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Renewable energy plays a key role in the sustainable pathway towards a low carbon future and, despite new supply capacities, the transformation of the energy system also requires the adoption of a method which allows for the integration of increasing amounts of renewable energy. This requires a transition to more flexible processes at an industrial level and demand side management (DSM) is one possible way of achieving this transition. Currently, increased shares of variable renewable energy can cause the electricity supply to become more volatile and result in changes to the electricity market. In order to develop a new dynamic equilibrium to balance supply and demand, sufficient flexibility in demand is required. As adequate storage systems are not available in the short to medium term, the potential for large electricity consumers to operate flexibly is an attractive, pragmatic and feasible option. Recent studies in Germany suggest that there is significant potential for DSM in so-called "energy-intensive industries". However, the figures (which fall in the approximate range of 1,250-2,750 MW positive and 400-1,300 MW negative shiftable load) should be interpreted with caution. The range of industrial processes considered are diverse and vary from plant to plant, with the result that it is difficult to provide accurate calculations of the accumulated potential for Germany or the EU as a whole. Based on extensive surveys and panel discussions with representatives from energy-intensive industries (aluminum, cement, chemicals, iron & steel, pulp & paper), which together account for approximately one third of the industrial electricity demand in Germany, our paper provides an overview of both the opportunities and the barriers faced by DSM. One of the key findings is the possible loss in energy efficiency due to DSM: in order to decrease or increase production depending on the stability needs of the electricity system, plants and processes may no longer operate at their optimum levels. The effects on downstream production must also be taken into account in order to gain a more complete understanding of the overall effects of industrial DSM.
The overall objective of the web-based consumer information tool Euro-Topten is to promote the market transformation towards energy efficient products. Euro-Topten informs consumers about the most energy efficient products in various categories and thereby aims to directly influence the purchasing decisions of individuals or professional buyers.
Providers of internet-based information tools are confronted with the problem, that there is no bidirectional interaction with the users. Hence, it is difficult to evaluate if the specific needs of users are addressed, if and how the user processes this information and to what extent the information influences the user's decision making process.
To study these questions, a web-based survey was conducted in two consecutive rounds. In the first round the survey focused on the assessment of the information tool itself and the motivation for using the Euro-Topten websites. This survey was online on all active Euro-Topten partner websites from October to December 2012. In total, 1791 users completed the survey.
In the second round, a subset of the survey population was queried again. 1,043 participants agreed to take part in a more comprehensive follow up survey, 383 completed the second survey between May and July 2013. The second survey concentrated on the question how Euro-Topten has influenced the purchasing behaviour of the survey participants. This gave significant insights on how the information on the Euro-Topten websites has affected purchasing decisions of the surveyed users.
Based on a comparison of performance indicators of the most efficient products recommended on the Euro-Topten websites with performance indicators of a base case product available on the market, avoided energy demand could be estimated for those users, who bought products from the Euro-Topten list. Based on these results, two impacts of Euro-Topten could be estimated: The influence of Euro-Topten on purchasing decision of users and the associated reductions in energy demand and CO2-emissions.
In addition to the expansion of renewable energies, the efficient use of energy is crucial in order to ensure energy transition successful. The Federal Government of Germany has therefore set itself clear objectives with the National Energy Efficiency Action Plan (NAPE), which aims to reduce the primary energy consumption in Germany - compared to 2008 levels - by 20 per cent until 2020, and by 50 per cent until 2050. In addition, greenhouse gas emissions should fall by 40 per cent compared to 1990.
To reach this goal, the German Federal Ministry of Economic Affairs and Energy (BMWi) inter alia launched the "National Top Runner Initiative (NTRI)" in January 2016. It is an important component and concerns private homes, as well as industry, retail and services.
The NTRI is intended to bring energy efficient and high-quality appliances (so called Top Runners) onto the market more quickly, thus accelerate market replacement. For this purpose, motivation, knowledge and competence in product-related energy efficiency is to be strengthened and expanded along the whole value chain - from the appliance manufacturer to the retailer and the consumer. Manufacturers are pushed to develop more efficient products and consumers get valuable information about Top-Runner products and how they can benefit. In this context, retailers are especially relevant as they act as "gatekeeper" between manufacturers and consumers. They play a key role in advancing an energy efficient production and consumption. They do not only select the products but they also have a direct contact to consumers and influence the purchase decision. In this paper, special emphasis will be put on the role of retailers and the efforts of the National Top Runner Initiative will be illustrated. Barriers and incentives to motivate this target group will be elaborated.
Refrigerators and freezers (subsumed under the term "cold appliances") are among the most widely used electrical appliances in the residential sector all around the world. Currently, about 1.4 billion domestic cold appliances worldwide use about 650 TWh electricity, which is 1.2 times Germany’s total electricity consumption, and cause CO2 emissions of 450 million tons of CO2eq.
Although the specific electricity consumption per volume of cold appliances has decreased during recent years due to technical progress and policy instruments like labelling and eco-design requirements, total worldwide energy consumption of these appliances is on the increase. Scenario calculations were carried out for 10 world regions by the Wuppertal Institute. Results show that about half of the energy consumption could be saved with the most energy-efficient appliances available today, and even higher savings will be possible with next generation technologies by 2030. According to the analysis, these savings are usually very cost-effective.
All these aspects are part of the new website "bigEE.net - Your guide to energy efficiency in buildings" which aims to provide information about technical options but also about policies to support the development of energy-efficient appliances.
To initiate and foster market transformation of energy-efficient appliances it is highly advisable for policymakers to generate appliances-specific policy packages. Since each regional market has its specificity (e.g. energy prices, typical appliance affecting the cost effectiveness of efficient appliances), the barriers for the market transformation of single product groups are also specific and need to be addressed by appropriate policies and measures. Elements of measures to build appropriate specific policy packages for refrigerators will be presented in the paper, and the refrigerator package from California (USA) demonstrates the successful implementation of a sector-specific package.
About 2 % of the overall electricity consumption of the EU is caused by circulators in single or double family homes and flats. A new technology of pumps with electronically commutated (EC) motor pumps is available now; it is one possible way to achieve a reduction in circulator annual electricity use by 60 % or more.
The project's objective is a market transformation towards this new very energy-efficient pump technologies - Energy+ pumps - for circulators in heating systems, both stand alone and integrated in boilers. Only few manufacturers have so far introduced the new pump technology to the market for single or double family homes and flats.
To bring more products to the market from all major manufacturers, the project will adapt and apply the technology procurement methodology as it was very successfully tested in the European Energy+ project on energy-efficient cold appliances.
Large buyers will be aggregated, to activate the pump and boiler manufacturers. Sales and training materials and a sizing spreadsheet software for installation contractors will be developed and applied. A competition both for energy-efficient products and marketing campaigns will be organised and the information on the Energy+ pumps will be disseminated widely through website, newsletter, media, and fairs.
This paper gives a short overview of this project and presents the results of the first project phases: a European wide market study on circulators and heating systems, and the first Energy+ lists for circulators, buyers and supporters.
Die Wärmewende ist als Teil der Energiewende ein gesellschaftliches Großprojekt. Für eine erfolgreiche Umsetzung benötigt die Wärmewende im Vergleich zur Stromwende vielfältigere und differenziertere Handlungsmechanismen. Es geht dabei nicht nur um den Ersatz fossiler Energieträger im Bereich der Wärmeversorgung durch regenerative Quellen, sondern vielmehr um einen systemischen Ansatz, der zudem eine stringente Forcierung von Energieeffizienzmaßnahmen, eine optimierte Verzahnung von Strom- und Wärmesystemen sowie eine zielgruppenspezifische Adressierung und Sensibilisierung von Akteursgruppen (hier: Kommunen, Privathaushalte, Industrie, GHD) erforderlich macht.
The concept of regime and "flat ontologies" : empirical potential and methodological implications
(2012)
Techno-economic feasibility study of solar and wind based irrigation systems in Northern Colombia
(2014)
Water pumping systems powered by solar and wind energy are a clean, decentralized and economic alternative for the irrigation of crops. The intense droughts experienced in the last years in Northern Colombia due to particularly strong Nino Phenomena have reactivated the need of reliable water pumping irrigation systems in that region. This study aims to assess the techno economic feasibility of solar and wind based pumping irrigation system, taking as case study the Municipality of Piojo in the Atlantico department. In the first stage of the study the irrigation water requirements were determined by using the software CROPWAT based on two different crop patterns that represent existing feasible alternatives for small farmers of the region: i) a common crop pattern, which represent the current average distribution of crops for subsistence farming and ii) a fruit cash crop pattern that comprises crops for which well established markets in the region exist. Solar wind and diesel based pumping systems were sized based on the crop water demands for 1 ha. The unit irrigation costs of the three technologies, the two crop patterns and the three irrigation methods (surface, sprinkler and drip) were calculated and compared. The economical analysis was complemented with a cost-benefit analysis over 20 years. Our results show that both renewable energy based pumping systems (wind and solar) can cover the irrigation water demands of small farmers in the region. The economical analysis shows that windmills are the most cost effective solution followed by the solar pumping system. Diesel pumping system was the less cost effective, even though it does not comprise investment in water storage tank. The cost benefit analysis demonstrates that any irrigation system is financially unfeasible when providing water to a common crop pattern. In case of the fruit cash crop scenario the highest dividends were obtained by the wind pumping system and the lowest dividends by the diesel pumping system. The lowest payback period was obtained by the windmill after 7 years and could be even feasible after the fifth year if the surplus water would be used to irrigate larger areas. Dividends obtained in a fruit cash crop scenario with irrigation after 20 years were in the range of EUR 5200 and EUR 11200 higher than dividends obtained by the same crop pattern but without irrigation.
Innovation and diffusion of car-sharing for sustainable consumption and production of urban mobility
(2008)
In the light of the tremendous challenges facing the energy systems of the Middle East and North Africa (MENA), a number of concepts, roadmaps and scenario studies have emerged, describing potential transformation pathways towards a more sustainable, renewable-based, energy supply future in the region. Our article uses the scientific approach of "transition research" to analyze the most pertinent publications and concepts in this field to identify the key drivers and barriers for the transformation of the regional energy systems. The analysis likewise includes an assessment of possible indicators and indexes that can be used to monitor the sustainability of the transformation process of MENA energy systems.
In recent years, many energy scenario studies have proven that a power supply system based on renewable energies (RE) >90 percent is feasible. However, existing scenarios differ significantly in the composition of generation technologies. Some scenarios focus on wind energy in the northern part of Europe, others base on a large utilisation of solar technologies in the south. Apart from the generation capacities, the needed technical flexibilisation strategies such as grid extension, demand flexibilisation and energy storage are generally known and considered in many scenarios. Yet, the impact of different renewable generation strategies on the local utilisation of flexibility options needs to be further assessed. Based upon the BMBF research project RESTORE2050, analyses have been carried out that focus on these interdependencies. The results of the project show that the local utilisation of flexibilisation options depends to a great extent on the technology focus of the long-term renewable expansion strategy. This applies for the spatial flexibilisation as provided by transnational interconnection capacities, especially the ones connecting regions with a surplus of power generation (e.g. GB, Norway and Spain). Another impact of the renewable scenario is seen on the required temporal flexibilisation of electricity generation and demand. In addition, the available options will compete for high utilisation in a future energy system. The differences in the utilisation of these applications, which base on the varying shares of photovoltaic (PV) and wind energy generation, lead to the conclusion that the decision about longterm RE expansion ought to be made very soon in order to avoid inefficient flexibility pathways. Otherwise, if the future RE structure will be kept open, adequate adoption of new flexibility options will be difficult, especially in case of technologies with long lead and realisation time (e.g. new power grids and large scale energy storage devices).
Fernwärme (FW) spielt aufgrund ihres Potenzials zur effizienten Integration erneuerbarer Energien (EE) und Abwärme eine entscheidende Rolle für die Umsetzung der Wärmewende. Im Rahmen dieses Beitrags werden Herausforderungen, Maßnahmen und Trends sowie Projektbeispiele für die künftige Fernwärmeversorgung beleuchtet.
Die Akteurswende
(2015)
Die zunehmende Abkehr vom ursprünglichen EEG-Vergütungssystem mit einer festen Einspeisevergütung hin zu einer mehr und mehr marktorientierten Ausrichtung führt zu der Frage, ob die Umstrukturierung des EEG am Ende zu einer neuen Phase der Energiewende führt, der Neo-EEG-Phase.
Im vorliegenden Artikel werden die Veränderungen und Entwicklungsphasen des EEG mit besonderem Blick auf die Akteure des Stromsystems analysiert. Im Kontext der Energiewende können die zu beobachtenden und teils deutlich einschneidenden Veränderungen für alle Akteure des Systems durchaus als "Akteurswende" verstanden werden.
Increasing urbanisation and climate change belong to the greatest challenges of the 21st century. A high share of global greenhouse gas emissions are estimated to originate in urban areas (40 % to 78 % according to UN Habitat 2010). Therefore, low carbon city strategies and concepts implicate large greenhouse gas (GHG) mitigation potentials. At the same time, with high population and infrastructure densities as well as concentrated economic activities, cities are particularly vulnerable to the impacts of climate change and need to adapt. Scarce natural resources further constrain the leeway for long-term, sustainable urban development. The Low Carbon Future Cities (LCFC) project aims at tapping this three-dimensional challenge and will develop an integrated strategy / roadmap, balancing low carbon development, gains in resource efficiency and adaptation to climate change. The study focuses on two pilot regions - one in China (Wuxi) and one in Germany (Düsseldorf+) - and is conducted by a German-Chinese research team supported by the German Stiftung Mercator. The paper gives an overview of first outcomes of the analysis of the status quo and assessment of the most likely developments regarding GHG emissions, climate impacts and resource use in Wuxi. The project developed an emission inventory for Wuxi to identify key sectors for further analysis and low carbon scenarios. The future development of energy demand and related CO2 emissions in 2030 were simulated in the current policy scenario (CPS), using five different sub-models. Selected aspects of Wuxi's current material and water flows were analysed and modelled for energy transformation and the building sector. Current and future climate impacts and vulnerability were investigated. Recent climatic changes and resulting damages were analysed, expected changes in temperature and precipitation in the coming four decades were projected using ensembles of three General Circulation Models. Although Wuxi's government started a path to implement a low carbon plan, the first results show that more ambitious efforts are needed to overcome the challenges faced.
Energy intensive industries are one of the fields in which strong increases of energy efficiency and deep decarbonisation strategies are particularly challenging. Although European energy intensive industries have already achieved significant energy and greenhouse gas reductions in the past, much remains to be done to make a significant contribution to achieving European as well as national climate mitigation targets of greenhouse gas emission reductions by -80% or more (compared to the baseline of 1990). North Rhine-Westphalia (NRW) is a European hotspot for coping with this challenge, accommodating more than 10% of the energy intensive industries of the EU28. It is also the first German state to have adopted its own Climate Law, enacting state-wide CO2 emission reductions by 80% until 2050 compared to 1990. The state government initiated the project "Platform Climate Protection and Industry North-Rhine Westphalia" to identify and develop the necessary far-reaching low carbon innovation strategies for energy intensive industries. Heart of the project was a dialogue process, which involved a broad spectrum of stakeholders from steel, chemical, aluminium, cement, glass and paper producing industries. Besides enhancing and broadening the knowledge on high efficiency and low-carbon technologies within industries, the aim was to explore possible pathways and preconditions for the application of these technologies in energy intensive industries as well as to strengthen the motivation of companies for initiatives and investments in technologies with lower CO2 emissions. The results of the dialogue shall provide a basis for a possible low-carbon industry roadmap NRW and may also serve as an example for other industrialized regions in the EU and globally. The paper sketches the structured dialogue process with the stakeholders from companies as well as industrial associations and presents the learnings regarding the engagement of energy intensive industries into ambitious climate policies on a regional level. These include existing limitations as well as chances in the respective sectors on the state level, regarding their economic and technical structures as well as their innovation systems. The findings are based on more than a dozen stakeholder workshops with industry companies and more than 150 individual representatives of NRW's energy intensive industries as well as on background research in the initial phase of the project.
Bei der Energiewende handelt es sich um einen komplexen Transformationsprozess, der nicht allein aus der nationalen Perspektive betrachtet werden kann. Er ist nicht vollständig unabhängig, sondern in einen Mehr-Ebenen-Prozess eingebunden. Es gilt entsprechend sowohl lokale als auch regionale, nationale, europäische und auch die internationalen Energiewendeprozesse und zugehörigen Rahmenbedingungen zu diskutieren und zu beachten. Es gilt aber auch, über den eigentlichen Energiebereich hinausgehende Trends in ihren Wechselwirkungen mit dem Energiesystem zu identifizieren und zu analysieren. Mit der Energiewende wird zudem eine Zielvielfalt angesprochen. Es geht über das Erreichen von Klimaschutzzielen hinaus um eine größere Vielfalt von gesellschaftlich-politischen Zielen.
Der Transformationsprozess hat keine eindimensionale Zielorientierung, sondern muss in einer mehrdimensionalen Betrachtung analysiert werden.
Erneuerbare Energien und Energieeffizienz : Systemlösungen als Schlüsselelement der Energiewende
(2013)
Erneuerbare Energien und Energieeffizienz sind die Schlüsselstrategien für die Umsetzung einer klimaverträglichen Energieversorgung in Deutschland und weltweit. Dieser Beitrag soll die Kopplung zwischen erneuerbaren Energien und Energieeffizienz im Kontext von Systemlösungen aufzeigen. Diese Systemlösungen sollten schon sehr frühzeitig und systematisch im Kontext von technologischen Lösungen, von Infrastrukturansätzen und von Politikansätzen bedacht werden.
Die Energiewende stellt einen ambitionierten und zugleich hochkomplexen Transformationsprozess dar. Der vorliegende Artikel stellt acht Thesen auf, die dabei helfen können, die Herausforderungen besser zu verstehen und Ansatzpunkte für zukünftiges Handeln zu identifizieren sowie Forschungsbedarf aufzuzeigen.
Kommunale Wärmetransformationsprojekte verfolgen verschiedene Ziele gleichzeitig. In der Regel soll die Transformation einen Beitrag leisten, um die Treibhausgasemissionen der Wärmeversorgung zu senken. Gleichzeitig stehen aber weitere Ziele, u. a. die Sozialverträglichkeit, Akzeptanz und wirtschaftliche Tragfähigkeit im Fokus der Akteure. Dabei muss eine einseitige Zieloptimierung vermieden werden. Darüber hinaus erscheint es sinnvoll, den Beitrag der jeweiligen Konzepte zu den Nachhaltigkeitszielen im Blick zu behalten.
Im Kontext kommunaler Wärmetransformationsprojekte geht es auf der Bedarfsseite darum, die Energieverbräuche für Raum- und Prozesswärme zu senken. Die Akteure auf Seiten der Abnehmer und Wärmenutzer:innen sind u. a. gewerbliche Unternehmen, die Wohnungswirtschaft, die öffentliche Hand und die Bewohner:innen.
Auf der Versorgungsseite muss die Wärmebereitstellung von fossilen Energieträgern umgestellt werden auf regenerative Energien, wie Bioenergie, Solarthermie, Geothermie, Umgebungswärme und industrielle Abwärme. Daher treten hier als Akteure der Wärmewende nicht mehr nur Energieversorgungsunternehmen, Stadtwerke und Kommunen, sondern bspw. auch Industrieunternehmen als Abwärmequellen und Selbsterzeuger auf.
Dieser Beitrag ordnet zunächst eine multikriterielle Nachhaltigkeitsbewertung in das Vorgehen kommunaler Wärmetransformationsprojekte ein. Anschließend werden Ansätze einer multikriteriellen Nachhaltigkeitsbewertung aus Projekten von FVEE- Mitgliedseinrichtungen dargestellt. Der dritte Abschnitt schließlich zeigt, wie diese in der Interaktion und Kommunikation mit den Akteuren genutzt werden können.
Dieser Artikel ist der Frage gewidmet, welchen Beitrag eine verstärkte Sektorenkopplung zum Gelingen der Energiewende leisten kann. Ausgehend von einer Einführung der Prinzipien und Technologien bietet er Einblicke in die zur Erforschung der Sektorenkopplung angewendeten Methoden, sowie ausgewählte Ergebnisse.
Hinsichtlich der Energieversorgung versteht man unter Sektorenkopplung im Allgemeinen eine engere Verzahnung und Verknüpfung verschiedener Energieanwendungsbereiche, sowie die Zunahme von Verzweigungs- und Verknüpfungsstellen im Energiesystem. Die wesentlichen Anwendungsbereiche der Energie sind dabei die Bereitstellung von Strom, Wärme und Mobilität.
Mit dem European Green Deal hat Europa seine Klimaschutzziele nach oben korrigiert und einen weiteren, erforderlichen Schritt auf dem Weg zur Dekarbonisierung unternommen. Die neuen europäischen Zielvorgaben sind in Deutschland mit der Verabschiedung des Klimaschutzgesetzes seit Ende 2019 schon verbindlich festgeschrieben, wobei hier bereits spezifische CO2-Budgets für die Einzelsektoren definiert werden. Die Umsetzung dieser Ziele verlangt eine radikale Transformation des heutigen Energieversorgungssystems.
Der Umbau des komplexen und heterogenen Wärmebereiches stellt dabei eine der größten Herausforderung dar: Wärme ist in Europa für über 50 % des Endenergieverbrauches verantwortlich, wird aber gegenwärtig nur zu 22 % aus erneuerbaren Quellen bereitgestellt. Aus geoklimatischen, kulturellen und politischen Gründen sind dabei die Anteile in den einzelnen europäischen Ländern sehr unterschiedlich. Unter den Spitzenreitern sind Schweden (66 %) und Dänemark (48 %). Unser Nachbarland Österreich erreicht immerhin 34 %. Im Vergleich dazu liegt Deutschland mit 15 % abgeschlagen auf einem hinteren Platz.
Der verstärkte Einsatz erneuerbarer Energien ist neben der Steigerung der Energieeffizienz die tragende Säule der Wärmewende, wobei hier ein breiter Mix an Technologien gefragt ist.
Die direkte Nutzung der Wärmetechnologien hat weiterhin Priorität, erfordert aber eine stark beschleunigte Erschließung der vorhandenen Potenziale sowie einen nachhaltigen Umgang mit wertvoller Biomasse.
Die Sektorenkopplung bietet die notwendige Ergänzung für die geplante Transformation (BMWi, 2021). Solarenergie in Form von Solarwärme und Solarstrom wird somit in Kombination mit Umweltwärme eine zentrale Rolle im zukünftigen Wärme- und Kälteversorgungssystem spielen. Darauf fokussiert sich der Beitrag, wobei die spezifische Situation der Niedertemperatur-Solarthermie und der Schlüsseltechnologie Wärmepumpe adressiert werden.
Nach einer langen Phase der Stabilität ist die Stromwirtschaft in den vergangenen 15 Jahren stark in Bewegung geraten. Zunächst stand der Wechsel von staatlich überwachten und regulierten Gebietsmonopolen hin zu liberalisierten Erzeuger- und Verbrauchermärkten an. Im Moment befinden wir uns in einem ähnlichen Umbruch, weg von konventioneller hin zu erneuerbarer Energieerzeugung.
Im vorliegenden Beitrag soll der Leitfrage nachgegangen werden, ob die Paradigmen der einzelnen Phasen miteinander vereinbar sind, welche noch immer ihre Daseinsberechtigung haben und welche modifiziert werden sollten.
De-industrialization, climate and demographic changes are only a few key words that indicate the challenge of urban development in many industrialized countries for the coming decades. A fundamental transformation of infrastructure and the built environment is expected to adjust to future needs. Numerous concepts of integrating efficiency and renewable energy sources into urban planning were elaborated in recent years. Energy sufficiency in the meaning of voluntary demand reduction of energy intensive goods and services is the third and mostly forgotten pillar of sustainable development. However, organizational and spatial measures are needed to support behavior modification. This paper presents results of a transdisciplinary research design with local stakeholders and scientific experts to develop an understanding of what energy sufficiency might contribute to sustainable urban development. Based on the Multi-Level-Perspective of the transition research approach, it analyzes how stakeholders and experts define energy sufficiency structures for the shrinking district of Vohwinkel (Germany). The paper also shows a compilation and evaluation of measures which facilitate energy sufficient behavior in the fields of space heating and passenger transport on a local level. The methodological concept comprises expert interviews, thought experiments with stakeholders to develop a vision of an "energy sufficient Vohwinkel 2050" as well as a stakeholder workshop to discuss the results. A shrinking population is seen as a chance to actively adapt the built environment to foster energy sufficiency.
Contemporary combined heat and power (CHP) systems are often based on fossil fuels, such as natural gas or heating oil. Thereby, small-scale cogeneration systems are intended to replace or complement traditional heating equipment in residential buildings. In addition to space heating or domestic hot water supply, electricity is generated for the own consumption of the building or to be sold to the electric power grid.
The adaptation of CHP-systems to renewable energy sources, such as solid biomass applications is challenging, because of feedstock composition and heat integration. Nevertheless, in particular smallscale CHP technologies based on biomass gasification and solid oxide fuel cells (SOFCs) offer significant potentials, also regarding important co-benefits, such as security of energy supply as well as emission reductions in terms of greenhouse gases or air pollutants. Besides emission or air quality regulations, the development of CHP technologies for clean on-site small-scale power generation is also strongly incentivised by energy efficiency policies for residential appliances, such as e.g. Ecodesign and Energy Labelling in the European Union (EU). Furthermore, solid residual biomass as renewable local energy source is best suited for decentralised operations such as micro-grids, also to reduce long-haul fuel transports. By this means such distributed energy resource technology can become an essential part of a forward-looking strategy for net zero energy or even smart plus energy buildings.
In this context, this paper presents preliminary impact assessment results and most recent environmental considerations from the EU Horizon 2020 project "FlexiFuel-SOFC" (Grant Agreement no. 641229), which aims at the development of a novel CHP system, consisting of a fuel flexible smallscale fixed-bed updraft gasifier technology, a compact gas cleaning concept and an SOFC for electricity generation. Besides sole system efficiencies, in particular resource and emission aspects of solid fuel combustion and net electricity effects need to be considered. The latter means that vastly less emission intensive gasifier-fuel cell CHP technologies cause significant less fuel related emissions than traditional heating systems, an effect which is further strengthened by avoided emissions from more emission intensive traditional grid electricity generation. As promising result, operation "net" emissions of such on-site generation installations may be virtually zero or even negative. Additionally, this paper scopes central regulatory instruments for small-scale CHP systems in the EU to discuss ways to improve the framework for system deployment.
Der schnell fortschreitende Digitalisierungs- und Automatisierungsprozess ist heute schon ein wichtiger Wegbegleiter für die Transformation des aktuellen Energiesystems. Im vorliegenden Beitrag werden sechs Anwendungsbeispiele vorgestellt, die deutlich machen, dass die Energiewende ohne Digitalisierung nicht denkbar ist.
Der Klimawandel stellt uns vor die globale Herausforderung, auf fossile Energieträger zu verzichten. Die erfolgreiche Transformation des Energiesystems ist eine wesentliche Voraussetzung für eine vollständige Reduktion der Treibhausgase. Eine solche Transformation kann nur gelingen, wenn der fundamental neue Charakter des Systems erfasst und im abgeleiteten Rückschluss daraus der passende Pfad eingeschlagen wird. Im Kern lässt sich dieser neue Charakter als ein defossilisiertes, auf regenerativen Energien basierendes Energiesystem beschreiben.
Welche Rolle spielt die Digitalisierung mit der Vielzahl ihrer Methoden und Anwendungen für die Energiewende - also für die Transformation unseres Energiesystems im Sinne der vereinbarten Klimaschutzziele? Ist sie notwendige Voraussetzung für den Systemumbau und ermöglicht beispielsweise erst den Übergang auf ein nahezu vollständig erneuerbares Energiesystem (Enabler) oder ist sie lediglich ein nützliches, den Umbau beschleunigendes Hilfsmittel (Facilitator)? Welche Veränderungen sind durch die Ziele der Energiewende getrieben und welche durch die Verbreitung von Techniken der Digitalisierung? All dies waren Fragen, die im Rahmen der Jahrestagung 2018 des Forschungsverbunds Erneuerbare Energien unter dem Titel "Die Energiewende - smart und digital" behandelt wurden. Dieser einführende Beitrag versucht einige Anhaltspunkte zur Beantwortung dieser Fragen zu liefern und in das Thema einzuführen.
Die Transformation des deutschen Energiesystems in Richtung signifikanter Reduktion energiebedingter CO2-Emissionen kann durch eine Abfolge verschiedener Phasen beschrieben werden. Phasenübergänge ergeben sich dabei aus strukturellen Erfordernissen im Gesamtsystem bei kontinuierlichem weiteren Ausbau erneuerbarer Energiewandler, insbesondere Sonne und Wind. Die anstehende zweite Phase der Transformation ist durch eine umfassende Systemintegration volatiler erneuerbarer Energien insbesondere im Bereich der Strombereitstellung geprägt. Dies erfordert sowohl eine flexible komplementäre Erzeugung als auch die Aktivierung von Flexibilitätsoptionen auf der Verbrauchsseite.
Die Bundesrepublik Deutschland hat sich zum Ziel gesetzt, bis 2045 klimaneutral zu werden. Das kann nur funktionieren, wenn fossile Rohstoffe durch erneuerbare Energien ersetzt werden - insbesondere in den Bereichen Industrie und Verkehr. Ein wesentlicher Baustein in diesem Transformationsprozess ist die Errichtung einer Wasserstoffwirtschaft, innerhalb derer Strom aus erneuerbaren Energien in grünen Wasserstoff umgewandelt und dieser als Energieträger vor allem in den Bereichen Industrie und Verkehr angewendet wird.
There is an increasing pressure that enhanced and novel energy technologies are swiftly adopted by the market to ensure meeting the energy and climate targets. An important issue with such novel developments is their risk to be stuck in the "valley of death", i.e. that their transition to the market is delayed or unsuccessful. Publicly supported demonstration projects could help to bridge the valley of death by reducing barriers to the adoption caused by missing information and perceived risks. A challenge for technology demonstrations in the industrial context is their often high investments that are required to prove their real-world benefits. Given the magnitude of such investments, it becomes crucial that public funding focuses on the most promising demonstration proposals. Structured evaluation processes can help to facilitate the identification of promising proposals and to improve the quality and transparency of decisions. This paper deals with a corresponding multi-staged multi-criteria decision support system (DSS) suggested to the German Federal Ministry for Economic Affairs and Energy. It deals with the evaluation of demonstration proposals across three stages: The first stage represents a filtering stage to identify those proposals relevant for further considerations. The second stage comprises a multi-criteria scoring method drawing on an evaluation against nineteen criteria. The final third stage serves to critically review the need for public funding of well-scored proposals. This contribution outlines the development of the DSS and its design and thus provides insights on proposal evaluating in energy research.
Technologische Innovationen in den Bereichen erneuerbare Energien und Energieeffizienz bilden eine wesentliche Grundlage der weltweiten Energiesystemtransformation und wirken bei geeigneter Implementierung als Wertschöpfungsmotor. Die Größe und erhebliche Wachstumsdynamik der internationalen Märkte für Energietechnologien und -systeme macht die Positionierung deutscher Unternehmen auf diesen Märkten daher zu einem Thema von sehr weitreichender wirtschaftspolitischer Relevanz. Daraus ergibt sich die Frage, wie Deutschland von einer konsequenten Umsetzung der Energiewende und seiner damit verbundenen Vorreiterfunktion auf den internationalen Märkten für Energietechnologien profitieren kann.
Jordan's electricity system has and continues to experience considerable pressures for reform due to continuous increase of electricity demand combined with high dependency on imported fossil fuels and a partially subsidised electricity market. In this paper we use the transitions pathways to examine and analyse pressures on the regime in relation to plausible future developments of particular niches such as renewable energy technologies. Our analysis is methodologically distinct in that we explicitly identify mechanisms operating in the system and relate those to existing scenarios to assess future developments. Currently, we see future developments being sensitive to the actions of key regime actors.
Es besteht Einvernehmen, dass die hohe Komplexität des Wärmesystems das zentrale Hindernis für die Wärmewende darstellt: Der Wärmebedarf im Industrie- und Gebäudesektor ist durch unterschiedliche Temperatur- und Nachfrageprofile aber auch durch verschiedene Geschäftsmodelle gekennzeichnet. Im Gebäudebereich sind darüber hinaus auch die vielfältigen Erwartungen und Präferenzen der Millionen von Investoren und Nutzern entscheidend, die über rein techno-ökonomische Überlegungen hinausgehen. Diese Systemkomplexität erschwert die Entwicklung von Strategien im Wärmesektor und hemmt unter anderem auch die Möglichkeiten für Technologieentwickler das Marktpotenzial ihrer Innovationen einzuschätzen.
Fragen der Akzeptanz müssen folglich auf mehreren Ebenen Berücksichtigung finden, von Fragestellungen der Gesamtsystemanalyse bis hin zu einzelnen Umsetzungsprojekten. Entsprechend vielfältig ist die Forschung zur gesellschaftlichen Akzeptanz der Wärmwende im FVEE. Sie umfasst sowohl die Analyse von Nutzerpräferenzen bis hin zur gemeinsamen Gestaltung von Energiewendeprojekten, um die Gelingensbedingungen zu verbessern.
Allen Ansätzen ist gemein, dass die vorherrschende technisch-ökonomische Betrachtung der Wärmewende erweitert wird: Es wird nach Faktoren geforscht, welche die Nutzer*innen beeinflussen und es werden gezielt Bereiche untersucht, welche das Potenzial für zukünftige Akzeptanzkonflikte haben. Des Weiteren gibt es Ansätze, die Akzeptanzfragen bereits im Entwicklungsprozess von Innovationen zu berücksichtigen. Abschließend, in Bezug auf die konkrete Umsetzung von Wärmetransformationsprojekten, werden verschiedene Methoden des Co-Designs entwickelt, erforscht und getestet. Im Folgenden werden einzelne Projekte aus den verschiedenen Bereichen vorgestellt.
Energy systems with high shares of renewable electricity are feasible, but require balancing measures such as storage, grid exchange or demand-side management to maintain system stability. The demand for these balancing options cannot be assessed separately since they influence each other. Therefore, a model was developed to analyze these mutual dependencies by optimizing a concerted use of balancing technologies. This model is presented here. It covers the European electricity system in hourly resolution. Since this leads to a large optimization problem, several options for reducing system complexity are presented. The application of the model is illustrated with a case study outlining the effects of pumped hydro storage and controlled charging of electric vehicles in central Europe.
Die Wahrung der Systemsicherheit muss perspektivisch von konventionellen Kraftwerken auf regenerative Energien und Kraft-Wärme-Kopplungsanlagen (KWK) verlagert werden. Diese sollen zukünftig Systemdienstleistungen übernehmen, um in zunehmendem Maße fluktuierende erneuerbare Energien (FEE) zu integrieren. Deutschland strebt an, im Jahr 2020 ein Viertel der elektrischen Energie aus KWK-Anlagen zu erzeugen. Damit werden diese Anlagen einen wesentlichen Teil der regelbaren Stromerzeugung ausmachen. Insbesondere die Erzeugung in dezentralen Blockheizkraftwerken (BHKW) wird zunehmen. Vor diesem Hintergrund stellt sich die Frage, ob dezentrale Anlagen überhaupt nennenswert zur Systemstabilität beitragen können.
Wind energy that can neither be fed into the grid nor be used regionally must be curtailed. This paper proposes different options to deal with such surplus wind energy amounts in a time horizon until 2020. It assesses their ability to handle the surplus energy in a sustainable way using a multi criteria analysis. The paper bases on a study that was prepared for the Ministry for Climate Protection, Environment, Agriculture, Nature Conservation and Consumer Protection of North Rhine-Westphalia between 2010 and 2012.
Im Rahmen einer aktuellen Studie zur Transformation des Europäischen Energiesystems zur Klimaneutralität unter Berücksichtigung der Gaskrise entwickelte das Wuppertal Institut ein Szenario (EU27+UK) für die Transformation der europäischen Industrie inklusive Raffinerien und Kokereien, in dem die industriellen Treibhausgasemissionen bis zum Jahr 2050 um 99 % gegenüber 2018 gemindert werden. Der Endenergiebedarf der Industrie sinkt in diesem Szenario durch den Einsatz von Wärmepumpen, andere Energieeffizienzmaßnahmen sowie einen Rückgang der Produktion in Raffinerien bis 2040 deutlich und der Bedarf an fossilen Gasen kann zeitnah gemindert und bis 2045 auf nahezu Null gesenkt werden.
Im Rahmen dieses Szenarios erfolgte auch eine detaillierte Abbildung der Entwicklung der Prozesswärmebereitstellung in Deutschland. Die Bereit- stellung von Niedertemperaturwärme (< 150 °C) erfolgt im Szenario größtenteils über Wärmepumpen und Fernwärme. Solar- und Geothermie spielen eine (kleinere) Rolle. Für die Dampfbereitstellung (150 - 500 °C) werden vielfach hybride Strom/H2-Kessel eingesetzt, daneben Biomasse. In der Chemieindustrie spielen auch langfristig Reststoffe aus Steamcrackern eine wichtige Rolle.
Die Bereitstellung von Hochtemperaturwärme erfolgt prozessspezifisch je nach den technischen Gegebenheiten der Prozesse (z. B. H2 in den Direktreduktions- anlagen und Biomasse in den Walzwerken der Stahlindustrie, abfallbasierte Brennstoffe vor allem in den Klinkeröfen der Zementindustrie, Biomethan und Strom in der Glasindustrie, Strom für Primär- und Sekundäraluminium). Biogene Energieträger in Kombination mit CCS (BECCS) ermöglichen in der Stahlindustrie und in der mineralischen Industrie die Bereitstellung von Hochtemperaturwärme und gleichzeitig negative Emissionen zur Kompensation von Restemissionen.
Under the framework of the UN framework convention on climate change (UNFCCC) and its Kyoto Protocol the targets and strategies for the second and third commitment period ("post-2012") have to be discussed and set in the near future. Regarding the substantial emission reductions that have to be shouldered by the industrialized nations over the next two decades it is evident that all available potentials to mitigate greenhouse gas (GHG) emissions have to be harnessed and that energy efficiency has to play a key role.
To substantiate this we developed a comprehensive scenario analysis of the EU 25s energy system and other greenhouse gas emissions until 2020. Our analysis shows which key potentials to mitigate greenhouse gas emissions are available, by which policies and measures they are attainable
and which will be benefits of greenhouse gas mitigation measures.
By this analysis we show the mayor role of energy efficiency in all sectors and all member states. We demonstrate that a reduction of EU 25 greenhouse gas emissions by more than 30 % by 2020 is feasible, reasonable and - to a large extent - cost effective. We also develop a comprehensive policy package necessary to achieve ambitious Post-Kyoto targets.
The scenario analysis results in a clear identification of the needed strategies, policies and measures and especially the relevance of energy efficiency to achieve the necessary ambitious greenhouse gas reduction targets. It also clearly shows the costs and the benefits of such a policy compared to a business as usual case.
Several low-carbon energy roadmaps and scenarios have recently been published by the European Commission and the International Energy Agency (IEA) as well as by various stakeholders such as Eurelectric, ECF and Greenpeace. Discussions of these studies mainly focus on technology options available on the electricity supply side and mostly omit the significant challenges that all of the scenarios impose on the energy demand side.
A comparison of 5 decarbonisation scenarios from 4 of the most relevant recent scenario studies for the EU shows that all of them imply significant efficiency improvements in traditional appliances, usually well above levels historically observed over longer periods of time. At the same time they assume substantial electrification of transportation and heating. The scenarios suggest that both of these challenges need to be tackled successfully for decarbonising the energy system.
With shares of renewable electricity reaching at least 60 % of supply in 2050 in almost all of the decarbonisation scenarios, the adaptation of demand to variable supply becomes increasingly important. This aspect of demand side management should therefore be part of any policy mix aiming for a low-carbon power system.
Based on a quantitative analysis of 5 decarbonisation scenarios and a comparison with historical evidence we derive the (implicit) new challenges posed by the current low-carbon roadmaps and develop recommendations for energy policy on the electricity demand side.
The EU aims to become the first climate neutral continent. To achieve this goal, the industry sector needs to reduce its GHG emissions to net zero or at least close to net zero. This is a particularly challenging task due to the high energy demand especially of primary materials production and the little potential to reduce this energy intensity when switching to other production processes based on electricity or hydrogen. In order to identify robust strategies for achieving a net-zero-compatible industry sector, the paper at hand analyses the transformation of the industry sector as described by a number of recent climate neutrality scenarios for Germany. Apart from overall industry, a focus is set on the sectors of steel, chemicals and cement. The analysed scenarios show very deep GHG emission reductions in industry and they appear to be techno-economically feasible by the mid of the century, without relying on offsets or on shifts from domestic production to imports. The scenarios agree on a suite of core strategies to achieve this, such as direct and indirect electrification, energy efficiency and recycling as well as new technological routes in steel making and cement. The scenarios differ, however, regarding the future mix of electricity, hydrogen and biomass and regarding the future relevance of domestic production of basic chemicals.
International consensus is growing that a transition towards a low carbon society (LCS) is needed over the next 40 years. The G8, the Major Economies Forum on Energy and Climate, as well as the Ad Hoc Working Group on Long-term Cooperative Action under the United Nations Framework Convention on Climate Change, have concluded that states should prepare their own Low-emission Plans or Low-emission Development Plans and such plans are in development in an increasing number of countries.
An analysis of recent long-term low emission scenarios for Germany shows that all scenarios rely heavily on a massive scale up of energy efficiency improvements based on past trends. However, in spite of the high potential that scenario developers assign to this strategy, huge uncertainty still exists in respect of where the efficiency potentials really lie, how and if they can be achieved and how much their successful implementation depends on more fundamental changes towards a more sustainable society (e.g. behavioural changes).
In order to come to a better understanding of this issue we specifically examine the potential for energy efficiency in relation to particular demand sectors. Our comparative analysis shows that despite general agreement about the high importance of energy efficiency (EE), the perception on where and how to achieve it differ between the analysed scenarios. It also shows that the close nexus between energy efficiency and non-technical behavioural aspects is still little understood. This leads us to the conclusion that in order to support energy policy decisions more research should be done on energy efficiency potential. A better understanding of its potential would help energy efficiency to fulfil its role in the transition towards a LCS.
Following the decisions of the Paris climate conference at the end of 2015 as well as similar announcements e.g. from the G7 in Elmau (Germany) in the summer of 2015, long-term strategies aiming at (almost) full decarbonisation of the energy systems increasingly move into the focus of climate and energy policy. Deep decarbonisation obviously requires a complete switch of energy supply towards zero GHG emission sources, such as renewable energy. A large number of both global as well as national climate change mitigation scenarios emphasize that energy efficiency will likewise play a key role in achieving deep decarbonization. However, the interdependencies between a transformation of energy supply on the one hand and the role of and prospects for energy efficiency on the other hand are rarely explored in detail.
This article explores these interdependencies based on a scenario for Germany that describes a future energy system relying entirely on renewable energy sources. Our analysis emphasizes that generally, considerable energy efficiency improvements on the demand side are required in order to have a realistic chance of transforming the German energy system towards 100 % renewables. Efficiency improvements are especially important if energy demand sectors will continue to require large amounts of liquid and gaseous fuels, as the production of these fuels are associated with considerable energy losses in a 100 % renewables future. Energy efficiency on the supply side will therefore differ considerably depending on how strongly the use of liquid and gaseous fuels in the various demand sectors can be substituted through the direct use of electricity. Apart from a general discussion of the role of energy efficiency in a 100 % renewable future, we also look at the role of and prospects for energy efficiency in each individual demand sector.
Based on a comprehensive scenario analysis of the EU's GHG emissions by 2020, we show that the 20% energy savings target set in the Action Plan "Doing more with less" in 2006 is still the most significant and thus indispensable strategy element within an ambitious EU climate and energy strategy targeting at a 30% reduction of GHG emissions by 2020.
The scenario analysis provides a sector by sector projection of potential future energy use and GHG emissions, combined with a detailed policy analysis of the core policies on energy efficiency by the EU and its Member States taken from current research results by the authors and others.
Consequently the paper identifies and quantifies the current implementation deficit in the EU and shows that, despite of sufficient targets, implementation is still significantly lacking in almost all fields of energy efficiency. Some, e.g. transport sector and buildings, are still substantially far from receiving the necessary political impetus. The paper also demonstrates co-benefits of a strong energy efficiency strategy, e.g. the achievability of the targets of the RES directive, which crucially depends on a strong efficiency policy.
We conclude that the efforts of the energy efficiency policy of the EU and its Member States have to be significantly intensfied. As proposed by the EU in case that other developed and key developing countries take up comparable targets in order to fulfil its role in the climate and energy strategy. To achieve this, we offer an analysis of the current weaknesses of EU energy efficiency policy and derive recommendations on how the EU can still reach its targets for 2020.
Ausgangspunkt einer Bewertung des Standes der Energiewende ist die Verständigung darüber, was sie konkret umfasst. Hier bietet sich die Zielmatrix des Energiekonzepts der Bundesregierung vom Herbst 2010 an, die allerdings um folgende Punkte zu erweitern ist: vollständiger Ausstieg aus der Atomenergie bis zum Jahr 2022; Steigerung des Anteils der Kraft-Wärme-Kopplung an der gesamten Stromerzeugung bis 2020 auf 25 Prozent.
The unprecedented challenge of reaching carbon neutrality before mid-century and a large share of it within 2030 in order to keep under the 1.5 or 2 °C carbon budgets, requires broad and deep changes in production and consumption patterns which, together with a shift to renewables and reinforced efficiency, need to be addressed through energy sufficiency. However, inadequate representations and obstacles to characterising and identifying sufficiency potentials often lead to an underrepresentation of sufficiency in models, scenarios and policies.
One way to tackle this issue is to work on the development of sufficiency assumptions at a concrete level where various implications such as social consequences, environmental co-benefits, conditions for implementation can be discussed. This approach has been developed as the backbone of a collaborative project, gathering partners in 20 European countries at present, aiming for the integration of harmonised national scenarios into an ambitious net-zero European vision.
The approach combines a qualitative discussion on the role of energy sufficiency in a "systemic" merit order for global sustainability, and a quantitative discussion of the level of sufficiency to be set to contribute to meeting 100 % renewables supply and net-zero emissions goals by 2050 at the latest. The latter is based on the use of a dashboard, which serves as a common descriptive framework for all national scenario trajectories and their comparison, with a view to harmonising and strengthening them through an iterative process.
A set of key sufficiency-related indicators have been selected to be included in the dashboard, while various interrelated infrastructural, economic, environmental, social or legal factors or drivers have been identified and mapped. This paves the way for strengthening assumptions through the elaboration of "sufficiency corridors" defining a convergent, acceptable and sustainable level of energy services in Europe. The process will eventually inform the potential for sufficiency policies through a better identification of leverages, impacts and co-benefits.
Wasserelektrolyse und regenerative Gase als Schlüsselfaktoren für die Energiesystemtransformation
(2013)
The reduction of greenhouse gas (GHG) emissions by energyintensive industries to a net zero level is a very ambitious and complex but still feasible challenge, as recent studies show for the EU level. "Industrial Transformation 2050" by Material Economics (2019) is of particular relevance, as it shows how GHG-neutrality can be achieved in Europe for the sectors chemicals (plastics and ammonia), steel and cement, based on three main decarbonisation strategies. The study determines the resulting total demands for renewable electricity, hydrogen and for the capture and storage of CO2 (CCS). However, it analyses neither the regional demand patterns that are essential for the required infrastructure nor the needed infrastructure itself.
Against this background the present paper determines the regional distribution of the resulting additional demands for electricity, hydrogen and CCS in Europe in the case that the two most energy and CCS intensive decarbonisation strategies of the study above will be realised for the existing industry structure. It explores the future infrastructure needs and identifies and qualitatively assesses different infrastructure solutions for the largest industrial cluster in Europe, i.e. the triangle between Antwerp, Rotterdam and Rhine-Ruhr. In addition, the two industrial regions of Southern France and Poland are also roughly examined.
The paper shows that the increase in demand resulting from a green transformation of industry will require substantial adaptation and expansion of existing infrastructures. These have not yet been the subject of infrastructure planning. In particular, the strong regional concentration of additional industrial demand in clusters (hot spots) must be taken into account. Due to their distance from the high-yield but remote renewable power generation potentials (sweet spots), these clusters further increase the infrastructural challenges. This is also true for the more dispersed cement production sites in relation to the remote CO2 storage facilities. The existing infrastructure plans should therefore be immediately expanded to include decarbonisation strategies of the industrial sector.
Conventional new buildings in OECD countries with a history of building codes save about 50 % of energy compared to average buildings in the building stock. This improvement, however, is not enough to create a building standard with low lifetime costs nor to reach long-term climate protection targets. Much higher energy savings can already be achieved through proven high-efficiency building concepts bringing net economic benefits among other advantages.
A strategic approach to integrated building design is the key to achieving these high-energy savings at low or no extra cost in residential buildings. In our paper we describe the "Easy Efficiency Approach", which can reduce primary energy consumption by 40 to 60 % compared to conventional new building standards, or by 70% to 80% when compared to the primary energy consumption of the existing building stock, and should be regarded as the minimum. This strategy focuses on low-cost options, mainly passive options. Although it can already significantly reduce energy consumption, this first step will not be sufficient to reach long-term climate protection goals. It is thus necessary to implement and support what we call an "Advanced Efficiency Approach", with savings up to 90% , as compared to new building standards, as soon as possible to avoid lock-in effects. Further improvements, especially through the active use of renewable energies, reduce the net primary energy demand to 0 % and beyond.
According to the chosen strategy clearly defined energy performance ranges, with reference to possible savings, for different climate zones worldwide are given. In verifying this approach simulations with BAT (Best Available Technologies) buildings of different types (single family, multi family, high rise) were carried out in close cooperation with project partners. This data has also been verified through an empirical database of built examples both for energy consumption as well their economic soundness.
Szenarien spielten und spielen eine zentrale Rolle für die Gestaltung der Energiewende. Sie beschreiben dabei auf konsistente Weise die mögliche zukünftige Entwicklung des Systems unter bestmöglicher Berücksichtigung des aktuellen Wissens bezüglich des Systems, d.h. der internen Abhängigkeiten und Wechselwirkungen der Systemkomponenten, aber auch die Abhängigkeit der Systementwicklung von äußeren Faktoren. Damit liefern Szenarien Leitplanken für zentrale technisch-strukturelle, energiepolitische, ökonomische und gesellschaftliche Weichenstellungen, die einen zielgerichteten Transformationsprozess flankieren müssen.
Das Energiesystem der Zukunft wird stark durch Elektrifizierung geprägt sein. Für die Langzeitspeicherung von Energie sowie für Bereiche, die sich nicht sinnvoll durch Strom defossilieren lassen, werden aber auch in Zukunft chemische Energieträger benötigt. Das Ziel der Klimaneutralität bedingt, dass diese Energieträger vollständig emissionsfrei aus erneuerbaren Energien (EE) hergestellt werden. Diese grünen Energieträger sind transportier- und handelbar, sodass sich ein internationaler Markt für grünen Wasserstoff und seine Folgeprodukte entwickeln wird.
Derzeit gibt es diesen Markt noch nicht. Grüner Wasserstoff ist preislich noch nicht konkurrenzfähig gegenüber fossilen Brennstoffen. Den größten Anteil am Wasserstoffpreis haben die Kosten für die Elektrolyseanlage sowie die Kosten für die Strombereitstellung. Die besten Bedingungen für die Wasserstoffproduktion bieten daher EE-Standorte und Technologien mit hohen Volllaststundenzahlen, an denen auch der Elektrolyseur bei wenig EE-Abregelung auf viele Betriebsstunden kommt.
Im Rahmen der Energiewende haben sich erneuerbare Energien zur Stromerzeugung in Deutschland bereits etabliert. Um jedoch das volle Potenzial der Reduktion von fossilen Energien und Treibhausgasen (THG) auszuschöpfen, muss aus der Energiewende auch eine Wärmewende werden. Der Energieeinsatz für die Wärmebereitstellung der Industrie betrug im Jahr 2012 etwa 535 TWh (22 % des Endenergiebedarfs Deutschlands), hauptsächlich bereitgestellt durch Erdgas (48 %) und Steinkohle (17 %) 1. Damit wurden für die Wärmebereitstellung im Industriesektor rund 159 Mio. t CO2-äq emittiert, was 17 % der THG-Emissionen Deutschlands entspricht.
Aufgrund der Vielseitigkeit der einzelnen Branchen und Wärmeanwendungen im Industriesektor kann dieser Beitrag nur beispielhaft einzelne Komponenten für eine Wärmewende aufzeigen, die auch wiederum die Aktivitäten der einzelnen Autoren widerspiegeln. Ausgehend von einer nationalen Betrachtung und expliziten Modellierungsergebnissen für die energieintensive Industrie in NRW, werden einzelne Potenziale und Aktivitäten im Bereich der Wärmebereitstellung, -speicherung und -integration behandelt.
Impacts of energy use on demand for freight transport : past development and future perspectives
(2005)
For some time, 3D printing has been a major buzzword of innovation in industrial production. It was considered a game changer concerning the way industrial goods are produced. There were early expectations that it might reduce the material, energy and transport intensity of value chains. However for quite a while, the main real world applications of additive manufacturing (AM) have been some rapid prototyping and the home-based production of toys made from plastics. On this limited basis, any hypotheses regarding likely impacts on industrial energy efficiency appeared to be premature. Notwithstanding the stark contrast between early hype and practical use, the diffusion of AM has evolved to an extent that at least for some applications allows for a preliminary assessment of its likely implications for energy efficiency.
Unlike many cross-cutting energy efficiency technologies, energy use of AM may vary substantially depending on industry considered and material used for processing. Moreover, AM may have much greater repercussions on other stages of value chains than conventional cross-cutting energy efficiency technologies. In case of AM with metals the following potential determinants of energy efficiency come to mind:
- A reduction of material required per unit of product and used during processing;
- Changes in the total number and spatial allocation of certain stages of the value chain; and
- End-use energy efficiency of final products.
At the same time, these various streams of impact on energy efficiency may be important drivers for the diffusion of AM with metals. This contribution takes stock of AM with metals concerning applications and processes used as well as early evidence on impacts on energy efficiency and combine this into a systematic overview. It builds on relevant literature and a case study on Wire Arc Additive Manufacturing performed within the REINVENT project.
Solarthermische Kraftwerke
(2018)
Der Schutz des Klimas und die dafür erforderliche Umstellung der Energieversorgung auf erneuerbare Energien ist eine globale Herausforderung, welche nach maßgeschneiderten Lösungen für die unterschiedlichen Klimazonen und Märkte der Erde verlangt. Die verstärkte Solarenergienutzung spielt dabei eine maßgebliche Rolle. Die Rolle Deutschlands als Exportnation beschränkt sich hierbei nicht auf die Klimawende im eigenen Land, sondern beinhaltet auch den weltweiten Export erneuerbarer Energietechnologien.
Die Kosten der photovoltaischen Stromerzeugung (PV) und der Windkraft sind in den vergangenen Jahren erfreulicherweise deutlich gesunken, entsprechend wurden in vielen Ländern große Kapazitäten zugebaut. Die resultierende stark gestiegene Einspeisung fluktuierender Erzeuger stellt Netzbetreiber vor neue Herausforderungen, insbesondere durch die extremen Lastschwankungen für plan- und steuerbare, heute größtenteils fossil befeuerte konventionelle Kraftwerke.
Hier bieten solarthermische Kraftwerke Lösungen.
Die Transformation des Energieversorgungssystems zu einer dekarbonisierten Energiebereitstellung bedingt ein koordiniertes Zusammenspiel der Sektoren Strom, Wärme und Verkehr. Dabei ist die Kopplung des Stromsektors mit dem Wärmesektor eine der entscheidenden Maßnahmen bei der Transformation. Die Aufnahme von Wind- und Sonnenenergie in das Netz kann durch genaue Einspeiseprognosen optimiert werden, die Kopplung zum Wärmesektor mittels Wärmepumpen und Power-to-Heat (Heizstab) ermöglicht die weitere Flexibilisierung der Nachfrageseite. Diese Interaktion wird durch intelligente Lösungen der Systemtechnik für das Energie- und Netzmanagement ermöglicht. Die Entwicklung von entsprechenden Anreizsystemen, Marktmechanismen und Geschäftsmodellen ist ebenfalls erforderlich, um diese Kopplung auch wirtschaftlich erfolgreich zu gestalten. Der Beitrag stellt das im Forschungsvorhaben "Interaktion EE-Strom, Wärme und Verkehr" erstellte 80-Prozent-Szenario für das Jahr 2050 vor und zeigt anhand von Beispielen zukünftige Anforderungen und Entwicklungen zu dieser Thematik auf.
This paper analyses and compares industry sector transformation strategies as envisioned in recent German, European and global deep decarbonisation scenarios.
The first part of the paper identifies and categorises ten key strategies for deep emission reductions in the industry sector. These ten key strategies are energy efficiency, direct electrification, use of climateneutral hydrogen and/or synthetic fuels, use of biomass, use of CCS, use of CCU, increases in material efficiency, circular economy, material substitution and end-use demand reductions. The second part of the paper presents a meta-analysis of selected scenarios, focusing on the question of which scenario relies to what extent on the respective mitigation strategies.
The key findings of the meta-analysis are discussed, with an emphasis on identifying those strategies that are commonly pursued in all or the vast majority of the scenarios and those strategies that are only pursued in a limited number of the scenarios. Possible reasons for differences in the choice of strategies are investigated.
The paper concludes by deriving key insights from the analysis, including identifying the main uncertainties that are still apparent with regard to the future steps necessary to achieve deep emission reductions in the industry sector and how future research can address these uncertainties.