Solar panels embedded in clothes can charge mobile phone
Smart Textiles
Embedded solar cells bring power to fabrics
Material appears and behaves the same as any ordinary textile and can be washed in a machine at 40°C.
17th October 2022
Innovation in Textiles
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Nottingham, United Kingdom
Research overseen by Dr Theodore Hughes-Riley, associate professor of Electronic Textiles at the Nottingham School of Art and Design in the UK, has led to the development of a woven textile embedded with 1,200 photovoltaic cells.
The cells combined together are capable of harnessing 400 milliwatts (mWatts) of electrical energy from the sun – sufficient to charge a basic mobile phone or smartwatch.
The e-textile is an advanced prototype which could be incorporated into a piece of clothing such as a jacket, or used as part of accessories such as backpacks or handbags.
Fitted with strong but very flexible wiring, it is designed to be exposed to the same forces as everyday clothing and can be washed in a machine at 40°C with other laundry.
The solar cells – which measure only five millimetres in length and 1.5 millimetres in width – are embedded in a waterproof polymer resin and cannot be felt by the wearer.
“This prototype gives an exciting glimpse of the future potential for e-textiles,” said Dr Hughes-Riley, of the university’s Advanced Textiles Research Group (ATRG). “Until now very few people would have considered that their clothing or textile products could be used for generating electricity. The material which we have developed, for all intents and purposes, appears and behaves the same as any ordinary textile, as it can be scrunched up and washed in a machine, but hidden beneath the surface is a network of more than a thousand tiny photovoltaic cells which can harness the sun’s energy to charge personal devices.
“Electronic textiles really have the potential to change people’s relationship with technology, as this prototype shows how we could do away with charging many devices at the wall. This development builds on previous technologies we have made and it can be scaled up to generate more power.”
The material, which measures 51cm by 27cm, is breathable and chemically stable as all the solar cells are made from silicone.
Tests showed that the material generated a power output of 335.3 mWatts in 0.86 sunlight. Under 1.0 sun it would generate up to 394 mWatts.
The project team included Dr Neranga Abeywickrama, who worked as a postdoctoral research fellow in energy harvesting and management in textiles, and PhD candidate Matholo Kgatuke, research associate in the weaving of electronic textiles.
“This project shows how e-textiles can be at the forefront of sustainability and that they have the potential to reshape our existing conceptions of technology,” said Ms Kgatuke. “We have combined long-established weaving techniques with modern technology to create future products which may change people’s perceptions of clothing and electronics.”
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