Summary
As a response to the need to decrease the transportation related emissions and energy consumption, today, all major passenger car and other light-duty vehicle manufacturers are broadening their electric vehicle portfolio. The dependency of the present electrical traction motors on the rare materials, such as rare earth permanent magnet materials, namely Neodymium-Iron-Boron magnets, is problematic from several viewpoints: they are imported and expensive and there is a real risk for supply problems in the coming years. To strengthen the European competitiveness, VOLTCAR ('Design, manufacturing, and validation of ecocycle electric traction motor') proposes high-speed, permanent magnet assisted synchronous reluctance technology with a drastic reduction in rare materials' utilisation.
During VOLTCAR, the motor prototype is perfected to meet the strictest performance requirements (power density, efficiency), sustainability criteria (recyclability, circularity and low use of rare resources and copper) and the expectations of the automotive sector (cost, reliability, integrability). This major goal is supported by introducing digital design and optimisation methodologies that are capable of assessing the life cycle costs, energy consumption, and carbon footprint in the early phase, guiding the outcomes towards maximised sustainability with reduced use of rare materials and efficient recycling and repurposing patterns. The validity of the VOLTCAR motor prototypes, 50 kW and 120 kW motor, and related technologies is proved according to the automotive standards, presenting an X-in-the-loop (XiL) experimentation environments. With this development, VOLTCAR will simultaneously lead to more green jobs in local SMEs throughout Europe to reduce unemployment rate.
The VOLTCAR consortium comprises world-leading automotive Tier 1 and Tier 2 companies and research partners with complementary knowledge and expertise for the successful execution of the proposed work.
During VOLTCAR, the motor prototype is perfected to meet the strictest performance requirements (power density, efficiency), sustainability criteria (recyclability, circularity and low use of rare resources and copper) and the expectations of the automotive sector (cost, reliability, integrability). This major goal is supported by introducing digital design and optimisation methodologies that are capable of assessing the life cycle costs, energy consumption, and carbon footprint in the early phase, guiding the outcomes towards maximised sustainability with reduced use of rare materials and efficient recycling and repurposing patterns. The validity of the VOLTCAR motor prototypes, 50 kW and 120 kW motor, and related technologies is proved according to the automotive standards, presenting an X-in-the-loop (XiL) experimentation environments. With this development, VOLTCAR will simultaneously lead to more green jobs in local SMEs throughout Europe to reduce unemployment rate.
The VOLTCAR consortium comprises world-leading automotive Tier 1 and Tier 2 companies and research partners with complementary knowledge and expertise for the successful execution of the proposed work.
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| Web resources: | https://cordis.europa.eu/project/id/101096557 |
| Start date: | 01-02-2023 |
| End date: | 31-01-2026 |
| Total budget - Public funding: | 5 997 135,75 Euro - 5 997 135,00 Euro |
Cordis data
Original description
As a response to the need to decrease the transportation related emissions and energy consumption, today, all major passenger car and other light-duty vehicle manufacturers are broadening their electric vehicle portfolio. The dependency of the present electrical traction motors on the rare materials, such as rare earth permanent magnet materials, namely Neodymium-Iron-Boron magnets, is problematic from several viewpoints: they are imported and expensive and there is a real risk for supply problems in the coming years. To strengthen the European competitiveness, VOLTCAR ('Design, manufacturing, and validation of ecocycle electric traction motor') proposes high-speed, permanent magnet assisted synchronous reluctance technology with a drastic reduction in rare materials' utilisation.During VOLTCAR, the motor prototype is perfected to meet the strictest performance requirements (power density, efficiency), sustainability criteria (recyclability, circularity and low use of rare resources and copper) and the expectations of the automotive sector (cost, reliability, integrability). This major goal is supported by introducing digital design and optimisation methodologies that are capable of assessing the life cycle costs, energy consumption, and carbon footprint in the early phase, guiding the outcomes towards maximised sustainability with reduced use of rare materials and efficient recycling and repurposing patterns. The validity of the VOLTCAR motor prototypes, 50 kW and 120 kW motor, and related technologies is proved according to the automotive standards, presenting an X-in-the-loop (XiL) experimentation environments. With this development, VOLTCAR will simultaneously lead to more green jobs in local SMEs throughout Europe to reduce unemployment rate.
The VOLTCAR consortium comprises world-leading automotive Tier 1 and Tier 2 companies and research partners with complementary knowledge and expertise for the successful execution of the proposed work.
Status
SIGNEDCall topic
HORIZON-CL5-2022-D5-01-09Update Date
09-02-2023
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Organisations
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| TEKNOLOGIAN TUTKIMUSKESKUS VTT OY (Coördinator)
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| BORGWARNER TURBO SYSTEMS ENGINEERING GMBH
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| DANFOSS MOBILE ELECTRIFICATION OY
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| HIDRIA ROTOMATIKA DOO/, INDUSTRIJA ROTACIJSKIH SISTEMOV
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| KATHOLIEKE UNIVERSITEIT LEUVEN
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| KOLEKTOR GROUP VODENJE IN UPRAVLJANJE DRUZB DOO (KOL)
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| KREMENCHUK MYKHAILO OSTROHRADSKYI NATIONAL UNIVERSITY
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| LUT University
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| ROBERT BOSCH GMBH
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| RTD TALOS LIMITED
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| SIEMENS INDUSTRY SOFTWARE NV (SISW)
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| University of Ljubljana, Faculty of Mechanical engineering