Your search keyword '"Eltrop, Ludger"' showing total 3 results

1. Cost-Optimized Heat and Power Supply for Residential Buildings: The Cost-Reducing Effect of Forming Smart Energy Neighborhoods.

Author

Bahret, Christoph and Eltrop, Ludger

Subjects

*POWER resources, *NEIGHBORHOODS, *URBAN planning, *NEIGHBORHOOD planning, *DWELLINGS, *SMART cities, *HOME energy use, *ENERGY consumption

Abstract

The Clean Energy for all Europeans Package by the EU aims, among other things, to enable collective self-consumption for various forms of energy. This step towards more prosumer-based and decentralized energy systems comes at a time when energy planning at a neighborhood scale is on the rise in many countries. It is widely assumed that—from a prosumer's cost-perspective—shared conversion and storage technologies supplying more than a single building can be advantageous. However, it is not clear whether this is the case generally or only under certain conditions. By analyzing idealized building clusters at different degrees of urbanization (DOU), a linear-optimization approach is used to study the cost difference between shared energy infrastructure (smart energy neighborhoods, SENs) and individually planned buildings. This procedure is carried out for various emission reduction targets. The results show, that with higher emission reduction targets the advantage of SENs increases within rural environments and can reach up to 16%. Nevertheless, there are constellations in which the share of energetic infrastructure among buildings does not lead to any economic advantages. For example, in the case of building clusters with less than four buildings, almost no cost advantage is found. The result of this study underlines the importance of energy system planning within the process of urban planning. [ABSTRACT FROM AUTHOR]

Published

2021

2. Development of Scenarios for a Multi-Model System Analysis Based on the Example of a Cellular Energy System.

Author

Kühnbach, Matthias, Guthoff, Felix, Bekk, Anke, and Eltrop, Ludger

Subjects

ENERGY futures, SYSTEM analysis, MARKETING models, DISCOURSE analysis

Abstract

Scenario analysis combined with system and market modelling is a well-established method to evaluate technological and societal developments and their impacts on future energy pathways. This paper presents a process-oriented method for developing consistent energy scenarios using multiple energy system models. Its added value is that the developed energy scenarios are consistent in a multi-model environment and practicable for a broader target group from scientists to practitioners. The scenarios consist of comprehensive storylines and systematically defined quantitative parameters. Following a step-by-step process, a condensed set of overlapping descriptors is generated and used to define the scenarios in a consistent parameter matrix. The set of descriptors allow consistent and comparable outputs independent of model-specific characteristics. The corresponding quantitative parameters can be used by diverse energy system tools. Using multiple models, a team of researchers can explore questions from differing points of view. In an example study, we apply the method to develop scenarios in the context of a cellular energy system. This approach enables the development of scenarios that provide a consistent basis for both stakeholder discourse and multi-model system analysis. [ABSTRACT FROM AUTHOR]

Published

2020

3. A Life Cycle Assessment of Biomethane Production from Waste Feedstock Through Different Upgrading Technologies.

Author

Florio, Ciro, Fiorentino, Gabriella, Corcelli, Fabiana, Ulgiati, Sergio, Dumontet, Stefano, Güsewell, Joshua, and Eltrop, Ludger

Subjects

BIOGAS, METHANE as fuel, NATURAL gas, CRYOGENICS, COGENERATION of electric power & heat

Abstract

Upgrading consists of a range of purification processes aimed at increasing the methane content of biogas to reach specifications similar to natural gas. In this perspective, an environmental assessment, based on the Life Cycle Assessment (LCA) method, of different upgrading technologies is helpful to identify the environmental characteristics of biomethane and the critical steps for improvement. The aim of this work is to conduct an LCA of biomethane production from waste feedstock, using the SimaPro software. The study focuses on the comparison of several upgrading technologies (namely, membrane separation, cryogenic separation, pressure swing adsorption, chemical scrubbing, high pressure water scrubbing) and the on-site cogeneration of electricity and heat, including the environmental benefits deriving from the substitution of fossil-based products. The results show a better environmental performance of the cogeneration option in most of the impact categories. The Fossil resource scarcity is the impact category which is mainly benefited by the avoided production of natural gas, with savings of about 0.5 kg oil eq/m3 of biogas for all the investigated technologies, with an average improvement of about 76% compared to conventional cogeneration. The results show that the membrane upgrading technology is slightly more environmentally convenient than the other upgrading technologies. [ABSTRACT FROM AUTHOR]

Published

2019