Periodic Reporting for period 1 - PRISM (Panel Recycling and Integrated Solar Material)
Période du rapport: 2024-04-01 au 2024-12-31
The PRISM project aims to address the growing problem of photovoltaic (PV) waste through an innovative, high-efficiency recycling process. With global installed PV capacity expected to reach 4,500 GW by 2050, the volume of decommissioned panels is set to grow significantly, leading to a pressing need for advanced recycling technologies.
Current PV recycling methods are inefficient, focusing mainly on bulk material recovery, while valuable components such as silver, copper, and silicon are often lost or incinerated. SOLAR MATERIALS has developed a patented layer-by-layer thermo-mechanical recycling process that enables the cost-effective and energy-efficient recovery of over 95% of materials from end-of-life PV panels.
With the advanced pilot and first commercial recycling plant, SOLAR MATERIALS provides a cost-effective solution for owners of solar parks including private households to recycle solar panels combining ecology and economy. The process results are the lowest recycling fee in the industry with precious and critical raw materials being sold to local industries.
Current PV recycling methods are inefficient, focusing mainly on bulk material recovery, while valuable components such as silver, copper, and silicon are often lost or incinerated. SOLAR MATERIALS has developed a patented layer-by-layer thermo-mechanical recycling process that enables the cost-effective and energy-efficient recovery of over 95% of materials from end-of-life PV panels.
With the advanced pilot and first commercial recycling plant, SOLAR MATERIALS provides a cost-effective solution for owners of solar parks including private households to recycle solar panels combining ecology and economy. The process results are the lowest recycling fee in the industry with precious and critical raw materials being sold to local industries.
The PRISM project has successfully advanced photovoltaic (PV) panel recycling from pilot-scale validation to industrial readiness. Initial tests on a fully automated pilot line for whole solar panels confirmed the effectiveness of the innovative delamination process, enabling efficient separation of valuable raw materials like silver, silicon, and high-purity glass.
Building on this success, the process was refined to enhance temperature control, bus bar removal, and silicon separation, improving material recovery quality. A large-scale recycling campaign further validated the system’s high throughput and economic viability, achieving over 95% material recovery, including silver and silicon.
Now transitioning to industrial-scale implementation, the first commercial recycling plant is being established, operating at one minute per panel. An AI-driven optimization system has been integrated to fine-tune efficiency.
With a cost-effective, scalable, and energy-efficient process, the project is setting new standards for PV recycling, driving the transition toward a circular solar economy.
Building on this success, the process was refined to enhance temperature control, bus bar removal, and silicon separation, improving material recovery quality. A large-scale recycling campaign further validated the system’s high throughput and economic viability, achieving over 95% material recovery, including silver and silicon.
Now transitioning to industrial-scale implementation, the first commercial recycling plant is being established, operating at one minute per panel. An AI-driven optimization system has been integrated to fine-tune efficiency.
With a cost-effective, scalable, and energy-efficient process, the project is setting new standards for PV recycling, driving the transition toward a circular solar economy.
The PRISM project introduces the first fully automated and scalable PV panel recycling process, surpassing conventional methods that recover only bulk materials like glass and aluminum. The patented thermo-mechanical delamination technology enables the cost-effective recovery of silver and silicon, materials previously lost in standard recycling processes.
Unlike chemical and pyrolysis-based methods, this approach avoids toxic emissions and hazardous chemicals, reducing both operational costs and environmental impact. Additionally, an AI-driven optimization system enhances process efficiency by linking material data with real-time adjustments, ensuring maximum material recovery.
With significantly lower recycling fees (50% cheaper than competitors) and a high-value output stream, this technology is a game-changer in PV recycling. It not only meets but exceeds EU regulatory targets, positioning itself as the leading solution for a truly circular solar economy.
Unlike chemical and pyrolysis-based methods, this approach avoids toxic emissions and hazardous chemicals, reducing both operational costs and environmental impact. Additionally, an AI-driven optimization system enhances process efficiency by linking material data with real-time adjustments, ensuring maximum material recovery.
With significantly lower recycling fees (50% cheaper than competitors) and a high-value output stream, this technology is a game-changer in PV recycling. It not only meets but exceeds EU regulatory targets, positioning itself as the leading solution for a truly circular solar economy.