Zukünftige Energie- und Industriesysteme
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Als Direct Air Capture (DAC) werden Technologien zur Abscheidung von Kohlendioxid aus der Atmosphäre bezeichnet. Diese könnten zunehmend zum Einsatz kommen, um CO2 für Power-to-X-Prozesse (PtX) oder zur Erzielung "negativer Emissionen" bereitzustellen. Die Ergebnisse einer multidimensionalen Bewertung im Rahmen der BMWi-Studie "Technologien für die Energiewende" (et 09/2018) zeigen, dass noch große Unsicherheiten bestehen und die Entwicklung überwiegend an Deutschland vorbeigeht.
A significant reduction in greenhouse gas emissions will be necessary in the coming decades to enable the global community to avoid the most dangerous consequences of man-made global warming. This fact is reflected in Germany's 7th Federal Energy Research Program (EFP), which was adopted in 2018. Direct Air Capture (DAC) technologies used to absorb carbon dioxide (CO2) from the atmosphere comprise one way to achieve these reductions in greenhouse gases. DAC has been identified as a technology (group) for which there are still major technology gaps. The intention of this article is to explore the potential role of DAC for the EFP by using a multi-dimensional analysis showing the technology's possible contributions to the German government's energy and climate policy goals and to German industry's global reputation in the field of modern energy technologies, as well as the possibilities of integrating DAC into the existing energy system. The results show that the future role of DAC is affected by a variety of uncertainty factors. The technology is still in an early stage of development and has yet to prove its large-scale technical feasibility, as well as its economic viability. The results of the multi-dimensional evaluation, as well as the need for further technological development, integrated assessment, and systems-level analyses, justify the inclusion of DAC technology in national energy research programs like the EFP.
In dem Forschungsprojekt "Technologien für die Energiewende" (TF_Energiewende) bewertet ein Konsortium von drei Verbundpartnern und zehn Technologiepartnern unter der Federführung des Wuppertal Instituts seit Herbst 2016 den mittelfristigen Forschungs- und Entwicklungsbedarf für die zentralen Technologien, die im Rahmen der Energiewende derzeit und zukünftig benötigt werden.
The German government has set itself the target of reducing the country's GHG emissions by between 80 and 95% by 2050 compared to 1990 levels. Alongside energy efficiency, renewable energy sources are set to play the main role in this transition. However, the large-scale deployment of renewable energies is expected to cause increased demand for critical mineral resources. The aim of this article is therefore to determine whether the transformation of the German energy system by 2050 ("Energiewende") may possibly be restricted by a lack of critical minerals, focusing primarily on the power sector (generating, transporting and storing electricity from renewable sources). For the relevant technologies, we create roadmaps describing a number of conceivable quantitative market developments in Germany. Estimating the current and future specific material demand of the options selected and projecting them along a range of long-term energy scenarios allows us to assess potential medium- or long-term mineral resource restrictions. The main conclusion we draw is that the shift towards an energy system based on renewable sources that is currently being pursued is principally compatible with the geological availability and supply of mineral resources. In fact, we identified certain sub-technologies as being critical with regard to potential supply risks, owing to dependencies on a small number of supplier countries and competing uses. These sub-technologies are certain wind power plants requiring neodymium and dysprosium, thin-film CIGS photovoltaic cells using indium and selenium, and large-scale redox flow batteries using vanadium. However, non-critical alternatives to these technologies do indeed exist. The likelihood of supplies being restricted can be decreased further by cooperating even more closely with companies in the supplier countries and their governments, and by establishing greater resource efficiency and recyclability as key elements of technology development.
Wo werden zukünftig grüner Wasserstoff und synthetische Kraftstoffe produziert? Zu welchen Kosten können diese erzeugt werden? Und welchen Anteil hätte eine heimische Produktion daran? Die Ergebnisse der Studie MENA-Fuels zeigen, dass im Nahen Osten und Nordafrika langfristig sehr große kostengünstige Potenziale für grünen Strom, Wasserstoff und Synfuels bestehen. Die Berücksichtigung von Investitionsrisiken hat jedoch einen signifikanten Einfluss auf deren Kosten und damit auf die Wahl der potenziellen Exportländer.
If the current energy policy priorities are retained, there may be no need to focus additionally on carbon capture and storage (CCS) in the power plant sector of Germany. This applies even in the case of ambitious climate protection targets, according to the results of the presented integrated assessment study. These cover a variety of aspects: Firstly, the technology is not expected to become available on a large scale in Germany before 2025. Secondly, if renewable energies and combined heat and power are expanded further and energy productivity is enhanced, there is likely to be only a limited demand for CCS power plants, as a scenario analysis of CCS deployment in Germany shows. Thirdly, cost analysis using the learning curve approach shows that the electricity generation costs of renewable electricity approach those of CCS power plants. This leads to the consequence that, from 2020, several renewable technologies may well be in a position to offer electricity at a cheaper rate than CCS power plants. In addition, a review of new life cycle assessments for CO2 separation in the power plant sector indicates that the greenhouse gas emissions from 1 kW h of electricity generated by first-generation CCS power plants could only be reduced by 68 % to 87 % (95 % in individual cases). Finally, a cautious, conservative estimate of the effective German CO2 storage capacity of approximately 5 billion tonnes of CO2 is calculated, including a fluctuation range yielding values between 4 and 15 billion tonnes of CO2. Therefore, the total CO2 emissions caused by large point sources in Germany could be stored for 12 years (basic value) or for 8 or 33 years (sensitivity values).
Prospects of carbon capture and storage (CCS) in India's power sector : an integrated assessment
(2014)
Objective: The aim of the present article is to conduct an integrated assessment in order to explore whether CCS could be a viable technological option for significantly reducing future CO2 emissions in India. Methods: In this paper, an integrated approach covering five assessment dimensions is chosen. However, each dimension is investigated using specific methods (graphical abstract).
Results: The most crucial precondition that must be met is a reliable storage capacity assessment based on site-specific geological data since only rough figures concerning the theoretical capacity exist at present. Our projection of different trends of coal-based power plant capacities up to 2050 ranges between 13 and 111 Gt of CO2 that may be captured from coal-fired power plants to be built by 2050. If very optimistic assumptions about the country's CO2 storage potential are applied, 75 Gt of CO2 could theoretically be stored as a result of matching these sources with suitable sinks. If a cautious approach is taken by considering the country's effective storage potential, only a fraction may potentially be sequestered. In practice, this potential will decrease further with the impact of technical, legal, economic and social acceptance factors. Further constraints may be the delayed commercial availability of CCS in India, a significant barrier to achieving the economic viability of CCS, an expected net maximum reduction rate of the power plant’s greenhouse gas emissions of 71-74%, an increase of most other environmental and social impacts, and a lack of governmental, industrial or societal CCS advocates.
Conclusion and practice implications: Several preconditions need to be fulfilled if CCS is to play a future role in reducing CO2 emissions in India, the most crucial one being to determine reliable storage capacity figures. In order to overcome these barriers, the industrialised world would need to make a stronger commitment in terms of CCS technology demonstration, cooperation and transfer to emerging economies like India. The integrated assessment might also be extended by a comparison with other low-carbon technology options to draw fully valid conclusions on the most suitable solution for a sustainable future energy supply in India.
Prospects of carbon capture and storage (CCS) in China's power sector : an integrated assessment
(2015)
Objective: The aim of the present article is to conduct an integrated assessment in order to explore whether CCS could be a viable technological option for significantly reducing future CO2 emissions in China. Methods: In this paper, an integrated approach covering five assessment dimensions is chosen. Each dimension is investigated using specific methods (graphical abstract). Results: The most crucial precondition that must be met is a reliable storage capacity assessment based on site-specific geological data. Our projection of different trends of coal-based power plant capacities up to 2050 ranges between 34 and 221 Gt of CO2 that may be captured from coal-fired power plants to be built by 2050. If very optimistic assumptions about the country’s CO2 storage potential are applied, 192 Gt of CO2 could theoretically be stored as a result of matching these sources with suitable sinks. If a cautious approach is taken, this figure falls to 29 Gt of CO2. In practice, this potential will decrease further with the impact of technical, legal, economic and social acceptance factors. Further constraints may be the delayed commercial availability of CCS in China; a significant barrier to achieving the economic viability of CCS due to a currently non-existing nation-wide CO2 pricing scheme that generates a sufficiently strong price signal; an expected life-cycle reduction rate of the power plant's greenhouse gas emissions of 59-60%; and an increase in most other negative environmental and social impacts. Conclusion and practice implications: Most experts expect a striking dominance of coal-fired power generation in the country's electricity sector, even if the recent trend towards a flattened deployment of coal capacity and reduced annual growth rates of coal-fired generation proves to be true in the future. In order to reduce fossil fuel-related CO2 emissions to a level that would be consistent with the long-term climate protection target of the international community to which China is increasingly committing itself, this option may require the introduction of CCS. However, a precondition for opting for CCS would be finding robust solutions to the constraints highlighted in this article. Furthermore, a comparison with other low-carbon technology options may be useful in drawing completely valid conclusions on the economic, ecological and social viability of CCS in a low-carbon policy environment. The assessment dimensions should be integrated into macro-economic optimisation models by combining qualitative with quantitative modelling, and the flexible operation of CCS power plants should be analysed in view of a possible role of CCS for balancing fluctuating renewable energies.
This article presents an integrated assessment conducted in order to explore whether carbon capture and storage (CCS) could be a viable technological option for significantly reducing future CO2 emissions in South Africa. The methodological approach covers a commercial availability analysis, an analysis of the long-term usable CO2 storage potential (based on storage capacity assessment, energy scenario analysis and source-sink matching), an economic and ecological assessment and a stakeholder analysis. The findings show, that a reliable storage capacity assessment is needed, since only rough figures concerning the effective capacity currently exist. Further constraints on the fast deployment of CCS may be the delayed commercial availability of CCS, significant barriers to increasing the economic viability of CCS, an expected net maximum reduction rate of the power plant's greenhouse gas emissions of 67%-72%, an increase in other environmental and social impacts, and low public awareness of CCS. One precondition for opting for CCS would be to find robust solutions to these constraints, taking into account that CCS could potentially conflict with other important policy objectives, such as affordable electricity rates to give the whole population access to electricity.
The study presents the results of an integrated assessment of carbon capture and storage (CCS) in the power plant sector in Germany, with special emphasis on the competition with renewable energy technologies. Assessment dimensions comprise technical, economic and environmental aspects, long-term scenario analysis, the role of stakeholders and public acceptance and regulatory issues. The results lead to the overall conclusion that there might not necessarily be a need to focus additionally on CCS in the power plant sector. Even in case of ambitious climate protection targets, current energy policy priorities (expansion of renewable energies and combined heat and power plants as well as enhanced energy productivity) result in a limited demand for CCS. In case that the large energy saving potential aimed for can only partly be implemented, the rising gap in CO2 reduction could only be closed by setting up a CCS-maximum strategy. In this case, up to 22% (41 GW) of the totally installed load in 2050 could be based on CCS. Assuming a more realistic scenario variant applying CCS to only 20 GW or lower would not be sufficient to reach the envisaged climate targets in the electricity sector. Furthermore, the growing public opposition against CO2 storage projects appears as a key barrier, supplemented by major uncertainties concerning the estimation of storage potentials, the long-term cost development as well as the environmental burdens which abound when applying a life-cycle approach. However, recently, alternative applications are being increasingly considered–that is the capture of CO2 at industrial point sources and biomass based energy production (electricity, heat and fuels) where assessment studies for exploring the potentials, limits and requirements for commercial use are missing so far. Globally, CCS at power plants might be an important climate protection technology: coal-consuming countries such as China and India are increasingly moving centre stage into the debate. Here, similar investigations on the development and the integration of both, CCS and renewable energies, into the individual energy system structures of such countries would be reasonable.
Der Politikbericht ist ein Ergebnis des Forschungsvorhabens "Technologien für die Energiewende", das vom Bundesministerium für Wirtschaft und Energie (BMWi) als Teil des strategischen Leitprojekts "Trends und Perspektiven der Energieforschung" von 2016 bis 2018 gefördert wurde. Er enthält neben einer kurzen deutschen und englischen Einleitung vierseitige Zusammenfassungen zu jedem der 31 analysierten Technologiefelder und eine Kurzdarstellung der Bewertungsmethodik. Die Zusammenfassungen sind gegliedert nach Definition des Technologiefeldes, aktueller Stand der Technologie, ausgewählte Bewertungskriterien und F&E-Empfehlungen.
Im Herbst 2018 wird das neue Energieforschungsprogramm (EFP) der Bundesregierung verabschiedet. Das Forschungsprojekt "Technologien für die Energiewende", kurz TF_Energiewende, hat hierfür eine wesentliche wissenschaftliche Basis geliefert. Für 31 Technologiefelder, die mehrere Hundert Technologien umfassen, analysierten die Projektpartner das Innovations- und Marktpotenzial, bewerteten Chancen und Risiken sowie den möglichen Beitrag der Technologien zur Umsetzung der Energiewende und zeigten Forschungs- und Entwicklungsbedarf auf. Die nun veröffentlichten Ergebnisse dienen gleichzeitig als umfassendes Nachschlagewerk für Entscheider in Unternehmen, Forschungsabteilungen, Fördergeber und die interessierte Fachöffentlichkeit.
Ziel dieses Teilvorhabens innerhalb des FlexGeber-Projektes war die Initiierung und Begleitung eines Prozesses zur Identifikation und (idealerweise späteren) Realisierung von Effizienz-, Erneuerbaren- und Flexibilitätspotenzialen in den Industriebetrieben Taifun-Tofu GmbH (Lebensmittel) und Hermann Peter KG (Baustoffe).
Dazu haben die Forschenden jeweils in einem Workshop relevante Akteure zusammengebracht und Wissen zur Bestimmung und Bewertung von Flexibilitäten aus technischer, rechtlich-politischer sowie strukturell-organisatorischer Sicht erarbeitet und vermittelt. Gemeinsam klärten sie, welche Informationen in welchem Format für Unternehmen erforderlich und relevant sind, um Flexibilitätsoptionen identifizieren und umsetzen zu können.
Insgesamt gliedert sich die methodische Vorgehensweise in vier zentrale Arbeitsschritte: Vor-Ort-Begehungen bei den Reallaboren, Identifikation technischer Hotspots, Akteursworkshop sowie abschließende Auswertung. Der vorliegende Teilbericht dokumentiert diesen Prozess und fokussiert auf die Identifikation von möglichen Effizienz-, Erneuerbaren- und Flexibilitätsoptionen und der Erfassung von Hemmnissen, die einer Umsetzung von Maßnahmen zur Erschließung der Potenziale bei den Praxispartnern entgegenstehen.
Da die Workshops vornehmlich auf die Unternehmen Taifun-Tofu und Hermann Peter ausgerichtet waren, fokussiert dieser Bericht auf Hemmnisse, die diese Unternehmen bzw. Unternehmen dieser Branchen betreffen. Darüber hinaus ist ein Kapitel zu Hemmnissen, die sich aus dem Demonstrationsvorhaben des Fraunhofer ISE-Campus (Ausbau des Kältenetzes und Installation von Kältespeichern) ableiten, ist in diesem Bericht enthalten.
The Paris Agreement introduces long-term strategies as an instrument to inform progressively more ambitious emission reduction objectives, while holding development goals paramount in the context of national circumstances. In the lead up to the twenty-first Conference of the Parties, the Deep Decarbonization Pathways Project developed mid-century low-emission pathways for 16 countries, based on an innovative pathway design framework. In this Perspective, we describe this framework and show how it can support the development of sectorally and technologically detailed, policy-relevant and country-driven strategies consistent with the Paris Agreement climate goal. We also discuss how this framework can be used to engage stakeholder input and buy-in; design implementation policy packages; reveal necessary technological, financial and institutional enabling conditions; and support global stocktaking and increasing of ambition.
The cement industry is one of the major energy consuming and CO2 emitting sectors in China. In 2010, 1,868 million tons of cement has been produced, which accounted for 56.1% of the world's total cement production. The 11th Five-Year Plan (FYP) (2006-2010) included policy measures for CO2 emission abatement in cement production. Based on the main governmental framework of CO2 mitigation policies at national level in the cement sector, key policies and technologies used during this period are identified and their effects on CO2 reduction are assessed. This paper calculates the reduction of CO2 emissions related to four main policies and technologies for efficient cement production in the 11th and the 12th FYP (2011-2015) with 2005 as a reference year. These are waste heat recovery, closing outdated facilities, substitution for clinker production and other technologies aiming to increase energy efficiency. Due to these measures, we estimate that a total CO2 emission reduction during the 11th FYP of 397 million tonnes could be saved, which is considerably different to 185.75 million tonnes estimated by Zeng (2008) and 303 million tonnes by the NDRC by using different calculation methods. Of the four technologies, the 4th group of energy efficiency increasing techniques was the most important policy and avoided the largest amount of CO2 emissions. Previous energy intensity reduction was mainly due to the outdated production closing and energy efficiency improving. Based on the assessment of technology performance, it appears that there is still a large emission reduction potential in cement production processes. The paper calculates this potential for the 12th FYP period (2011-2015) based on these four identified policy measures. The result is compared to the Chinese government targets in the 12th FYP and promising future CO2 mitigation policies and technologies are proposed, such as the use of alternative energy.
The main objective of this article is to evaluate CO2 mitigation potential and to calculate costs avoided by the use of different CO2 mitigation technologies in China's cement sector, namely energy efficiency improvements, use of alternative fuels, clinker substitution and carbon capture and storage (CCS). Three scenarios are designed based on the projection of cement output and technology development over the next 40 years (2010–2050). 2.5, 4.7 and 4.3 Gt tonnes of CO2 will be saved totally in basic scenario and two low carbon scenarios up to 2050. By comparing these technologies along the scenarios, it can be concluded that CO2 emissions can mainly be reduced by energy efficiency improvements and use of alternative fuels. Clinker substitution, which reduces the clinker-to-cement ratio as well as energy intensity, results in significant cost advantages. CCS, including post-combustion capture and oxy-fuel combustion capture, could play an important role in the capture of CO2 in the cement industry, and is expected to be in commercial use by 2030.
Today more than 45 % of all energy-related CO2 emissions come from burning coal. Thus, reducing CO2 emissions from coal use is a necessity for reaching the targets of the Paris Agreement. This will not only pose challenges for coal consumers (restructuring of the energy system), but also for countries whose economy is strongly depending on the production of coal. This paper examines the role of coal in three countries, which are or were in recent years among the top coal exporters: Indonesia, Colombia and Vietnam. Understanding challenges and possible transition pathways in these countries will help to develop global strategies to reduce CO2 emissions from coal in the short to mid-term.
Die deutschen Braun- und Steinkohlekraftwerke produzieren 40 % des deutschen Stroms - sind aber für 80 % der Treibhausgasemissionen in diesem Sektor verantwortlich. Ein sukzessiver Ausstieg aus der Kohleverstromung kann daher einen entscheidenden Beitrag leisten, die deutschen Klimaziele zu erreichen und den Pfad zur Einhaltung der Klimaziele von Paris offen zu halten. Vor diesem Hintergrund hat sich in den letzten Jahren in Deutschland eine Debatte um einen möglichen nationalen Kohleausstieg entsponnen.
Der Naturschutzbund Deutschland (NABU) hat das Wuppertal Institut daher beauftragt, zentrale wissenschaftliche Studien und politische Positionspapiere zum Thema Kohleausstieg zu analysieren. In der nun vorliegenden Metastudie fassen die Autoren den aktuellen Diskussionsstand zu wichtigen Eckpfeilern eines beschleunigten Kohleausstiegs in Deutschland zusammen. Analysiert wurden insbesondere Aussagen zur klimapolitischen Notwendigkeit und zur energiewirtschaftlichen Machbarkeit unterschiedlicher Zeithorizonte eines Kohleausstiegs sowie Optionen für eine sozialverträgliche Gestaltung des damit einhergehenden Strukturwandels.
Nach jahrzehntelangen, erfolgreichen Reduktionen der CO2-Emissionen in der Industrie, ist der Trend in den letzten Jahren wieder rückläufig geworden: seit 2014 sind die Emissionen wieder angestiegen (UBA 2019). Um die deutschen Klimaziele zu erreichen ist es daher notwendig, die Anstrengungen zu verstärken und intensiver als in der Vergangenheit Innovationen für den Klimaschutz voranzutreiben: Neue Produkte und Geschäftsmodelle sowie neue Herstellungsverfahren zu entwickeln, mit denen sich Treibhausgasemissionen reduzieren lassen.
Um die deutschen Klimaziele für 2030 einzuhalten, werden hierfür gerade auch (inkrementelle) Effizienzsteigerungen nötig sein - diese werden jedoch nicht ausreichend sein. Innovationen müssen auch einen disruptiven Wandel von Strukturen und Geschäftsmodellen erwirken. Disruptive Innovationen und industrielle Konversionsprozesse bergen jedoch hohe Risiken für die etablierte Industrie. Hier stellt sich also die Frage, wie eine auf Klimaschutz ausgerichtete Innovationspolitik gestaltet werden muss, um einerseits die notwendigen CO2-Einsparungen zu ermöglichen und andererseits die Leistungfähigkeit der deutschen Industrie zu befördern?
Vor diesem Hintergrund widmet sich diese Studie zwei zentralen Fragestellungen: Wie laufen Klimaschutz-Innovationsprozesse ab? Wie können Klimaschutz-Innovationen befördert werden?
Basierend auf einer konzeptionellen Klassifizierung von Klimaschutz-Innovationen, wurden eine Reihe von existierenden Klimaschutz-Innovationen, gerade aus der energieintensiven Industrie analysiert. Vier Fallbeispiele aus verschiedenen Sektoren (Aluminiumherstellung und -verarbeitung, Herstellung neuer Kraftstoffe sowie der Verzinkung) und verschiedenen Innovationstypen werden in der Studie ausführlich beschrieben. Dabei zeigt sich, dass sich Unternehmen nicht nur an aktuellen Rahmenbedingungen orientieren, sondern Innovationen - sowohl inkrementeller wie auch radikaler Natur- im Bereich Klimaschutz auch unter der Annahme dynamischer Entwicklungen von sich verstärkenden Klimaschutzrahmenbedingungen vorantreiben. Darüber hinaus waren an allen untersuchten Fällen auch externe Promotoren unterstützend tätig. Daher wurden die möglichen Rollen von Klimaschutz-Promotoren mit unterschiedlichen regionalen und inhaltlichen Schwerpunkten gezielt analysiert.
The climate impact of the iron and steel industry can be mitigated through increased energy efficiency, emission efficiency, material efficiency, and product use efficiency resulting in reduced product demand. For achieving ambitious greenhouse gas (GHG) mitigation targets in this sector all measures could become necessary. The current paper focuses on one of those four key measures: emission efficiency via innovative primary steelmaking technologies. After analysing their techno-economical potential until 2100 in part A of this publication, the current research broadens the evaluation scope for the crucial year 2050, based on a Multicriteria-Analysis (MCA). 12 criteria from five different categories ("technology", "society and politics", "economy", "safety and vulnerability" and "ecology") are used to assess the same four future steelmaking technologies in a systematic and holistic way in Germany, as one possible location. The technologies in focus are the blast furnace route (BF-BOF), blast furnace with carbon capture and storage (BF-CCS), hydrogen direct reduction (H-DR), and iron ore electrolysis (EW). These four technologies have been selected, as explained in part A of this paper, because they are the most commonly discussed technological options under discussion by policymakers and the iron and steel industry. The results of the current work should provide decision makers in industry and government with a long-term guidance on technological choices.
In 2050 the MCA shows significantly higher preference scores for the two innovative routes H-DR and EW compared to the blast furnace based routes. The main reasons being higher scores in the economical and environmental criteria. BF-CCS shows its greatest weakness in the social acceptance and the safety and vulnerability criteria. BF-BOF has the lowest economy and ecology score of all assessed routes, which is due to the projected high cost for carbon dioxide emission and increasing prices for fossil fuels. A first indicative trend assessment from today towards 2050 shows that H-DR is the preferred MCA option from today on.
Three exemplary weighting distributions (representing the perspectives of the steel industry, environmental organisations and the government), used to simulate different stakeholder angle of view, don't have a strong influence on the overall evaluation of the steelmaking routes. The results remain very similar, with the highest scores for the innovative routes (H-DR and EW). This leads to the conclusion that EW and in particular H-DR can be identified as the preferred future steelmaking technology across different perspectives.
Specific innovation efforts and dedicated programs are necessary to minimize the time until marketability and to share the development burden. The similarity of the MCA results from different perspectives indicates a great opportunity to reach a political consensus and to work together towards a common future goal. Regarding the pressing time horizon a concentrated engagement for one (or few) technological choices would be highly recommended.
Im Vergleich zu den Jahrzehnten zuvor ist das Energiesystem heute durch eine hohe Dynamik gekennzeichnet und steht unter ständigem Veränderungsdruck. Im vorliegenden Artikel diskutieren die Autoren die Rolle der Digitalisierung in den derzeitigen Prozessen. Sie nutzen dafür die Mehr-Ebenen-Perspektive (Multi Level Perspective, MLP). Diese sieht Transformation als ein Zusammenspiel von externen und internen Faktoren an: Die äußeren übergeordneten Entwicklungen kreieren einen Veränderungsdruck auf das Regime von außen, welches infolgedessen aus der Balance geraten kann. Darüber hinaus eröffnen sich Möglichkeiten für zielgerichtete Veränderungen im System durch die erfolgreiche Etablierung von innovativen Ansätzen. Letzteres gilt gerade für die breiten Anwendungspotenziale der Digitalisierung.
Die beiden Autoren zeichnen die Transformationsprozesse im Energiesektor seit Beginn der Liberalisierung nach und blicken anschließend auf die Herausforderungen in der jetzigen Phase der Energiewende - darunter die Systemintegration erneuerbarer Energien in das Stromsystem und die digitale Vernetzung. Der Artikel schließt ab mit einer Analyse externer und interner Faktoren, die eine Digitalisierung des Energiesektors weiter vorantreiben.
Digitalization is a transformation process which has already affected many parts of industry and society and is expected to yet increase its transformative speed and impact. In the energy sector, many digital applications have already been implemented. However, a more drastic change is expected during the next decades. Good understanding of which digital applications are possible and what are the associated benefits as well as risks from the different perspectives of the impacted stakeholders is of high importance. On the one hand, it is the basis for a broad societal and political discussion about general targets and guidelines of digitalization. On the other hand, it is an important piece of information for companies in order to develop and sustainably implement digital applications. This article provides a structured overview of potential digital applications in the German energy (electricity) sector, including the associated benefits and the impacted stakeholders on the basis of a literature review. Furthermore, as an outlook, a methodology to holistically analyze digital applications is suggested. The intended purpose of the suggested methodology is to provide a complexity-reduced fact base as input for societal and political discussions and for the development of new digital products, services, or business models. While the methodology is outlined in this article, in a follow-up article the application of the methodology will be presented and the use of the approach reflected.
Im Energiesektor hat die Digitalisierung bereits viele Abläufe der Wertschöpfungskette verändert. Es besteht jedoch weiterhin erhebliches Potenzial zur Nutzung von digitalen Anwendungen. Insofern ist mit weiteren tiefgreifenden Veränderungen zu rechnen. Neben den zahlreichen Nutzen bestehen auch potenzielle negative Auswirkungen. Die so entstehenden Spannungsfelder müssen frühzeitig analysiert werden, um Lösungsoptionen für potenzielle Hindernisse zu erarbeiten um somit den größtmöglichen Nutzen der Digitalisierung erzielen zu können.
Die Digitalisierung ist längst gelebte Praxis. Jeden Tag werden Milliarden an "digitalen" Handlungen ausgeführt. Beispielsweise werden täglich 207 Mrd. E-Mails verschickt, 8,8 Mrd. YouTube-Videos angesehen und 36 Mio. Amazonkäufe getätigt. Dabei nimmt die Geschwindigkeit, mit der neue Anwendungen entwickelt und etabliert werden, kontinuierlich zu. Es stellt sich also die Frage, was im Energiesektor zu erwarten ist und wie die Entwicklung zielgerichtet genutzt werden kann.
The development of digital technologies is accelerating, enabling increasingly profound changes in increasingly short time periods. The changes affect almost all areas of the economy as well as society. The energy sector has already seen some effects of digitalization, but more drastic changes are expected in the next decades. Besides the very positive impacts on costs, system stability, and environmental effects, potential obstacles and risks need to be addressed to ensure that advantages can be exploited while adverse effects are avoided. A good understanding of available and future digital applications from different stakeholders' perspectives is necessary. This study proposes a framework for the holistic evaluation of digital applications in the energy sector. The framework consists of a combination of well-established methods, namely the multi-criteria analysis (MCA), the life cycle assessment (LCA), and expert interviews. The objective is to create transparency on benefits, obstacles, and risks as a basis for societal and political discussions and to supply the necessary information for the sustainable development and implementation of digital applications. The novelty of the proposed framework is the specific combination of the three methods and its setup to enable sound applicability to the wide variety of digital applications in the energy sector. The framework is tested subsequently on the example of the German smart meter roll-out. The results reveal that, on the one hand, the smart meter roll-out clearly offers the potential to increase the system stability and decrease the carbon emission intensity of the energy system. Therefore, the overall evaluation from an environmental perspective is positive. However, on the other hand, close attention needs to be paid to the required implementation and operational effort, the IT (information technology) and data security, the added value for the user, the social acceptance, and the realization of energy savings. Therefore, the energy utility perspective in particular results in an overall negative evaluation. Several areas with a need for action are identified. Overall, the proposed framework proves to be suitable for the holistic evaluation of this digital application.
Transponder-based Aircraft Detection Lighting Systems (ADLS) are increasingly used in wind turbines to limit beacon operation times, reduce light emissions, and increase wind energy acceptance. The systems use digital technologies such as receivers of digital transponder signals, LTE/5G, and other information and communication technology. The use of ADLS will be mandatory in Germany both for new and existing wind turbines with a height of >100 m from 2023 (onshore) and 2024 (offshore), so a nationwide rollout is expected to start during 2022. To fully realize the benefits while avoiding risks and bottlenecks, a thorough and holistic understanding of the efforts required and the impacts caused along the life cycle of an ADLS is essential. Therefore, this study presents the first multi-aspect holistic evaluation of an ADLS. A framework for evaluating digital applications in the energy sector, previously developed by the authors, is refined and applied. The framework is based on multi-criteria analysis (MCA), life cycle assessment (LCA), and expert interviews. On an aggregated level, the MCA results show an overall positive impact from all stakeholders’ perspectives. Most positive impacts are found in the society and politics category, while most negative impacts are of technical nature. The LCA of the ADLS reveals a slightly negative impact, but this impact is negligible when compared to the total life cycle impact of the wind turbines of which the ADLS is a part. Besides the aggregated evaluation, detailed information on potential implementation risks, bottlenecks, and levers for life cycle improvement are presented. In particular, the worldwide scarcity of the required semiconductors, in combination with the general lack of technicians in Germany, lead to the authors’ recommendation for a limited prolongation of the planned rollout period. This period should be used by decision-makers to ensure the availability of technical components and installation capacities. A pooling of ADLS installations in larger regions could improve plannability for manufacturers and installers. Furthermore, an ADLS implementation in other countries could be supported by an early holistic evaluation using the presented framework.
Energy-intensive processing industries (EPIs) produce iron and steel, aluminum, chemicals, cement, glass, and paper and pulp and are responsible for a large share of global greenhouse gas emissions. To meet 2050 emission targets, an accelerated transition towards deep decarbonization is required in these industries. Insights from sociotechnical and innovation systems perspectives are needed to better understand how to steer and facilitate this transition process. The transitions literature has so far, however, not featured EPIs. This paper positions EPIs within the transitions literature by characterizing their sociotechnical and innovation systems in terms of industry structure, innovation strategies, networks, markets and governmental interventions. We subsequently explore how these characteristics may influence the transition to deep decarbonization and identify gaps in the literature from which we formulate an agenda for further transitions research on EPIs and consider policy implications. Furthering this research field would not only enrich discussions on policy for achieving deep decarbonization, but would also develop transitions theory since the distinctive EPI characteristics are likely to yield new patterns in transition dynamics.
Future of car-sharing in Germany : customer potential estimation, diffusion and ecological effect
(2007)