Summary
The HighLite project aims to substantially improve the competitiveness of the EU PV manufacturing industry by developing knowledge-based manufacturing solutions for high-performance low-cost modules with excellent environnment profiles (low CO2 footprint, enhanced durability, improved recyclability).
To achieve this, the HighLite project focuses on thin (down to 100 µm) high-efficiency crystalline silicon solar cells with passivating contacts and capitalizes on the learnings from previous large funded projects. In HighLite, a unique consortium of experienced industrial actors and leading institutes will work collectively to develop, optimize, and bring to high technology readiness levels (TRL 6-7) innovative solutions at both cell and module levels. In practice, HighLite will demonstrate high-efficiency ¼ size (or smaller) cut solar cells (silicon heterojunction cells with efficiency η ≥ 23.3%, interdigated back-contact cells with η ≥ 24.3%; only 0.2% less than full size cells) in pilot-line manufacturing. Industrial tools will be developed in the project for assembling these cut-cells into high-efficiency modules tailored for various distributed generation (DG) applications. More specifically, the following developments will take place: (1) building-applied PV modules with η ≥ 22% and a carbon footprint ≤ 250 kg-eq.CO2/kWp, (2) building-integrated PV modules with η ≥ 21% and improved shading tolerance, and (3) 3D-curved vehicle-integrated PV modules with η ≥ 20% and a weight ≤ 5 kg/m2. Finally, HighLite aims to show improved cost and performance (both through indoor testing and outdoor demonstrators) against state-of-the-art commercially available modules. Altogether, it is expected that the solutions developed in HighLite will: (1) create more demand in Europe and worldwide for such DG products, (2) significantly improve the competitiveness of industrial actors that are part of the consortium, and (3) trigger significant investment in the EU PV industry.
To achieve this, the HighLite project focuses on thin (down to 100 µm) high-efficiency crystalline silicon solar cells with passivating contacts and capitalizes on the learnings from previous large funded projects. In HighLite, a unique consortium of experienced industrial actors and leading institutes will work collectively to develop, optimize, and bring to high technology readiness levels (TRL 6-7) innovative solutions at both cell and module levels. In practice, HighLite will demonstrate high-efficiency ¼ size (or smaller) cut solar cells (silicon heterojunction cells with efficiency η ≥ 23.3%, interdigated back-contact cells with η ≥ 24.3%; only 0.2% less than full size cells) in pilot-line manufacturing. Industrial tools will be developed in the project for assembling these cut-cells into high-efficiency modules tailored for various distributed generation (DG) applications. More specifically, the following developments will take place: (1) building-applied PV modules with η ≥ 22% and a carbon footprint ≤ 250 kg-eq.CO2/kWp, (2) building-integrated PV modules with η ≥ 21% and improved shading tolerance, and (3) 3D-curved vehicle-integrated PV modules with η ≥ 20% and a weight ≤ 5 kg/m2. Finally, HighLite aims to show improved cost and performance (both through indoor testing and outdoor demonstrators) against state-of-the-art commercially available modules. Altogether, it is expected that the solutions developed in HighLite will: (1) create more demand in Europe and worldwide for such DG products, (2) significantly improve the competitiveness of industrial actors that are part of the consortium, and (3) trigger significant investment in the EU PV industry.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/857793 |
| Start date: | 01-10-2019 |
| End date: | 31-03-2023 |
| Total budget - Public funding: | 15 087 603,00 Euro - 12 870 478,00 Euro |
Cordis data
Original description
The HighLite project aims to substantially improve the competitiveness of the EU PV manufacturing industry by developing knowledge-based manufacturing solutions for high-performance low-cost modules with excellent environnment profiles (low CO2 footprint, enhanced durability, improved recyclability).To achieve this, the HighLite project focuses on thin (down to 100 µm) high-efficiency crystalline silicon solar cells with passivating contacts and capitalizes on the learnings from previous large funded projects. In HighLite, a unique consortium of experienced industrial actors and leading institutes will work collectively to develop, optimize, and bring to high technology readiness levels (TRL 6-7) innovative solutions at both cell and module levels. In practice, HighLite will demonstrate high-efficiency ¼ size (or smaller) cut solar cells (silicon heterojunction cells with efficiency η ≥ 23.3%, interdigated back-contact cells with η ≥ 24.3%; only 0.2% less than full size cells) in pilot-line manufacturing. Industrial tools will be developed in the project for assembling these cut-cells into high-efficiency modules tailored for various distributed generation (DG) applications. More specifically, the following developments will take place: (1) building-applied PV modules with η ≥ 22% and a carbon footprint ≤ 250 kg-eq.CO2/kWp, (2) building-integrated PV modules with η ≥ 21% and improved shading tolerance, and (3) 3D-curved vehicle-integrated PV modules with η ≥ 20% and a weight ≤ 5 kg/m2. Finally, HighLite aims to show improved cost and performance (both through indoor testing and outdoor demonstrators) against state-of-the-art commercially available modules. Altogether, it is expected that the solutions developed in HighLite will: (1) create more demand in Europe and worldwide for such DG products, (2) significantly improve the competitiveness of industrial actors that are part of the consortium, and (3) trigger significant investment in the EU PV industry.
Status
SIGNEDCall topic
LC-SC3-RES-15-2019Update Date
26-10-2022
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EU-Programme-Call
Horizon 2020
H2020-EU.3. SOCIETAL CHALLENGES
H2020-EU.3.3. SOCIETAL CHALLENGES - Secure, clean and efficient energy
H2020-EU.3.3.2. Low-cost, low-carbon energy supply
H2020-EU.3.3.2.0. Cross-cutting call topics
H2020-LC-SC3-2019-RES-IA-CSA
LC-SC3-RES-15-2019 Increase the competitiveness of the EU PV manufacturing industry
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Organisations
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| INTERUNIVERSITAIR MICRO-ELECTRONICA CENTRUM VZW (Coördinator)
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| 3D-Micromac AG (3DM)
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| APPLIED MATERIALS ITALIA SRL
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| COMMISSARIAT A L ENERGIE ATOMIQUE ET AUX ENERGIES ALTERNATIVES (CEA)
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| Centre Suisse d'Electronique et de Microtechnique SA
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| ECOLE POLYTECHNIQUE FEDERALE DE LAUSANNE (EPFL)
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| FRAUNHOFER GESELLSCHAFT ZUR FOERDERUNG DER ANGEWANDTEN FORSCHUNG E.V.
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| Henkel Electronic Materials (Belgium) NV
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| INSTITUT FUR SOLARENERGIEFORSCHUNG GMBH
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| INTERNATIONAL SOLAR ENERGY RESEARCH CENTER KONSTANZ
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| ION BEAM SERVICES (IBS)
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| ISSOL SA
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| PI PHOTOVOLTAIK-INSTITUT BERLIN AG
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| TNO - Nederlandse Organisatie voor Toegepast Natuurwetenschappelijk Onderzoek
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| UAB SOLI TEK R&D