By Rubi Rodriguez Mendoza
Solar has grown at unprecedented rates since the early 2000s. Global PV installed capacity reached 222 GW at the end of 2015, yet it is still expected to rise to 4,500 GW by 2050. In the U.S., the current PV installed capacity is 27 GW and it is forecast to reach 600GW by 2050, according to the International Renewable Energy Agency. This is great for consumers and for the environment. However, everything we manufacture does generate waste, even PV. PV panels are very durable, with few moving parts, so they last a long time, 30 years or more, according to SolarCity. But the growth in the PV industry will increase PV waste in the next 20-30 years in the world. The good news is that most PV components can be recycled. Recycling of PV panels is just taking off in the US, but Europe has set standards and best practices the US can also adopt.
How Components are Recycled
Photovoltaic panels consist of layers of glass, encapsulant EVA (ethylene vinyl acetate), silicon wafers and metallic conductors connected to a junction box. These components are mechanically and chemically separated during the recycling process and returned to manufacturers for incorporation into new products. You can read a detailed description of the recycling process here.
Europe & US Regulations
The extent to which the PV panels are recycled is closely tied with regulations that foster environmental practices in the solar industry. For instance PV Cycle, a European non-profit organization founded in 2007, works closely with governments and companies in the private sector to establish PV waste management strategies and legal compliance for companies and waste producers. PV Cycle partners with industries and governments to reduce the environmental impact of end-life PV panels and to require recycling to be the responsibility of producers. Currently, it is collaborating with manufacturing companies to adopt a design-for-recycling mindset so that PVs are easier and cheaper to recycle.
By contrast, the U.S. is just starting to develop policies and regulations for PV recycling. In October of 2015, California updated its Photovoltaic Panel Collection and Recycling Act of 2014 to require that “a PV panel producer shall establish and operate a take-back program for the collection, transportation, recovery, and environmentally sound recycling of end-of-life PV panels.” There may come a day when recycling PV panels will be enough of an economic opportunity, as new infrastructure for waste management emerges, that it won’t be so dependent on regulations, according to a report by IRENA.
Recycling Opportunities for the Future
Given that cumulative end-of-life PV waste volume in the U.S. is expected to grow from 6,500 tons at the end of 2016 to 7.5 to 10 million tons by 2050, a big opportunity for growth of the PV recycling market exists. For instance, First Solar, one of the few U.S.-based companies to do PV recycling, could likely benefit from this trend by creating more recycling sites in the country or increasing the recycling capacity of its sites.
Countries that foresee growth in their PV markets need to develop policies and markets to address the environmental impact of future PV waste volume. Programs like PV Cycle and regulations such as the California Recycling Act are a good foundation to make necessary improvements. PV waste management will absolutely be a challenge in the coming years. Therefore we need to find synergy between the different parties involved in the PV market, including science, technology, business and policy, in order to reduce the negative environmental impact of end-of-life PV panels.
The New Buildings Institute recently recognized Point Energy Innovations as a Zero Net Energy (ZNE) leader for work on ZNE schools in California.
“Point Energy Innovations (PEI) is a leader in driving schools toward ZNE,” NBI said.
“The firm’s design of the Newcastle Elementary School, under the Prop 39 ZNE School Retrofit Pilot Program, went well beyond a simple retrofit coupled with massive photovoltaics. The team relentlessly pursued deep green measures achieving an energy use intensity of 16 (saving 36%), providing cost-effective ZNE as a package, and a healthier, quality environment for students and teachers.”
The Prop 39 ZNE School Retrofit Pilot Program provides state funding to public schools and community colleges to improve energy efficiency and increase their use of clean energy.