Your search keyword '"Lührs, B."' showing total 8 results

1. Potential to reduce the climate impact of aviation by climate restricted airspaces

Author

Niklaß, M., Lührs, B., Grewe, V., Dahlmann, K., Luchkova, T., Linke, F., and Gollnick, V.

Published

2019

2. Reduction of the environmental impact of aviation via optimisation of aircraft size/range and flight network

Author

Rötger, T, Casas, G, Çelikel, A, Dörries, H, Lim, L, Owen, B, van Velzen, A, Linke, F, Lührs, B, Lutz, M, Radhakrishnan, K, Rötger, T, Casas, G, Çelikel, A, Dörries, H, Lim, L, Owen, B, van Velzen, A, Linke, F, Lührs, B, Lutz, M, and Radhakrishnan, K

Abstract

REIVON is a Clean Sky 2 Technology Evaluator project that investigates to what extent CO2 emissions of global aviation can be reduced via optimisation of aircraft size/range and flight network. Three alternative global flight networks are created, considering (1) splitting long-haul flights into shorter legs (intermediate stop operations, ISO), (2) reducing frequency to the necessary minimum on busy routes using larger aircraft, and (3) a combination of 1 and 2. In all cases, the use of aircraft optimised for specific combinations of range and seating capacity not existing today will be considered. For the first time, REIVON will carry out a holistic analysis of the impact of an optimised flight network on global air transport system stakeholders, such as passengers, aircraft manufacturers, airlines and airports, and of potential measures to support the implementation of such an alternative network.

Published

2022

3. Reduction of the environmental impact of aviation via optimisation of aircraft size/range and flight network

Author

Rötger, T, primary, Casas, G, additional, Çelikel, A, additional, Dörries, H, additional, Lim, L, additional, Owen, B, additional, van Velzen, A, additional, Linke, F, additional, Lührs, B, additional, Lutz, M, additional, and Radhakrishnan, K, additional

Published

2022

4. How to efficiently design aircraft with minimum climate impact?

Author

Linke, F. (author), Radhakrishnan, K. (author), Grewe, V. (author), Vos, Roelof (author), Niklaß, Malte (author), Lührs, B. (author), Yin, F. (author), Dedoussi, I.C. (author), Proesmans, P. (author), Deck, K.T. (author), Linke, F. (author), Radhakrishnan, K. (author), Grewe, V. (author), Vos, Roelof (author), Niklaß, Malte (author), Lührs, B. (author), Yin, F. (author), Dedoussi, I.C. (author), Proesmans, P. (author), and Deck, K.T. (author)

Abstract

Given the comparably high impact of aircraft emissions, especially their non-CO2 effects, on climate in the order of 5%, aviation stakeholders are required to act to reduce the warming effects of air traffic. Besides new operational procedures, like e.g. climate-optimized routing, this demands the development of completely new global-warming optimized aircraft by aircraft manufacturers. The European Clean Sky 2 project "Global-Warming Optimized Aircraft Design" (GLOWOPT) aims at providing aircraft designers an innovative tool to perform aircraft design studies for minimum climate impact, which we call Climate Functions for Aircraft Design (CFAD). The CFAD will substantially change the way aircraft are designed, while maintaining compatibility to existing Multidisciplinary Design Optimization (MDO) methods. The functions need to integrate a lot of information on the typical aircraft usage, including the routes the aircraft will be operated on. This is because, besides the amount of emissions, the impact of aviation non-CO2 effects, such as NOx, H2O as well as contrails, on climate is highly dependent on location (i.e. latitude, longitude) and altitude. So, the representative operating profile of the aircraft needs to be considered in a characteristic route and fleet model. This work will present the interdisciplinary GLOWOPT approach, which comprises expertise on aircraft design, operations, atmospheric physics and climate. Conceptual thoughts on how the complexity of the operating profile in combination with the geographically variable climate impact of aircraft emissions will be reduced such that it can be used in an aircraft design process are given., Flight Performance and Propulsion, Aircraft Noise and Climate Effects

Published

2020

5. Quantification of Formation Flight Benefits under Consideration of Uncertainties on Fuel Planning

Author

Swaid, M., Tobias Marks, Lührs, B., and Gollnick, V.

Subjects

Optimization, Wind Influence, Fuel Planning, Lufttransportsysteme, Formation Flight

Abstract

Within this study, a method is proposed that allows an effective fuel planning for a follower aircraft in aerodynamic formation flight missions. The special characteristic of such formation missions in the context of fuel planning is the uncertainty of the successful formation execution. The required trip fuel of the follower, therefore, strongly depends on the unknown factor of the formation success. The proposed method aims at minimizing costs due to carrying excess fuel and balancing the expected benefits with potential costs that might result from a refueling stop. For a set of 14 atmospheric days of the year 2012, the fuel planning by the proposed method is applied. It is shown, that an accurate fuel planning can help saving major amounts of fuel and money additionally to the formation benefits itself.

Published

2018

6. A Concept for Multi-Criteria Environmental Assessment of Aircraft Trajectories

Author

Matthes, S, Grewe, V, Dahlmann, K, Frömming, C, Irvine, E, Lim, L, Linke, F, Lührs, B, Owen, B, Shine, K, Stromatas, S, Yamashita, H, Yin, F, Matthes, S, Grewe, V, Dahlmann, K, Frömming, C, Irvine, E, Lim, L, Linke, F, Lührs, B, Owen, B, Shine, K, Stromatas, S, Yamashita, H, and Yin, F

Abstract

Comprehensive assessment of the environmental aspects of flight movements is of increasing interest to the aviation sector as a potential input for developing sustainable aviation strategies that consider climate impact, air quality and noise issues simultaneously. However, comprehensive assessments of all three environmental aspects do not yet exist and are in particular not yet operational practice in flight planning. The purpose of this study is to present a methodology which allows to establish a multi-criteria environmental impact assessment directly in the flight planning process. The method expands a concept developed for climate optimisation of aircraft trajectories, by representing additionally air quality and noise impacts as additional criteria or dimensions, together with climate impact of aircraft trajectory. We present the mathematical framework for environmental assessment and optimisation of aircraft trajectories. In that context we present ideas on future implementation of such advanced meteorological services into air traffic management and trajectory planning by relying on environmental change functions (ECFs). These ECFs represent environmental impact due to changes in air quality, noise and climate impact. In a case study for Europe prototype ECFs are implemented and a performance assessment of aircraft trajectories is performed for a one-day traffic sample. For a single flight fuel-optimal versus climate-optimized trajectory solution is evaluated using prototypic ECFs and identifying mitigation potential. The ultimate goal of such a concept is to make available a comprehensive assessment framework for environmental performance of aircraft operations, by providing key performance indicators on climate impact, air quality and noise, as well as a tool for environmental optimisation of aircraft trajectories. This framework would allow studying and characterising changes in traffic flows due to environmental optimisation, as well as studying trade-o

Published

2017

7. Mitigating the Climate Impact from Aviation: Achievements and Results of the DLR WeCare Project

Author

Grewe, V. (author), Dahlmann, K. (author), Flink, J. (author), Frömming, C. (author), Ghosh, R. (author), Gierens, K. (author), Heller, R (author), Hendricks, J. (author), Jockel, P. (author), Kaufmann, S. (author), Kölker, K. (author), Linke, F. (author), Luchkova, T. (author), Lührs, B. (author), van Manen, Jesper (author), Matthes, S (author), Minikin, A. (author), Niklaß, Malte (author), Plohr, M. (author), Righi, M. (author), Rosanka, S. (author), Schmitt, A (author), Schumann, U (author), Terekhov, I. (author), Unterstrasser, S. (author), Vázquez-Navarro, M. (author), Voigt, C. (author), Wicke, K. (author), Yamashita, H. (author), Zahn, A. (author), Ziereis, H. (author), Grewe, V. (author), Dahlmann, K. (author), Flink, J. (author), Frömming, C. (author), Ghosh, R. (author), Gierens, K. (author), Heller, R (author), Hendricks, J. (author), Jockel, P. (author), Kaufmann, S. (author), Kölker, K. (author), Linke, F. (author), Luchkova, T. (author), Lührs, B. (author), van Manen, Jesper (author), Matthes, S (author), Minikin, A. (author), Niklaß, Malte (author), Plohr, M. (author), Righi, M. (author), Rosanka, S. (author), Schmitt, A (author), Schumann, U (author), Terekhov, I. (author), Unterstrasser, S. (author), Vázquez-Navarro, M. (author), Voigt, C. (author), Wicke, K. (author), Yamashita, H. (author), Zahn, A. (author), and Ziereis, H. (author)

Abstract

The WeCare project (Utilizing Weather information for Climate efficient and eco efficient future aviation), an internal project of the German Aerospace Center (Deutsches Zentrum für Luft- und Raumfahrt, DLR), aimed at finding solutions for reducing the climate impact of aviation based on an improved understanding of the atmospheric impact from aviation by making use of measurements and modeling approaches. WeCare made some important contributions to advance the scientific understanding in the area of atmospheric and air transportation research. We characterize contrail properties, show that the aircraft type significantly influences these properties, and how contrail-cirrus interacts with natural cirrus. Aviation NOx emissions lead to ozone formation and we show that the strength of the ozone enhancement varies, depending on where within a weather pattern NOx is emitted. These results, in combination with results on the effects of aerosol emissions on low cloud properties, give a revised view on the total radiative forcing of aviation. The assessment of a fleet of strut-braced wing aircraft with an open rotor is investigated and reveals the potential to significantly reduce the climate impact. Intermediate stop operations have the potential to significantly reduce fuel consumption. However, we find that, if only optimized for fuel use, they will have an increased climate impact, since non-CO2 effects compensate the reduced warming from CO2 savings. Avoiding climate sensitive regions has a large potential in reducing climate impact at relatively low costs. Taking advantage of a full 3D optimization has a much better eco-efficiency than lateral re-routings, only. The implementation of such operational measures requires many more considerations. Non-CO2 aviation effects are not considered in international agreements. We showed that climate-optimal routing could be achieved, if market-based measures were in place, which include these non-CO2 effects. An alternative meas, Aircraft Noise and Climate Effects

Published

2017

8. Cost-Benefit Assessment of Climate-Restricted Airspaces as an Interim Climate Mitigation Option

Author

Niklaß, M., primary, Gollnick, V., additional, Lührs, B., additional, Dahlmann, K., additional, Froemming, C., additional, Grewe, V., additional, and van Manen, J., additional

Published

2017