Susana, Søgaard Lund, Rasmus, Vad Mathiesen, Brian, Chang, Miguel, Petersen, Uni Reinert, Grundahl, Lars, David, Andrei, Dahlbæk, Jonas, Kapetanakis, John, Lund, Henrik, Bertelsen, Nis, Hansen, Kenneth, Drysdale, David, and Persson, Urban

Abstract

Heat Roadmap Europe (HRE)

Published
2018

15. Heat Roadmap Europe : Large-Scale Electric Heat Pumps in District Heating Systems

Author

David, Andrei, Vad Mathiesen, Brian, Averfalk, Helge, Werner, Sven, Lund, Henrik, David, Andrei, Vad Mathiesen, Brian, Averfalk, Helge, Werner, Sven, and Lund, Henrik

Abstract

The Heat Roadmap Europe (HRE) studies estimated a potential increase of the district heating (DH) share to 50% of the entire heat demand by 2050, with approximately 25–30% of it being supplied using large-scale electric heat pumps. This study builds on this potential and aims to document that such developments can begin now with technologies currently available. We present a database and the status of the technology and its ability of expansion to other European locations by reviewing experiences aimed at further research or application in the heating industry. This is based on a survey of the existing capacity of electric large-scale heat pumps with more than 1 MW thermal output, operating in European DH systems. The survey is the first database of its kind containing the technical characteristics of these heat pumps, and provides the basis for the analysis of this paper. By quantifying the heat sources, refrigerants, efficiency and types of operation of 149 units with 1580 MW of thermal output, the study further uses this data to analyze if the deployment of this technology on a large-scale is possible in other locations in Europe. It finally demonstrates that the technical level of the existing heat pumps is mature enough to make them suitable for replication in other locations in Europe.

Published
2017
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16. Enhanced Heating and Cooling Plans to Quantify the Impact of Increased Energy Efficiency in EU Member States - Work Package 2, Main Report: Executive Summary

Author

Connolly, David, Hansen, Kenneth, Drysdale, David, Lund, Henrik, Vad Mathiesen, Brian, Werner, Sven, Persson, Urban, Möller, Bernd, Garcia Wilke, Ole, Bettgenhäuser, Kjell, Pouwels, Willemijn, Boermans, Thomas, Novosel, Tomislav, Krajačić, Goran, Duić, Neven, Trier, Daniel, Møller, Daniel, Michael Odgaard, Anders, and Laurberg Jensen, Linn

Subjects
STRATEGO, Sustainable heating and cooling, District heating and cooling, Energy planning, Mapping
Abstract

The STRATEGO WP2 main report quantifies the impact of implementing various energy efficiency measures in the heating and cooling sectors of five EU Member States: Czech Republic, Croatia, Italy, Romania, and the United Kingdom. These countries vary considerably in terms of population, climate, resources, and energy supply, so the key results, conclusions, and recommendations presented in this report can inform national energy policy across all of Europe. The results from this study indicate that a total investment of approximately €1.1 trillion in energy efficiency measures across all five of these countries, between 2010 and 2050, will save enough fuel to reduce the costs of their energy systems. After considering both the initial investment and the resulting savings, the total annual cost of the heating, cooling, and electricity sectors is reduced by an average of ~15% in each country (see Figure 1). These initial investments are primarily required in heat savings for the buildings, district heating in urban areas, and electric heat pumps in rural areas. In essence, energy efficiency measures in the heating sector will enable EU Member States to simultaneously reduce energy demand, imported fossil fuels, carbon dioxide emissions, and the cost of the heating, cooling, and electricity sectors (see Figure 1).

Published
2015

17. Performance analysis of hybrid district heating system

Author

Mikulandrić, Robert, Krajačić, Goran, Duić, Neven, Gennadii, Khavin, Lund, Henrik, Vad Mathiesen, Brian, and Østergaard, Poul

Subjects
District heating systems, hybrid systems, system optimisation
Abstract

District heating system could contribute to more efficient heat generation through cogeneration power plants or waste heat utilization facilities and to increase of renewable energy sources share in total energy consumption. In the most developed EU countries, renewable energy sources have been more extensively used in district heating systems either separately or as a supplement to traditional fossil fuels in order to achieve national energy policy objectives. However, they are still facing problems such as high intermittences, high energy production costs and low load factors as well as problems related to transportation, storage and environmental impacts of biomass and waste utilisation. Implementation of heat storages in district heating systems could contribute to integration of intermittent energy sources. Hybridisation of heat production facility combines two or more different energy sources that can complement each other on daily and yearly basis and reduce negative aspects of particular energy source utilisation. In district heating systems, hybridisation could be performed through utilisation of renewable and non-renewable energy sources. Potential of fuel and emission reduction could reach up to 20% with utilisation of solar energy as supplement energy source in traditional fossil fuel based district heating systems. In this work, the performance of hybrid district energy system for a particular location will be analysed. For performance analysis, mathematical model that combines different energy sources for heat production will be used. The work has been carried out in scope of 4th Generation District Heating Technologies and Systems project.

Published
2013

19. Improving capacity of Jordanian Research in Integrated Renewable Energy and Water supply – JoRIEW project

Author

Schneider, Daniel Rolph, Sanopoulos, Dimitris, Mohsen, Mousa, Vad Mathiesen, Brian, Voutetakis, Paris, Krajačić, Goran, Duić, Neven, Ban, Marko, Duić, Neven, Guzović, Zvonimir, Klemeš, Jiri Jaromir, Markovska, Nataša, Schneider, Daniel Rolph, Varbanov, Petar, and Krajačić, Goran

Subjects
research, Jordan, renewable energy, desalination, integrated energy-water supply
Abstract

Sustainability and sustainable development of energy, water and environment systems are the ultimate goals of the societies that care about their own future. To reach these goals it will not be enough to apply new technologies and process but it will seek for a wider approach to the integrated system planning and to large scale cooperation between different stakeholders. The knowledge transfer is one of the important pillars of transforming the current system to the more sustainable one. The paper describes results of networking achieved within recently started JoRIEW project that will have significant impact on Jordanian national policy in terms of water management, renewable energy sources and energy saving. The objective of the JoRIEW project is to reinforce the cooperation capacities of Jordanian research centres by promoting closer scientific collaboration with a number of European located research centres and universities. The project will help to structure and enhance S&T cooperation in areas of common interest, such us system integration, integrated energy and water planning, development of water supply systems that can be powered by intermittent renewable energies, in particular flexible pumping techniques and reverse osmosis desalination technology, where joint research efforts could bring common solutions and mutual benefits. Improving Jordanian capacities in research will be achieved through following activities that are in detailed presented in the paper: Networking of Jordanian and EU research centres in view of disseminating scientific information, identifying partners and setting up joint research Developing training modules to build competency and facilitate the Jordanian participation in FP7 projects regarding energy and water research Developing the Jordanian research strategy for sustainable and renewable energy and water desalination in order to increase its scope, in particular its regional coverage and to improve its responses to the socio-economic needs of Jordan and other countries in the region.

Published
2012

20. Danish Wind Power Export and Cost

Author

Lund, Henrik, Hvelplund, Frede, Alberg Østergaard, Poul, Möller, Bernd, Vad Mathiesen, Brian, N. Andersen, Anders, Morthorst, Poul Erik, Karlsson, Kenneth, Meibom, Peter, Münster, Marie, Munksgaard, Jesper, Karnøe, Peter, Wenzel, Henrik, and Lindboe, Hans Henrik

Abstract

In a normal wind year, Danish wind turbines generate the equivalent of approx. 20 percent of the Danish electricity demand. This paper argues that only approx. 1 percent of the wind power production is exported. The rest is used to meet domestic Danish electricity demands. The cost of wind power is paid solely by the electricity consumers and the net influence on consumer prices was as low as 1-3 percent on average in the period 2004-2008. In 2008, the net influence even decreased the average consumer price, although only slightly. In Denmark, 20 percent wind power is integrated by using both local resources and international market mechanisms. This is done in a way which makes it possible for our neighbouring countries to follow a similar path. Moreover, Denmark has a strategy to raise this share to 50 percent and the necessary measures are in the process of being implemented. Recently, a study made by the Danish think tank CEPOS claimed the opposite, i.e. that most of the Danish wind power has been exported in recent years. However, this claim is based on an incorrect interpretation of statistics and a lack of understanding of how the international electricity markets operate. Consequently, the results of the CEPOS study are in general not correct. Moreover, the CEPOS study claims that using wind turbines in Denmark is a very expensive way of reducing CO2 emissions and that this is the reason for the high energy taxes for private consumers in Denmark. These claims are also misleading. The cost of CO2 reduction by use of wind power in the period 2004-2008 was only 20 EUR/ton. Furthermore, the Danish wind turbines are not paid for by energy taxes. Danish wind turbines are given a subsidy via the electricity price which is paid by the electricity consumers. In the recent years of 2004-2008, such subsidy has increased consumer prices by 0.54 €¢/kWh on average. On the other hand, however, the same electricity consumers also benefitted from the wind turbines since the wind power decreased the electricity market price on Nord Pool. On average during 2004-2008, such effect decreased the consumer prices by 0.27 €¢/kWh and consequently the net influence during this period increased consumer prices by only 0.27 €¢/kWh equal to only 1-3 percent of the final consumer prices. In 2008, the net influence of wind power actually decreased the consumer price slightly by approx. 0.05 €¢/kWh. Consequently, the influence of Danish wind turbines on the consumer electricity price is negligible.

Published
2010

21. Progress and results from the 4DH research centre

Author

Werner, Sven, Lund, Henrik, Vad Mathiesen, Brian, Werner, Sven, Lund, Henrik, and Vad Mathiesen, Brian

Abstract

With lower and more flexible distribution temperatures, fourth generation district heating systems can utilize renewable energy sources, while meeting the requirements of low-energy buildings and energy conservation measures in the existing building stock. 4DH is an international strategic research centre located at Aalborg University, which develops 4th generation district heating technologies and systems (4GDH). This technology is fundamental to the implementation of the Danish objective of being fossil fuel-free by 2050 and the European 2020 goals. The research centre is working between 2012 and 2017, with The Danish Council for Strategic Research as main financier and the participating 31 Danish and international companies and universities as co-financiers. Thirteen PhD student projects constitute a vital part of the research centre. In 4GDH systems, synergies are created between three areas of district heating and cooling, which also sum up the work of the 4DH Centre: Grids and components; Production and system integration, and Planning and implementation. This paper presents an overview of the progress and results achieved after more than two years of work. This includes the basic definition paper, the two Heat Roadmap Europe pre-studies, annual conferences, additional demonstration projects, initiated European project proposals, an international PhD course based on the new international textbook, PhD student seminars, all PhD student subjects, and a list of major papers and articles written so far within the research centre., The work presented in this paper is a result of the research activities of the Strategic Research Centre for 4th Generation District Heating (4DH), which has received funding from The Danish Council for Strategic Research. Additional funding was obtained from Euroheat & Power for the two Heat Roadmap Europe pre-studies. The participation of Halmstad University in the 4DH research centre is co-financed by the Swedish Fjärrsyn research program., 4DH

Published
2014

22. 4th Generation District Heating (4GDH) : Integrating smart thermal grids into future sustainable energy systems

Author

Lund, Henrik, Werner, Sven, Wiltshire, Robin, Svendsen, Svend, Thorsen, Jan Eric, Hvelplund, Frede, Vad Mathiesen, Brian, Lund, Henrik, Werner, Sven, Wiltshire, Robin, Svendsen, Svend, Thorsen, Jan Eric, Hvelplund, Frede, and Vad Mathiesen, Brian

Abstract

This paper defines the concept of 4th Generation District Heating (4GDH) including the relations to District Cooling and the concepts of smart energy and smart thermal grids. The motive is to identify the future challenges of reaching a future renewable non-fossil heat supply as part of the implementation of overall sustainable energy systems. The basic assumption is that district heating and cooling has an important role to play in future sustainable energy systems – including 100 percent renewable energy systems – but the present generation of district heating and cooling technologies will have to be developed further into a new generation in order to play such a role. Unlike the first three generations, the development of 4GDH involves meeting the challenge of more energy efficient buildings as well as being an integrated part of the operation of smart energy systems, i.e. integrated smart electricity, gas and thermal grids. © 2014 Elsevier Ltd., 4DH-projektet

Published
2014
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23. Simulation versus Optimisation: Theoretical Positions in Energy System Modelling.

Author

Lund, Henrik, Arler, Finn, Østergaard, Poul Alberg, Hvelplund, Frede, Connolly, David, Vad Mathiesen, Brian, and Karnøe, Peter

Subjects
RENEWABLE energy sources, ELECTRIC power production, ARCHETYPES, FOSSIL fuels, POWER resources
Abstract

In recent years, several tools and models have been developed and used for the design and analysis of future national energy systems. Many of these models focus on the integration of various renewable energy resources and the transformation of existing fossil-based energy systems into future sustainable energy systems. The models are diverse and often end up with different results and recommendations. This paper analyses this diversity of models and their implicit or explicit theoretical backgrounds. In particular, two archetypes are defined and compared. On the one hand, the prescriptive investment optimisation or optimal solutions approach. On the other hand the analytical simulation or alternatives assessment approach. Awareness of the dissimilar theoretical assumption behind the models clarifies differences between the models, explains dissimilarities in results, and provides a theoretical and methodological foundation for understanding and interpreting results from the two archetypes. [ABSTRACT FROM AUTHOR]

Published
2017
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25. The role of district heating in decarbonising the EU energy system and a comparison with existing strategies

Author

Connolly, David, Lund, Henrik, Vad Mathiesen, Brian, Möller, Bernd, Østergaard, Poul Alberg, Nielsen, Steffen, Werner, Sven, Persson, Urban, Trier, Daniel, Connolly, David, Lund, Henrik, Vad Mathiesen, Brian, Möller, Bernd, Østergaard, Poul Alberg, Nielsen, Steffen, Werner, Sven, Persson, Urban, and Trier, Daniel

Abstract

Many strategies have already been proposed for the decarbonisation of the EU energy system by the year 2050. These typically focus on the expansion of renewable energy in the electricity sector and subsequently, electrifying both the heat and transport sectors as much as possible. In these strategies, the role of district heating has never been fully explored system, nor have the benefits of district heating been quantified at the EU level. This study combines the mapping of local heat demands and local heat supplies across the EU27. Using this local knowledge, new district heating potentials are identified and then, the EU27 energy system is modelled to investigate the impact of district heating. The results indicate that a combination of heat savings, district heating in urban areas, and individual heat pumps in rural areas will enable the EU27 to reach its greenhouse gas emissions targets by 2050, but at a cheaper price than a scenario which focuses primarily on the implementation of heat savings., Heat Roadmap Europe 2050

Published
2013

26. System and market integration of wind power in Denmark

Author

Lund, Henrik, Hvelplund, Frede, Alberg Østergaard, Poul, Möller, Bernd, Vad Mathiesen, Brian, Karnøe, Peter, Andersen, Anders N., Morthorst, Poul Erik, Karlsson, Kenneth Bernard, Münster, Marie, Munksgaard, Jesper, Wenzel, Henrik, Lund, Henrik, Hvelplund, Frede, Alberg Østergaard, Poul, Möller, Bernd, Vad Mathiesen, Brian, Karnøe, Peter, Andersen, Anders N., Morthorst, Poul Erik, Karlsson, Kenneth Bernard, Münster, Marie, Munksgaard, Jesper, and Wenzel, Henrik

Abstract

Denmark has more than 10 years’ of experience with a wind share of approximately 20 per cent. During these 10 years, electricity markets have been subject to developments with a key focus on integrating wind power as well as trading electricity with neighbouring countries. This article introduces a methodology to analyse and understand the current market integration of wind power and concludes that the majority of Danish wind power in the period 2004e2008 was used to meet the domestic demand. Based on a physical analysis, at least 63 per cent of Danish wind power was used domestically in 2008. To analyse the remaining 37 per cent, we must apply a market model to identify cause-effect relationships. The Danish case does not illustrate any upper limit for wind power integration, as also illustrated by Danish political targets to integrate 50 per cent by 2020. In recent years, Danish wind power has been financed solely by the electricity consumers, while maintaining production prices below the EU average. The net influence from wind power has been as low as 1e3 per cent of the consumer price. © 2012 Elsevier Ltd. All rights reserved.

Published
2013

27. Det intelligente energisystem

Author

Skøtt, Torben, Vad Mathiesen, Brian, Lund, Henrik, Hvelplund, Frede K., Connelly, David, Bentsen, Niclas S., Tonini, Davide, Morthorst, Poul Erik, Wenzel, Henrik, Astrup, Thomas Fruergaard, Meyer, Niels I, Münster, Marie, Alberg Østergaard, Poul, Bak-Jensen, Birgitte, Pagh Nielsen, Mads, Schaltz, Erik, Pillai, J.R., Hamelin, Lorie, Felby, Claus, Heussen, Kai, Karnøe, Peter, Munksgaard, Jesper, Hansen, Lise-Lotte Pade, Møller Andersen, Frits, Skøtt, Torben, Vad Mathiesen, Brian, Lund, Henrik, Hvelplund, Frede K., Connelly, David, Bentsen, Niclas S., Tonini, Davide, Morthorst, Poul Erik, Wenzel, Henrik, Astrup, Thomas Fruergaard, Meyer, Niels I, Münster, Marie, Alberg Østergaard, Poul, Bak-Jensen, Birgitte, Pagh Nielsen, Mads, Schaltz, Erik, Pillai, J.R., Hamelin, Lorie, Felby, Claus, Heussen, Kai, Karnøe, Peter, Munksgaard, Jesper, Hansen, Lise-Lotte Pade, and Møller Andersen, Frits

Published
2012

28. 100% Renewable energy systems, climate mitigation and economic growth

Author

Vad Mathiesen, Brian, Lund, Henrik, Karlsson, Kenneth Bernard, Vad Mathiesen, Brian, Lund, Henrik, and Karlsson, Kenneth Bernard

Abstract

Greenhouse gas mitigation strategies are generally considered costly with world leaders often engaging in debate concerning the costs of mitigation and the distribution of these costs between different countries. In this paper, the analyses and results of the design of a 100% renewable energy system by the year 2050 are presented for a complete energy system including transport. Two short-term transition target years in the process towards this goal are analysed for 2015 and 2030. The energy systems are analysed and designed with hour-by-hour energy system analyses. The analyses reveal that implementing energy savings, renewable energy and more efficient conversion technologies can have positive socio-economic effects, create employment and potentially lead to large earnings on exports. If externalities such as health effects are included, even more benefits can be expected. 100% Renewable energy systems will be technically possible in the future, and may even be economically beneficial compared to the business-as-usual energy system. Hence, the current debate between leaders should reflect a combination of these two main challenges.

Published
2011

30. Industry mitigation scenarios and IndustryPLAN tool results

Author

Magni Johannsen, Rasmus, Vad Mathiesen, Brian, and Ridjan Skov, Iva

Subjects
7. Clean energy
Abstract

The IndustryPLAN tool targets the lacking middle ground between highly site-specific analyses of individual production facilities and generalized nationally aggregated analyses. The purpose of the IndustryPLAN tool is to open the black box of industry and provide a framework for developing sub-sector specific analyses on both a country-specific and European level. This is done by establishing both disaggregated industry energy demands for all countries of the EU and an extensive catalogue of potential mitigation measures for the future. Applying the energy efficiency first principle, the IndustryPLAN tool provides a framework for investigating the industrial energy sector in the context of the renewable energy transition. The user is provided with a flexible platform for developing future industry energy scenarios based on a range of potential energy efficiency measure, electrification measures, and hydrogen fuel shift measures. This report presents the scenarios resulting from the detailed analysis of the European industrial sector in the sEEnergies project. The scenario results provide the inputs necessary for representing the industry sector in further holistic energy system modelling in tools such as EnergyPLAN.

31. Report on energy efficiency potentials in the transport sector

Author

Næss, Petter, Wolday, Fitwi, Elle, Morten, Abid, Hamza, Strunge Kany, Mikkel, and Vad Mathiesen, Brian

Subjects
13. Climate action, 7. Clean energy
Abstract

This report illuminates potentials for energy saving within the transportation sector in the EU/EFTA area through energy efficiency measures for bringing about a modal shift from energy-demanding to more energy-efficient modes of transportation and reducing the movement of persons and goods.

32. Data set from the different scenarios developed in TransportPLAN

Author

Abid, Hamza, Strunge Kany, Mikkel, Vad Mathiesen, Brian, Nielsen, Steffen, Elle, Morten, and Næss, Petter

Subjects
11. Sustainability, 7. Clean energy
Abstract

As part of work package 2 of the sEEnergies project, transport data has been collected for 28 European countries. This includes transport activity demand data, transport specific energy consumptions, load factors and capacity for different modes of transport. The major source of data are the European National Travel Surveys. The data is categorized based on distance bands for each mode, both for passenger and freight. This is done for all EU-28 countries in a bottom up manner. The data is then combined together via weighted average to calculate the overall EU-28 transport activity and transport energy demand for the reference year (2017). A baseline is created following the same transport growth rates as used in the European PRIMES model. On top of the baseline, along with the results from Deliverable 2.1, calculations are performed to estimate the demand reductions and modal shifts based on energy efficient urban spatial and infrastructure development for the future.These energy efficiency practices are then combined with four energy efficiency transport technology scenarios for the future.

33. Data set from the different scenarios developed in TransportPLAN

Author

Abid, Hamza, Strunge Kany, Mikkel, Vad Mathiesen, Brian, Nielsen, Steffen, Elle, Morten, and Næss, Petter

Subjects
11. Sustainability, 7. Clean energy
Abstract

As part of work package 2 of the sEEnergies project, transport data has been collected for 28 European countries. This includes transport activity demand data, transport specific energy consumptions, load factors and capacity for different modes of transport. The major source of data are the European National Travel Surveys. The data is categorized based on distance bands for each mode, both for passenger and freight. This is done for all EU-28 countries in a bottom up manner. The data is then combined together via weighted average to calculate the overall EU-28 transport activity and transport energy demand for the reference year (2017). A baseline is created following the same transport growth rates as used in the European PRIMES model. On top of the baseline, along with the results from Deliverable 2.1, calculations are performed to estimate the demand reductions and modal shifts based on energy efficient urban spatial and infrastructure development for the future.These energy efficiency practices are then combined with four energy efficiency transport technology scenarios for the future.

34. Scenario analysis of the renewable district heating system in Ozalj, a small city in Croatia

Author

Doračić, Borna, Pušić, Tin, Novosel, Tomislav, Pukšec, Tomislav, Duić, Neven, Laurberg Jensen, Linn, Lund, Henrik, and Vad Mathiesen, Brian.

Subjects
district heating, renewable energy, heat demand mapping, techno-economic analysis, environmental impact
Abstract

Heating and cooling represents the most intensive energy sector in the European Union, accounting for around 50 % of its final energy consumption. Therefore, this sector has significant potentials to increase the energy efficiency, while reducing the primary energy consumption. Nevertheless, district heating systems are currently distributed in a rather uneven fashion in the European Union, covering a minor share of the overall heating demand. Furthermore, small renewable district heating systems are practically neglected, especially in the South- Eastern Europe. When managed properly, these systems have a number of potential benefits, including enhancement of the local employment and the security of the supply, increase of the local economy, use of various heat sources (e.g. biomass, solar collectors, excess heat, geothermal energy), etc. District heating will be also very important for future smart energy systems by enabling the integration of the power and heating/cooling sectors with the use of power- to-heat technologies and thermal storage. It is necessary to support and promote these concepts in order to achieve primary energy savings and reduction of environmental impact of the heating and cooling sectors. This is one of the main goals of the CoolHeating project (www.coolheating.eu), funded by Horizon2020 programme (grant agreement No 691679), which aims to support the implementation of "small modular renewable district heating and cooling grids" for communities in South-Eastern Europe. The final outcome of the project will be the initiation of new renewable district heating projects in 5 target communities up to the investment stage. This paper will provide a brief description of the CoolHeating project and an overview of the techno-economic analysis carried out for the heating sector in the city of Ozalj which is one of the target cities in Croatia. The first step in the analysis was to map the heat demand in Ozalj, in order to define areas of the city which are most suitable for a small district heating system. Input data for this have been gathered by a survey implemented as a part of the CoolHeating project. By analysing the results, two alternative district heating distributions have been proposed and evaluated. Furthermore, a techno-economic analysis has been conducted for two production facility alternatives and the environmental impact of the proposed system has been compared to the current situation. Heat demand mapping has been done by utilising Matlab and qGIS software, while Microsoft Excel and Matlab have been used to calculate the economic and environmental aspects of the analysed system.

Published
2017

35. Reapplication model for planning, development and integration of Smart district heating systems in Smart energy system

Author

Doračić, Borna, Vad Mathiesen, Brian, and Krajačić, Goran

Subjects
TEHNIČKE ZNANOSTI. Strojarstvo, metodologija, pametni centralizirani toplinski sustav, TECHNICAL SCIENCES. Mechanical Engineering, pametni grad, reaplikacija
Abstract

U ovom radu obrađena je tema reaplikacije pametnih centraliziranih toplinskih sustava kao dijela pametnih energetskih sustava u pametnim gradovima. Rad je napravljen u skladu s zadacima postavljenima u radnom paketu 8, projekta SmartEnCity. Najprije je proveden sažeti pregled projekata pametnih gradova i pametnih centraliziranih toplinskih sustava kako bi se odredili važni podaci iz projekata u tijeku. Dobiveni podaci će služiti kao vrijedan doprinos u SmartEnCity projektu. Opisom pametnih centraliziranih toplinskih sustava su definirane njihove glavne karakteristike. Opis je dan uz pomoć sveobuhvatnog pregleda postojeće literature. Kako bi se pametni centralizirani toplinski sustav kopirao, tj. replicirao iz jednog grada u drugi, potrebno je odrediti važne aspekte za replikaciju. Glavni aspekti koji su definirani i objašnjeni su: geografski, financijski, tehnički i aspekt vlasništva. Nakon definiranja važnih aspekata za replikaciju, definirani su i opisani važni koraci metodologije za replikaciju pametnih centraliziranih toplinskih sustava, te je izrađen dijagram toka replikacije dajući grafički prikaz metodologije, korak po korak. Konačno, definirana su i opisana četiri alata za korištenje u svrhu replikacije aktivnosti u gradu Sønderborg. Također, predložen je i sadržaj plana djelovanja za individualnu replikaciju u gradu Sønderborg. This thesis deals with replicating smart district heating systems as a part of smart energy systems in smart cities. The thesis was done done with inspiration from the Workpackage 8 of SmartEnCity EU research project and the municipality of Sønderborg, Denmark. First, a brief review of smart cities and smart district heating projects was carried out in order to define important lessons learned from ongoing demonstration activities to serve as a valuable input in SmartEnCity project. Description of smart district heating systems, defining their main characteristics was given by means of comprehensive review of existing literature. In order to replicate a smart district heating system from one city to another, it is necessary to define important aspects for replication. Main aspects that were defined and explained are geographical, financial, technical and ownership aspects. After defining important aspects for replication, important steps of methodology for replication of smart district heating systems are defined and described and the replication flowchart is drafted giving a step-by-step graphical representation of the methodology. Finally, four tools to be used in replication activities in the city of Sønderborg were defined and described and also the content for individual replication in the city of Sønderborg was proposed.

Published
2016

36. The role of large scale heat pumps in future energy systems

Author

Dominković, Dominik Franjo, Vad Mathiesen, Brian, and Krajačić, Goran

Subjects
usrednjeni troškovi toplinske energije, dizalica topline, levelized cost of heating energy, El-spot, područno grijanje, Nordpool, EnergyPLAN, CEEP, district heat, seasonal thermal energy storage, sezonski spremnik topline, Danish energy system, TIMES, pit thermal energy storage, heat pump, TEHNIČKE ZNANOSTI. Strojarstvo, MARKAL, wind energy, TECHNICAL SCIENCES. Mechanical Engineering, danski energetski sustav
Abstract

Ovaj diplomski rad predstavlja procjenu uloge dizalica topline velikih instaliranih snaga u budućem energetskom sustavu. U uvodu je opisana analiza trenutnog danskog energetskog sustava s posebnim naglaskom na sektore električne te toplinske energije. Također je objašnjen tehnološki koncept dizalica topline velikih instaliranih snaga. Poslije uvoda slijedi analiza dvaju modela koji se koriste za modeliranje energetskih sustava, EnergyPLAN-a i TIMES-a (MARKAL-a), kako bi se ukazalo na prednosti i nedostatke oba modela. Glavni zaključak analize je da EnergyPLAN-u ima prednost prilikom modeliranja energetskih sustava sa visokim udjelom intermitentnih izvora energije. U sljedećem poglavlju je prikazana analiza investicije u električni kotao te dizalice topline velike instalirane snage koristeći metodu usrednjenih troškova toplinske energije (eng. levelized cost of heating energy). Također je analizirana i elastičnost potražnje za električnom energijom na Nordpool burzi električne energije. Analizom se pokušalo utvrditi hoće li povećana potražnja za električnom energijom uslijed pogona dizalica topline dovesti do porasta cijena električne energije. Naposljetku, nekoliko različitih scenarija razvijeno je u EnergyPLAN-u s različitim instaliranim snagama vjetroelektrana, optimalnim kapacitetima dizalica topline velikih instaliranih snaga te sezonskim spremnicima topline u obliku jame (eng. pit thermal energy storage). U radu je pokazano da za svaku instaliranu snagu vjetroelektrana u energetskom sustavu postoji određena optimalna snaga dizalica topline, koja će smanjiti ukupne troškove energetskog sustava, CO2 emisija i kritičnog viška u proizvodnji električne energije (CEEP). Dodatne uštede u troškovima energetskog sustava ostvarive su dodavanjem velikih sezonskih spremnika topline u sustav s već optimalno instaliranom snagom dizalica topline. In this thesis, several tasks were performed in order to evaluate the role of large scale heat pumps in the near term future energy systems. Firstly, the analysis of the Danish current energy system was carried out with the special emphasize on the electricity and district heating sector. Moreover, a technical concept of the large scale heat pumps was provided. Secondly, the analysis of EnergyPLAN and TIMES (MARKAL) modelling tools was performed in order to detect pros and cons of each of the models. EnergyPLAN was chosen as the favourable modelling tool for the assessment of the energy systems with high share of intermittent energy sources. Thirdly, for the purpose of economic evaluation of investments in electric boilers and large scale heat pumps, a levelized cost of heating energy (LCOH) was calculated. Furthermore, price elasticity of electricity demand on Nordpool’s El-spot market was calculated in order to assess possible shift in demand due to possible increased usage of electricity by heat pumps. Lastly, several different scenarios in EnergyPLAN were developed with different wind penetration levels, large scale heat pumps capacity and pit thermal energy storage (PTES). It was shown that for each wind penetration level, a certain amount of large scale heat pumps is optimal, which reduces the total system costs, CO2 emissions and critical excess in electricity production (CEEP). Moreover, adding large scale seasonal thermal energy storage to the system with implemented optimal level of heat pumps capacity will decrease total system costs even more.

Published
2015

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