Filtern
Erscheinungsjahr
- 2019 (73) (entfernen)
Dokumenttyp
- Dissertation (51)
- Bachelorarbeit (9)
- Masterarbeit (9)
- Arbeitspapier (2)
- Habilitation (1)
- Beitrag in Konferenzband (1)
Schlagworte
- Nachhaltigkeit (5)
- Baurecht (3)
- Governance (3)
- Landwirtschaft (3)
- Steuerungsprozesse (3)
- Sustainability (3)
- Agriculture (2)
- Ethiopia (2)
- Teilhabe (2)
- Äthiopien (2)
Institut
- Fakultät Nachhaltigkeit (25)
- Fakultät Wirtschaftswissenschaften (14)
- Fakultät Bildung (7)
- Institut für Ökologie (IE) (7)
- Fakultät Kulturwissenschaften (5)
- Institut für Management, Accounting & Finance (IMAF) (4)
- Institut für Psychologie (IFP) (4)
- Institut für Ethik und Transdisziplinäre Nachhaltigkeitsforschung (IETSR) (3)
- Institut für Nachhaltigkeitssteuerung (INSUGO) (3)
- Professional School (3)
In response to the challenges of the energy transition, the German electricity network is subjected to a process of substantial transformation. Considering the long latency periods and lifetimes of electricity grid infrastructure projects, it is more cost-efficient to combine this need for transformation with the need to adapt the grid to future climate conditions. This study proposes the spatially varying risk of electricity grid outages as a guiding principle to determine optimal levels of security of electricity supply. Therefore, not only projections of future changes in the likelihood of impacts on the grid infrastructure were analyzed, but also the monetary consequences of an interruption. Since the windthrow of trees was identified a major source for atmospherically induced grid outages, a windthrow index was developed, to regionally assess the climatic conditions for windthrow. Further, a concept referred to as Value of Lost Grid was proposed to quantify the impacts related to interruptions of the distribution grid. In combination, the two approaches enabled to identify grid entities, which are of comparably high economic value and subjected to a comparably high likelihood of windthrow under future climate conditions. These are primarily located in the mid-range mountain areas of North-Rhine Westphalia, Baden-Württemberg and Bavaria. In comparison to other areas of less risk, the higher risk in these areas should be reflected in comparably more resilient network structures, such as buried lines instead of overheadlines, or more comprehensive efforts to prevent grid interruptions, such as structural reinforcements of pylons or improved vegetation management along the power lines. In addition, the outcomes provide the basis for a selection of regions which should be subjected to a more regionally focused analysis inquiring spatial differences (with respect to the identified coincidence of high windthrow likelihoods and high economic importance of the grid) among individual power lines or sections of a distribution network.
Wind energy is expected to become the largest source of electricity generation in Europe's future energy mix. As a consequence, future electricity generation will be exposed to an increasing degree to weather and climate. With planning and operational lifetimes of wind energy infrastructure reaching climate time scales, adaptation to changing climate conditions is of relevance to support secure and sustainable energy supply. Premise for success of wind energy projects is the ability to service financial obligations over the project lifetime. Though, revenues(viaelectricity generation) are exposed to changing climate conditions affecting the wind resource, operating conditions or hazardous events interfering with the wind energy infrastructure. For the first time, a procedure is presented to assess such climate change impacts specifically for wind energy financing. At first, a generalised financing chain for wind energy is prepared to (qualitatively) trace the exposure of individual cost elements to physical climate change. In this regard, the revenue through wind power production is identified as the essential component within wind energy financing being exposed to changing climate conditions. This implies the wind resource to be of crucial interest for an assessment of climate change impacts on the financing of wind energy. Therefore, secondly, a novel high-resolution experimental modelling framework with the non-hydrostatic extension of the regional climate model REMO is set up to generate physically consistent climate and climate change information of the wind resource across wind turbine operating altitudes. With this setup, enhanced simulated intra-annual and inter-annual variability across the lower planetary boundary layer is achieved, being beneficial for wind energy applications, compared to state-of-the-art regional climate model configurations. In addition, surrogate climate change experiments with this setup disclose vertical wind speed changes in the lower planetary boundary layer to be indirectly affected by temperature changes through thermodynamically-induced atmospheric stability alterations. Moreover, air density changes are identified to occasionally exceed the net impact of wind energy density changes originating from changes in wind speed. This supports the consideration of air density information (in addition to wind speed) for wind energy yiel assumptions. Thirdly, the generated climate and climate change information of the wind resource are transferred to a simplified but fully-fledged financial model to assess the financial risk of wind energy project financing with respect to changing climate conditions. Sensitivity experiments for an imaginary offshore wind farm located in the German Bight reveal the long-term profitability of wind energy project financing not to be substantially affected by changing wind resource conditions, but incidents with insufficient servicing of financial obligations experience changes exceeding -10% to 14%. The integration of wind energy-specific climate and climate change information into existing financial risk assessment procedures would illustrate a valuable contribution to enable climate change adaptation for wind energy.
Der vorliegende Beitrag beschäftigt sich, wie zwei vorangegangene Berichte, mit den Arbeits-bedingungen von Unternehmern. Als Analysebasis dienen die Daten des European Survey on Working Conditions aus den Jahren 2000, 2005 und 2010 sowie, nun ergänzend, die Daten aus der Erhebung aus dem Jahr 2015. Über die vier Erhebungswellen hinweg betrachtet ergeben sich, was die Beschreibung der Arbeitssituation der Unternehmer angeht, keine wesentlichen Verän-derungen. Die Unternehmer sind, was ihre Arbeitsbedingungen angeht, zum Teil, aber nicht durchgängig, besser gestellt als die übrigen Erwerbspersonen. Grundlage der Analyse ist ein ein-faches Modell, das positive und negative Aspekte der Arbeitssituation gegenüberstellt. Aus the-oretischer Sicht von Interesse sind die sich wechselseitig verstärkenden Effekte von Belastungs- und Motivationsfaktoren.