Your search keyword '"Grube, Thomas"' showing total 14 results

1. A Versatile Model for Estimating the Fuel Consumption of a Wide Range of Transport Modes.

Author

Khan Ankur, Atiquzzaman, Kraus, Stefan, Grube, Thomas, Castro, Rui, and Stolten, Detlef

Subjects

CHOICE of transportation, ENERGY consumption, FREIGHT & freightage, PUBLIC transit, VEHICLE models, PASSENGER traffic, TRUCKING rates

Abstract

The importance of a flexible and comprehensive vehicle fuel consumption model cannot be understated for understanding the implications of the modal changes currently occurring in the transportation sector. In this study, a model is developed to determine the tank-to-wheel energy demand for passenger and freight transportation within Germany for different modes of transport. These modes include light-duty vehicles (LDVs), heavy-duty vehicles (HDVs), airplanes, trains, ships, and unmanned aviation. The model further estimates future development through 2050. Utilizing standard driving cycles, backward-looking longitudinal vehicle models are employed to determine the energy demand for all on-road vehicle modes. For non-road vehicle modes, energy demand from the literature is drawn upon to develop the model. It is found that various vehicle parameters exert different effects on vehicle energy demand, depending on the driving scenario. Public transportation offers the most energy-efficient means of travel in the forms of battery electric buses (33.9 MJ/100 pkm), battery electric coaches (21.3 MJ/100 pkm), fuel cell electric coaches (32.9 MJ/100 pkm), trams (43.3 MJ/100 pkm), and long-distance electric trains (31.8 MJ/100 pkm). International shipping (9.9 MJ/100 tkm) is the most energy-efficient means of freight transport. The electrification of drivetrains and the implementation of regenerative braking show large potential for fuel consumption reduction, especially in urban areas. Occupancy and loading rates for vehicles play a critical role in determining the energy demand per passenger-kilometer for passenger modes, and tonne-kilometer for freight modes. [ABSTRACT FROM AUTHOR]

Published

2022

2. A techno-economic perspective on solar-tohydrogen concepts through 2025.

Author

Grube, Thomas, Reul, Julian, Reuß, Markus, Calnan, Sonya, Monnerie, Nathalie, Schlatmann, Rutger, Sattler, Christian, Robinius, Martin, and Stolten, Detlef

Published

2020

3. Costs of Making Hydrogen Available in Supply Systems Based on Renewables.

Author

Grube, Thomas and Höhlein, Bernd

Published

2016

4. Power-to-Steel: Reducing CO2 through the Integration of Renewable Energy and Hydrogen into the German Steel Industry.

Author

Otto, Alexander, Robinius, Martin, Grube, Thomas, Schiebahn, Sebastian, Praktiknjo, Aaron, and Stolten, Detlef

Subjects

RENEWABLE energy sources, FURNACES, COMBUSTION equipment, CARBON sequestration, CARBON dioxide mitigation

Abstract

This paper analyses some possible means by which renewable power could be integrated into the steel manufacturing process, with techniques such as blast furnace gas recirculation (BF-GR), furnaces that utilize carbon capture, a higher share of electrical arc furnaces (EAFs) and the use of direct reduced iron with hydrogen as reduction agent (H-DR). It is demonstrated that these processes could lead to less dependence on--and ultimately complete independence from--coal. This opens the possibility of providing the steel industry with power and heat by coupling to renewable power generation (sector coupling). In this context, it is shown using the example of Germany that with these technologies, reductions of 47-95% of CO2 emissions against 1990 levels and 27-95% of primary energy demand against 2008 can be achieved through the integration of 12-274 TWh of renewable electrical power into the steel industry. Thereby, a substantial contribution to reducing CO2 emissions and fuel demand could be made (although it would fall short of realizing the German government's target of a 50% reduction in power consumption by 2050). [ABSTRACT FROM AUTHOR]

Published

2017

5. Kosten der Wasserstoffbereitstellung in Versorgungssystemen auf Basis erneuerbarer Energien.

Author

Grube, Thomas and Höhlein, Bernd

Published

2014

6. Closing the loop: captured CO2 as a feedstock in the chemical industry.

Author

Otto, Alexander, Grube, Thomas, Schiebahn, Sebastian, and Stolten, Detlef

Published

2015

7. INDOCYANINE GREEN ANGIOGRAPHIC EVIDENCE OF CHOROIDITIS IN SCLERODERMA.

Author

Abdellatief, Amro, Balasubramaniam, Saranya C., Grube, Thomas J., Gonzalez Santiago, Tania M., Osborn, Thomas G., and Pulido, Jose S.

Published

2015

8. Coagulation profiles and intraoperative substitution requirements during elective piggyback liver transplantation with prophylactic antifibrinolytic therapy.

Author

Weber, Thomas, Sendt, Wolfgang, Grube, Thomas, Scheele, Johannes, and Weber, T.

Published

2002

9. Differentiated Therapy with Prostaglandin E1 (Alprostadil) after Orthotopic Liver Transplantation: the Usefulness of Procalcitonin (PCT) and Hepatic Artery Resistive Index (RI) for the Evaluation of Early Graft Function and Clinical Course.

Author

Kornberg, Arno, Grube, Thomas, Wagner, Thomas, Voigt, Rico, Homman, Merten, Homann, Merten, Schotte, Uwe, Schmidt, Karlo, and Scheele, Johannes

Published

2000

10. Hydrogen Road Transport Analysis in the Energy System: A Case Study for Germany through 2050.

Author

Reuß, Markus, Dimos, Paris, Léon, Aline, Grube, Thomas, Robinius, Martin, and Stolten, Detlef

Subjects

AUTOMOTIVE transportation, LIQUID hydrogen, FUEL cell vehicles, HYDROGEN, SUSTAINABLE transportation, HYDROGEN production, HYDROGEN storage

Abstract

Carbon-free transportation is envisaged by means of fuel cell electric vehicles (FCEV) propelled by hydrogen that originates from renewably electricity. However, there is a spatial and temporal gap in the production and demand of hydrogen. Therefore, hydrogen storage and transport remain key challenges for sustainable transportation with FCEVs. In this study, we propose a method for calculating a spatially resolved highway routing model for Germany to transport hydrogen by truck from the 15 production locations (source) to the 9683 fueling stations (sink) required by 2050. We consider herein three different storage modes, namely compressed gaseous hydrogen (CGH2), liquid hydrogen (LH2) and liquid organic hydrogen carriers (LOHC). The model applies Dijkstra's shortest path algorithm for all available source-sink connections prior to optimizing the supply. By creating a detailed routing result for each source-sink connection, a detour factor is introduced for "first and last mile" transportation. The average detour factor of 1.32 is shown to be necessary for the German highway grid. Thereafter, the related costs, transportation time and travelled distances are calculated and compared for the examined storage modes. The overall transportation cost result for compressed gaseous hydrogen is 2.69 €/kgH2, 0.73 €/kgH2 for liquid hydrogen, and 0.99 €/kgH2 for LOHCs. While liquid hydrogen appears to be the most cost-efficient mode, with the integration of the supply chain costs, compressed gaseous hydrogen is more convenient for minimal source-sink distances, while liquid hydrogen would be suitable for distances greater than 130 km. [ABSTRACT FROM AUTHOR]

Published

2021

11. Future Power Train Solutions for Long-Haul Trucks.

Author

Peters, Ralf, Breuer, Janos Lucian, Decker, Maximilian, Grube, Thomas, Robinius, Martin, Samsun, Remzi Can, and Stolten, Detlef

Abstract

Achieving the CO2 reduction targets for 2050 requires extensive measures being undertaken in all sectors. In contrast to energy generation, the transport sector has not yet been able to achieve a substantive reduction in CO2 emissions. Measures for the ever more pressing reduction in CO2 emissions from transportation include the increased use of electric vehicles powered by batteries or fuel cells. The use of fuel cells requires the production of hydrogen and the establishment of a corresponding hydrogen production system and associated infrastructure. Synthetic fuels made using carbon dioxide and sustainably-produced hydrogen can be used in the existing infrastructure and will reach the extant vehicle fleet in the medium term. All three options require a major expansion of the generation capacities for renewable electricity. Moreover, various options for road freight transport with light duty vehicles (LDVs) and heavy duty vehicles (HDVs) are analyzed and compared. In addition to efficiency throughout the entire value chain, well-to-wheel efficiency and also other aspects play an important role in this comparison. These include: (a) the possibility of large-scale energy storage in the sense of so-called 'sector coupling', which is offered only by hydrogen and synthetic energy sources; (b) the use of the existing fueling station infrastructure and the applicability of the new technology on the existing fleet; (c) fulfilling the power and range requirements of the long-distance road transport. [ABSTRACT FROM AUTHOR]

Published

2021

12. Intravitreal moxifloxacin in the management of Ochrobactrum intermedium endophthalmitis due to metallic intraocular foreign body.

Author

Jacobs, David J., Grube, Thomas J., Flynn Jr., Harry W., Greven, Craig M., Pathengay, Avinash, Miller, Darlene, Sanke, Robert F., and Thorman, Joseph

Subjects

MOXIFLOXACIN, FOREIGN bodies, EYE diseases, OCULAR injuries, VANCOMYCIN, CEFTAZIDIME

Abstract

A healthy 34-year-old man presented with Ochrobactrum intermedium endophthalmitis due to a metallic intraocular foreign body. After vitrectomy, lensectomy, removal of the metallic intraocular foreign body, intravitreal vancomycin and ceftazidime, and systemic ciprofloxacin, intraocular inflammation worsened. Repeat vitreous culture confirmed persistent endophthalmitis due to multidrug-resistant O. intermedium. The endophthalmitis successfully resolved after the administration of intravitreal moxifloxacin. [ABSTRACT FROM AUTHOR]

Published

2013

13. Future Hydrogen Markets for Transportation and Industry: The Impact of CO2 Taxes.

Author

Cerniauskas, Simonas, Grube, Thomas, Praktiknjo, Aaron, Stolten, Detlef, and Robinius, Martin

Subjects

TRANSPORTATION industry, FUTURES market, FUEL cell vehicles, ENERGY tax, CARBON taxes, MATERIALS handling

Abstract

The technological lock-in of the transportation and industrial sector can be largely attributed to the limited availability of alternative fuel infrastructures. Herein, a countrywide supply chain analysis of Germany, spanning until 2050, is applied to investigate promising infrastructure development pathways and associated hydrogen distribution costs for each analyzed hydrogen market. Analyzed supply chain pathways include seasonal storage to balance fluctuating renewable power generation with necessary purification, as well as trailer- and pipeline-based hydrogen delivery. The analysis encompasses green hydrogen feedstock in the chemical industry and fuel cell-based mobility applications, such as local buses, non-electrified regional trains, material handling vehicles, and trucks, as well as passenger cars. Our results indicate that the utilization of low-cost, long-term storage and improved refueling station utilization have the highest impact during the market introduction phase. We find that public transport and captive fleets offer a cost-efficient countrywide renewable hydrogen supply roll-out option. Furthermore, we show that, at comparable effective carbon tax resulting from the current energy tax rates in Germany, hydrogen is cost-competitive in the transportation sector by the year 2025. Moreover, we show that sector-specific CO2 taxes are required to provide a cost-competitive green hydrogen supply in both the transportation and industrial sectors. [ABSTRACT FROM AUTHOR]

Published

2019

14. The Impact of Drive Cycles and Auxiliary Power on Passenger Car Fuel Economy.

Author

Grube, Thomas and Stolten, Detlef

Subjects

ELECTRIC heating, PROCESS heating, ENERGY consumption, AIR conditioning, RAILROAD passenger cars

Abstract

In view of the advancement of zero emission transportation and current discussions on the reliability of nominal passenger car fuel economy, this article considers the procedure for assessing the potential for reducing the fuel consumption of passenger cars by using electric power to operate them. The analysis compares internal combustion engines, hybrid and fully electric concepts utilizing batteries and fuel cells. The starting point for the newly developed, simulation-based fuel consumption analysis is a longitudinal vehicle model. Mechanical power requirements on the drive side incorporate a large variety of standardized drive cycles to simulate typical patterns of car usage. The power requirements of electric heating and air conditioning are also included in the simulation, as these are especially relevant to electric powertrains. Moreover, on-board grid-load profiles are considered in the assessment. Fuel consumption is optimized by applying concept-specific operating strategies. The results show that the combination of low average driving speed and elevated onboard power requirements have severe impacts on the fuel efficiency of all powertrain configurations analyzed. In particular, the operational range of battery-electric vehicles is strongly affected by this due to the limited storage capacity of today’s batteries. The analysis confirms the significance of considering different load patterns of vehicle usage related to driving profiles and onboard electrical and thermal loads. [ABSTRACT FROM AUTHOR]

Published

2018