Summary
To date, most modern, off-the-shelf battery designs targeting lightweight application use lithium-ion technology. This is due to the fact that other existing technologies such as NiMH and Pb:Acid are often too heavy, leading to energy densities inferior to those of Li-Ion technologies. New technologies must improve upon energy density, whilst also employing green, recyclable designs and avoiding the use of critical raw materials.
In addition, the rapid increase in the number of electrified vehicles, especially those employing fast-charging systems, has lead to an increasing load on energy generation systems. During periods of mass travel (for example, during the summer vacation season), this can lead to severe loading. It is therefore important to consider the whole of the electric vehicle system – not only at the vehicle level, but also at the infrastructure level.
Europe is very strong in terms of its capacity to produce final products (such as EVs and stationary storage systems), but is weaker when considering its capacity to produce and use raw materials, advanced materials, and equipment for manufacturing cells. The overarching of goal of the TEMPEST project is to develop and mature a new generation of safe-by-design, recyclable, high-performance, and lightweight batteries for the largest possible swath of transport applications.
TEMPEST will bring to TRL5 advanced, module-free battery systems, optimized using AI algorithms, and based on both LIC and SSC cell chemistries through three different demonstrator batteries types (compact, large-scale, and stationary) selected as representative batteries for the range of use case applications targeted (automotive, aircraft, maritime, rail, and stationary). TEMPEST has access to direct capacity to scale results.
In addition, the rapid increase in the number of electrified vehicles, especially those employing fast-charging systems, has lead to an increasing load on energy generation systems. During periods of mass travel (for example, during the summer vacation season), this can lead to severe loading. It is therefore important to consider the whole of the electric vehicle system – not only at the vehicle level, but also at the infrastructure level.
Europe is very strong in terms of its capacity to produce final products (such as EVs and stationary storage systems), but is weaker when considering its capacity to produce and use raw materials, advanced materials, and equipment for manufacturing cells. The overarching of goal of the TEMPEST project is to develop and mature a new generation of safe-by-design, recyclable, high-performance, and lightweight batteries for the largest possible swath of transport applications.
TEMPEST will bring to TRL5 advanced, module-free battery systems, optimized using AI algorithms, and based on both LIC and SSC cell chemistries through three different demonstrator batteries types (compact, large-scale, and stationary) selected as representative batteries for the range of use case applications targeted (automotive, aircraft, maritime, rail, and stationary). TEMPEST has access to direct capacity to scale results.
Unfold all
/
Fold all
More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101103681 |
| Start date: | 01-05-2023 |
| End date: | 30-04-2026 |
| Total budget - Public funding: | 3 614 902,50 Euro - 3 614 902,00 Euro |
Cordis data
Original description
To date, most modern, off-the-shelf battery designs targeting lightweight application use lithium-ion technology. This is due to the fact that other existing technologies such as NiMH and Pb:Acid are often too heavy, leading to energy densities inferior to those of Li-Ion technologies. New technologies must improve upon energy density, whilst also employing green, recyclable designs and avoiding the use of critical raw materials.In addition, the rapid increase in the number of electrified vehicles, especially those employing fast-charging systems, has lead to an increasing load on energy generation systems. During periods of mass travel (for example, during the summer vacation season), this can lead to severe loading. It is therefore important to consider the whole of the electric vehicle system – not only at the vehicle level, but also at the infrastructure level.
Europe is very strong in terms of its capacity to produce final products (such as EVs and stationary storage systems), but is weaker when considering its capacity to produce and use raw materials, advanced materials, and equipment for manufacturing cells. The overarching of goal of the TEMPEST project is to develop and mature a new generation of safe-by-design, recyclable, high-performance, and lightweight batteries for the largest possible swath of transport applications.
TEMPEST will bring to TRL5 advanced, module-free battery systems, optimized using AI algorithms, and based on both LIC and SSC cell chemistries through three different demonstrator batteries types (compact, large-scale, and stationary) selected as representative batteries for the range of use case applications targeted (automotive, aircraft, maritime, rail, and stationary). TEMPEST has access to direct capacity to scale results.
Status
SIGNEDCall topic
HORIZON-CL5-2022-D2-01-05Update Date
31-07-2023
Images
No images available.
Geographical location(s)
Structured mapping
Unfold all
/
Fold all
Search
Organisations
-
| RESCOLL (Coördinator)
-
| ALBION TECHNOLOGIES LTD
-
| AVESTA BATTERY & ENERGY ENGINEERING
-
| FRAUNHOFER GESELLSCHAFT ZUR FOERDERUNG DER ANGEWANDTEN FORSCHUNG E.V.
-
| Fundación Tekniker
-
| IAAPS Limited
-
| KAUNO TECHNOLOGIJOS UNIVERSITETAS
-
| KEMIJSKI INSTITUT
-
| SUSTAINABLE INNOVATIONS EUROPE SL
-
| UNIVERSITY OF BATH (UBAH)
-
| University of Patras - PANEPISTIMIO PATRON