Poland innovative ion cell technology — POLON (Q78854): Difference between revisions
Jump to navigation
Jump to search
(Removed claim: summary (P836): Reference_reference_programme_aids:SA.41471 (2015/X).Protect_public_pomo_public_:Article 25 of Commission Regulation (EC) No 651/2014 of 17 June 2014 declaring certain categories of aid compatible with the internal market in the application of Article 107 and 108 of the Treaty (OJ(OJ LL 187/1 of 26.06.2014).The purpose of the project is to confirm on a semi-technical basis the feasibility and characteristics of Li-ion cells manufactured on the...) |
(Created claim: summary (P836): Reference number of the aid programme: SA.41471(2015/X). Purpose of public aid: Article 25 of EC Regulation No 651/2014 of 17 June 2014 declaring certain types of aid compatible with the internal market in the application of Articles 107 and 108 of the Treaty (OJ L. I'm sorry. EU L 187/1 of 26.06.2014).The aim of the project is to confirm on a semi-technical scale the feasibility and properties of lithium-ion cells (Li-ion) produced on the basis...) |
||||||||||||||
| Property / summary | |||||||||||||||
Reference number of the aid programme: SA.41471(2015/X). Purpose of public aid: Article 25 of EC Regulation No 651/2014 of 17 June 2014 declaring certain types of aid compatible with the internal market in the application of Articles 107 and 108 of the Treaty (OJ L. I'm sorry. EU L 187/1 of 26.06.2014).The aim of the project is to confirm on a semi-technical scale the feasibility and properties of lithium-ion cells (Li-ion) produced on the basis of its innovative technology for producing nanocomposite cathode material based on CCL-coated nanostructured LiFePO4 (nano-LFP). The technology combines two patent-protected inventions developed at the Jagiellonian University and the AGH University, and allows the production of premium Li-ion cells for energy storage systems (ESS) and hybrid and electric vehicles (xEV). In order to achieve the objective of the project, a fully functional semi-technical installation for the production of CCL/nano-LFP nanocomposite and Li-ion cell assembly line type 18650 (performance of 15000 pcs/year) will be constructed. Cells based on this technology will have higher capacity (+ 10 %), greater load capacity (up to 10C), thermal overload resistance due to improved heat dissipation by carbon coating, safety of use and lower manufacturing costs compared to LFP-based cells. The technology uses the aquatic environment and is a low-emission process consistent with the principles of green chemistry. Lithium-ion cells with CCL/nano-LFP cathode produced in accordance with this technology have a higher durability which increases the life of the product, reducing the amount of hazardous waste. The advantages of the product derive directly from the improved electrochemical properties of the nano-LFP material resulting from its use in the form of a nanomaterial (increased capacity and power), the use of conductive, nanometric manufacturing process (English) | |||||||||||||||
| Property / summary: Reference number of the aid programme: SA.41471(2015/X). Purpose of public aid: Article 25 of EC Regulation No 651/2014 of 17 June 2014 declaring certain types of aid compatible with the internal market in the application of Articles 107 and 108 of the Treaty (OJ L. I'm sorry. EU L 187/1 of 26.06.2014).The aim of the project is to confirm on a semi-technical scale the feasibility and properties of lithium-ion cells (Li-ion) produced on the basis of its innovative technology for producing nanocomposite cathode material based on CCL-coated nanostructured LiFePO4 (nano-LFP). The technology combines two patent-protected inventions developed at the Jagiellonian University and the AGH University, and allows the production of premium Li-ion cells for energy storage systems (ESS) and hybrid and electric vehicles (xEV). In order to achieve the objective of the project, a fully functional semi-technical installation for the production of CCL/nano-LFP nanocomposite and Li-ion cell assembly line type 18650 (performance of 15000 pcs/year) will be constructed. Cells based on this technology will have higher capacity (+ 10 %), greater load capacity (up to 10C), thermal overload resistance due to improved heat dissipation by carbon coating, safety of use and lower manufacturing costs compared to LFP-based cells. The technology uses the aquatic environment and is a low-emission process consistent with the principles of green chemistry. Lithium-ion cells with CCL/nano-LFP cathode produced in accordance with this technology have a higher durability which increases the life of the product, reducing the amount of hazardous waste. The advantages of the product derive directly from the improved electrochemical properties of the nano-LFP material resulting from its use in the form of a nanomaterial (increased capacity and power), the use of conductive, nanometric manufacturing process (English) / rank | |||||||||||||||
Normal rank | |||||||||||||||
| Property / summary: Reference number of the aid programme: SA.41471(2015/X). Purpose of public aid: Article 25 of EC Regulation No 651/2014 of 17 June 2014 declaring certain types of aid compatible with the internal market in the application of Articles 107 and 108 of the Treaty (OJ L. I'm sorry. EU L 187/1 of 26.06.2014).The aim of the project is to confirm on a semi-technical scale the feasibility and properties of lithium-ion cells (Li-ion) produced on the basis of its innovative technology for producing nanocomposite cathode material based on CCL-coated nanostructured LiFePO4 (nano-LFP). The technology combines two patent-protected inventions developed at the Jagiellonian University and the AGH University, and allows the production of premium Li-ion cells for energy storage systems (ESS) and hybrid and electric vehicles (xEV). In order to achieve the objective of the project, a fully functional semi-technical installation for the production of CCL/nano-LFP nanocomposite and Li-ion cell assembly line type 18650 (performance of 15000 pcs/year) will be constructed. Cells based on this technology will have higher capacity (+ 10 %), greater load capacity (up to 10C), thermal overload resistance due to improved heat dissipation by carbon coating, safety of use and lower manufacturing costs compared to LFP-based cells. The technology uses the aquatic environment and is a low-emission process consistent with the principles of green chemistry. Lithium-ion cells with CCL/nano-LFP cathode produced in accordance with this technology have a higher durability which increases the life of the product, reducing the amount of hazardous waste. The advantages of the product derive directly from the improved electrochemical properties of the nano-LFP material resulting from its use in the form of a nanomaterial (increased capacity and power), the use of conductive, nanometric manufacturing process (English) / qualifier | |||||||||||||||
point in time: 14 October 2020
| |||||||||||||||
Revision as of 10:31, 14 October 2020
Project in Poland financed by DG Regio
| Language | Label | Description | Also known as |
|---|---|---|---|
| English | Poland innovative ion cell technology — POLON |
Project in Poland financed by DG Regio |
Statements
Q2524466 (Deleted Item)
0 references
14,331,306.64 zloty
0 references
19,999,441.36 zloty
0 references
71.66 percent
0 references
1 January 2017
0 references
30 June 2020
0 references
MARCELLI ADV TECH SPÓŁKA Z OGRANICZONĄ ODPOWIEDZIALNOŚCIĄ
0 references
49°47'27.6"N, 20°22'45.8"E
0 references
Numer_referencyjny_programu_pomocowego: SA.41471(2015/X). Przeznaczenie_pomocy_publicznej: art. 25 rozporządzenia KE nr 651/2014 z dnia 17 czerwca 2014 r. uznające niektóre rodzaje pomocy za zgodne z rynkiem wewnętrznym w stosowaniu art. 107 i 108 Traktatu (Dz. Urz. UE L 187/1 z 26.06.2014).Celem projektu jest potwierdzenie w skali półtechnicznej wykonalności i właściwości ogniw litowo-jonowych (Li-ion) wytwarzanych w oparciu o posiadaną innowacyjną technologię wytwarzania nanokompozytowego materiału katodowego opartego na pokrytym węglem CCL nanostrukturalnym LiFePO4 (nano-LFP). Technologia łączy w sobie dwa chronione patentami wynalazki opracowane na Uniwersytecie Jagiellońskim oraz Akademii Górniczo-Hutniczej, i pozwala na wytwarzanie ogniw Li-ion klasy premium do zastosowań w systemach magazynowania energii (ESS) oraz pojazdach z napędem hybrydowym i elektrycznym (xEV). Dla osiągnięcia celu projektu zostanie skonstruowana w pełni funkcjonalna półtechniczna instalacja do produkcji nanokompozytu CCL/nano-LFP oraz linia montażowa ogniw Li-ion typu 18650 (wydajność 15000 szt./rok). Ogniwa wytwarzane w oparciu o powyższą technologię będą się cechować większą pojemnością (+10%), większą obciążalnością (do 10C), odpornością na przeciążenia termiczne dzięki lepszemu rozpraszaniu ciepła przez powłokę węglową, bezpieczeństwem użytkowania oraz niższymi kosztami wytwarzania w porównaniu do ogniw dostępnych na rynku wykonanych w technologii LFP. Technologia wykorzystuje środowisko wodne i jest nisko emisyjnym procesem zgodnym z zasadami zielonej chemii. Ogniwa litowo-jonowe z katodą CCL/nano-LFP wytworzoną zgodnie z tą technologią mają większą trwałość co wydłuża czas życia produktu, zmniejszając ilość odpadów niebezpiecznych. Przewagi produktu wynikają bezpośrednio z polepszonych właściwości elektrochemicznych materiału nano-LFP wynikających z zastosowania go w formie nanomateriału (zwiększona pojemność i moc), zastosowaniu procesu wytwarzania przewodzących, nanometrycznych (Polish)
0 references
Reference number of the aid programme: SA.41471(2015/X). Purpose of public aid: Article 25 of EC Regulation No 651/2014 of 17 June 2014 declaring certain types of aid compatible with the internal market in the application of Articles 107 and 108 of the Treaty (OJ L. I'm sorry. EU L 187/1 of 26.06.2014).The aim of the project is to confirm on a semi-technical scale the feasibility and properties of lithium-ion cells (Li-ion) produced on the basis of its innovative technology for producing nanocomposite cathode material based on CCL-coated nanostructured LiFePO4 (nano-LFP). The technology combines two patent-protected inventions developed at the Jagiellonian University and the AGH University, and allows the production of premium Li-ion cells for energy storage systems (ESS) and hybrid and electric vehicles (xEV). In order to achieve the objective of the project, a fully functional semi-technical installation for the production of CCL/nano-LFP nanocomposite and Li-ion cell assembly line type 18650 (performance of 15000 pcs/year) will be constructed. Cells based on this technology will have higher capacity (+ 10 %), greater load capacity (up to 10C), thermal overload resistance due to improved heat dissipation by carbon coating, safety of use and lower manufacturing costs compared to LFP-based cells. The technology uses the aquatic environment and is a low-emission process consistent with the principles of green chemistry. Lithium-ion cells with CCL/nano-LFP cathode produced in accordance with this technology have a higher durability which increases the life of the product, reducing the amount of hazardous waste. The advantages of the product derive directly from the improved electrochemical properties of the nano-LFP material resulting from its use in the form of a nanomaterial (increased capacity and power), the use of conductive, nanometric manufacturing process (English)
14 October 2020
0 references
Identifiers
POIR.01.02.00-00-0006/16
0 references