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.
Enhancing evaluations of future energy-related product policies with the digital product passport
(2022)
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.
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.
To achieve the EU's energy efficiency targets, both the rate of building energy renovation and its depth, i.e., the amount of energy savings post renovation need to be improved. Energy Performance Certificates (EPCs) are key to make energy efficiency measures transparent for the building market and to promote the energy efficiency of buildings through renovation. The revision of the Energy Performance of Buildings Directive (EPBD) is seen as a pre-condition to meet the Renovation Wave objectives and to reach a highly energy efficient and decarbonized building stock by 2050. One focus of the current revision of the EPBD is therefore the improvement of EPCs. QualDeEPC - High-quality Energy Performance Assessment and Certification in Europe Accelerating Deep Energy Renovation, funded under the EU's Horizon 2020 programme, is a project that aims to improve EPCs. Following an EU-wide review of existing EPC schemes, and extensive stakeholder discussions in the seven partner countries, QualDeEPC found that EPCs and EPC schemes need to enhance particularly in the following three ways:
1. Establish a close link between EPCs and deep energy renovation
2. Improve the quality of EPC schemes, i.e., both the EPCs and their data, and the processes of assessment, certification, verification
3. Improve cross-EU convergence of EPC schemes.
Die Forschung der FVEE-Institute zum Einsatz von klimaneutral erzeugtem Wasserstoff in der Industrie deckt sowohl technische Aspekte für einzelne Prozesse ab als auch systemanalytische Betrachtungen, die die Einsatzmöglichkeiten von Wasserstoff am einzelnen Standort oder für bestimmte Branchen in Deutschland bzw. Europa untersuchen.
Die Motivation zum Einsatz von Wasserstoff ergibt sich aus drei Gründen:
1. In der stofflichen Verwendung wird Wasserstoff als Molekül benötigt und kann deshalb auch nicht durch andere Energieträger substituiert werden. So wird Wasserstoff bereits heute in großen Mengen in der Ammoniaksynthese (Haber-Bosch-Verfahren) sowie in den Raffinerien benötigt.
2. Eine weitere Verwendungsart für Wasserstoff ergibt sich aus seiner Fähigkeit, Sauerstoff aus Eisenerz chemisch zu binden. Beim Einsatz in Direktreduktionsanlagen kann Wasserstoff als Reduktionsmittel eingesetzt werden, um Eisenerz zu Roheisen zu reduzieren.
3. Als dritte Option gerät die energetische Verwendung von Wasserstoff in der Industrie zunehmend in den Fokus der energiepolitischen Debatten. Hier steht Wasserstoff in einem klimaneutralen System direkt in Konkurrenz zu anderen Energieträgern wie Strom und Biomasse.
The Fit for 55 package stipulates a fair, competitive and green transition by 2030 and beyond. As part of this, increasing attention is given to the decarbonisation of the building stock: only 1 % of buildings in Europe are retrofitted each year, a number which must double if the EU is to meet its 2050 targets. Significant energy efficiency investments are needed, whilst the planned expansion of the EU-ETS to the building sector in 2026 will likely pass the carbon cost onto the consumer. This will increase the cost burden placed on low-income households, exacerbating energy poverty, if these two strategies are not counterbalanced by adequate policies and support mechanisms.
The European Private Rented Sector (PRS) is often side-lined by policymakers when implementing energy efficiency policies to tackle energy poverty. As many as 1 in 10 Europeans spend 40 % or more of their income on housing costs, with those in the PRS struggling with energy-related problems, such as poor energy efficiency and maintenance, to a much greater degree than the general population. Understanding these challenges and creating targeted policies is of critical scientific and policy importance.
To date, a pan-European policy on how to address energy poverty and energy efficiency improvements in the PRS is lacking; current European Union instruments to address such issues (including the Fit for 55, and the Clean Energy Package that preceded it) lack a dedicated approach towards the complex structural issues embedded in the European PRS. What is more, there is a limited understanding of the character of energy poverty in such residential dwellings, as well as policies to address energy injustices. We therefore examine current and historical disparities in energy poverty between the EU's PRS tenants and the general population by analysing a variety of quantitative indicators which reflect different dimensions of energy poverty. We then take stock of the policy landscape, identifying energy efficiency policies tailored to alleviate energy poverty in the PRS and common challenges. We subsequently interrogate possible solutions, drawing on existing good practice policies. In so doing, we aim to reduce the sector's political invisibility by addressing the lack of disaggregated, targeted data and dismantling barriers that currently lead to the PRS being disproportionately affected by energy poverty.
More and more cities are setting themselves ambitious climate protection targets, including CO2 neutrality. Schools are important institutions of cities and therefore they have to play a central role in achieving this goal.
With the investment backlog building up and pressure from the Friday for Future movement increasing, the Wuppertal Institute and Büro Ö-quadrat have initiated the project Schools4Future, aiming to support secondary schools to become climate-neutral. In cooperation with secondary school students and teachers, the project team evaluated the existing situation of the participating schools and developed GHG-balances and feasible climate protection concepts. For this purpose, an Excel-based carbon footprint (CF) assessment tool for schools has been developed which is freely available. The tool covers all important emission areas, including heating energy, electricity use, travel to and from schools, school trips, the school canteen and paper consumption. The students were found capable to conduct the CF assessment with the guidance of the teacher, information materials and support of the researchers. So far, six pilot schools have completed their CF assessment with emissions ranging between 335 and 944 kg CO2 per person.
In this paper we present the tool and compare the CF assessment of some schools. We further elaborate on how the tool and project has increased the climate awareness and self-efficacy of students and even stimulated measures by the school board.
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.
Variations in quantity, quality and time availability of input materials pose a major risk to circular supply chains (CSC) and require new models for creating and evaluating adaptive and resilient CSC in the circular economy (CE). This can be achieved through consistent modelling of the overarching relationship between resource input- and output streams, without neglecting the associated risks.
The model proposed below consists of five components based on five resilience requirements for supply-chains (SCs). It provides a data-based recommended course of action for managers with a low entry-barrier. It consists of a CSC visualization, safety stock calculation, risk monitoring for each SC node, reporting logic, and a measurement catalogue. The inspiration for this model came from an innovative case study ("Zirkelmesser") in the metal processing industry, where secondary products and materials are used to produce new products. Here, the problem of maintaining the resource supply arose and led to resilience issues. The mentioned case study serves as an application example for the model application and contributes to making emerging circular supply chains predictable and more controllable, thus increasing their resilience.