1 Dec 2011 | Worldwide
Energy harvesting case studies analyzed
Energy harvesting is the use of ambient energy to provide electricity for small and or mobile equipment, whether electrical or electronic. In 2011, $700 million is spent on the energy harvesting component itself, rising to just under $5 billion in 2021.
Those wishing to use energy harvesting need reassurance that it is a technology that has progressed beyond trials and new product announcements. They need to benchmark best practice. In addition, potential users and those supplying, financing or otherwise involved in energy harvesting need to identify the successful suppliers, technologies and users and learn from the failures out there. The report from IDTechEx Energy Harvesting in Action provides the answers, with analysis of over 160 successful ongoing uses of energy harvesting in 31 countries. Here we summarise some of the findings.
Most successful applicational sectors
The main ongoing uses so far of energy harvesting are in the following applicational sectors.
However, this is rapidly changing, mainly as more territories catch up with others in different aspects. For example, in energy harvesting for vehicles, Ford, Volvo, Volkswagen, BMW and others are now in extensive trials of energy harvesters for braking and capturing energy from heat.
In market value, variety of applications and number of devices, the Consumer sector is biggest of all and will remain so for the next ten years. Overall, photovoltaics is the clear winner and we believe its dominance will continue. Overall, China is the main manufacturer of products employing energy harvesting by number and value and this situation will pertain for the foreseeable future. Of the many types of energy harvesting employing electrodynamics, those capturing human energy are hugely successful. They include bicycle dynamos, wind-up radios and lights, kinetic wristwatches and miniature wind turbines.
There is a second generation of energy harvesting where two technologies are combined, notably photovoltaics with electrodynamic in laptops, radio, phone chargers, rock fall monitors, cars and road furniture, etc. This is more successful than piezoelectrics or thermoelectrics now but without the glamour. Indeed, totally new forms of photovoltaics and electrodynamics are now in ongoing use. Examples are non-silicon flexible PV in bags and apparel and electrodynamics in paving.
In our research, most suppliers of energy harvesting turn out to be small companies. In due course there will be a shakeout into large and small niche suppliers with little in between.
Further down the experience curve
The leaders in the energy harvesting market have usually been down the technological dead ends and entered second and third generation technology. There is always a doubt in the minds of potential users when they see newer companies offering technologies abandoned by the leaders yet with no clear breakthrough to explain why they can succeed where others failed. Some even offer what they can make rather than what is needed.
Leading continents and countries
By a big margin, the USA spends far more on energy harvesting products than any other country. Primarily, it takes the form of expenditure by NASA and the US Department of Defense, and the public buying consumer goods, all favouring photovoltaics.
Research in this report
In the IDTechEx report "Energy Harvesting in Action" we give more than 160 case studies of energy harvesting in ongoing use in 31 countries - enough to give some idea of the leading countries, technologies and applications. The number of case studies given by application sector in the report are shown below.
Number of case studies per applicational sector
The leading countries adopting energy harvesting in ongoing programs were as follows.
Countries adopting energy harvesting in ongoing programs
The IDTechEx Energy Harvesting & Storage Europe event, the largest in the World on the topic, will be held in Berlin, Germany on May 15-16. See www.IDTechEx.com/eheurope for details.
Top image: SaveWave
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