Thin Film Future Conference Analysis
Magic Cost Price
A solar installation over 6,000 m2 has been built in a field near to the German town of Waltenhofen. Its total power is 0.4 MW. Seven kilometers of electrical cable is required to transport the power generated by the Mitsubishi Heavy Industry thin-film solar panels. Another solar power plant has been produced next to this field in the same amount of space, but in this case using crystalline silicon solar panels. At 0.7 MV, the power from this plant is almost twice as much as that from the other installation.
Thin Film Future Conference Analysis
At the Thin-Film Future conference that the Dutch company SolarPlaza had recently organized in Munich, Manfred Bächler of Phoenix Solar displayed an aerial photograph of the two plants prior to entering into a discussion on which of the two techniques would be most beneficial: ‘Thin-film panels produce a lower yield of 6 to 10 % compared with 12 to 17 % from crystalline silicon,’ says Bächler. ‘Due to the lower power of the thin-film modules, more work is involved in installing them. After all, to achieve the same power, you use a larger surface area than for a crystalline silicon installation. Moreover, more supporting constructions are needed.’
Anyone led to think, as a result of this comparison, that the fate of thin-film technology is sealed should think again. The evidence for that is already apparent judging by the fact that over the past few years real-estate developer Phoenix Solar has been selling increasing numbers of installations that use thin-film cells at the expense of traditional silicon cells. This is party due to the company having succeeded in making drastic cuts to the cost of supporting constructions, increasing yields from thin-film cells, and reducing the cost of cabling and inverters. According to Bächler, it is extremely important to reassess the choice of either thin-film or silicon for each new project. ‘The debate about supplying power able to compete with the electricity grid is more complex and involved than most people realize,’ Bächler concluded.
Despite Bächler putting this into perspective, there would seem to be plenty of companies that believe in thin-film technology. Proof of this comes from recently published figures from the Prometheus Institute. In 2001, the share taken by thin-film technology within the power produced from solar panels was at 4.8 %. Six years later, this share had grown to 10 %. One important explanation for this sharp rise is not only the fact that silicon is expensive but that the material has been difficult to get hold of in the recent past due to a lack of manufacturing capacity. ‘Spectacular growth is occurring within the thin-film industry,’ says Travis Bradford of the Prometheus Institute.
Figure 1. Edwin Koot; CEO SolarPlaza and Travis Bradford; President Prometheus Institute
‘The number of companies is also increasing sharply; at present, approximately thirty are actively producing productive power of at least 5 MW. It’s anticipated that there will be 70 by 2010.’ Over 50 % of thin-film companies are using amorphous silicon as semiconductor material, followed next by 19 % using CIGS (Copper Indium Gallium Diselenide). In third place comes CdTe (Cadmium Telleride) at 10 %, while the upcoming “third generation” of solar cells, including organic cells, is taking up 15 % of the market. One of the upcoming companies is Nanosolar, which, in its own words, produces the cheapest solar panel in the world. Nanosolar uses CIGS as a semiconductor; the secret of its cheap manufacturing process lies in the use of a pressure process rather than a high vacuum process for lodging the light-sensitive material. Flexible film replaces the customary glass as a substrate. Moreover, the panel has been designed to cut the balance-of-system (BOS) costs by half compared with competitor panels. Clearly, this has been a success, as the huge demand has already meant that new orders for Nanosolar panels cannot be delivered within the next 12 months.
Figure 2. Martin Roscheisen, CEO of Nanosolar at The Thin-film Future
According to Fumihiro Tanikawa of Kaneka Solar, deciding on thin-film technology is not a difficult choice to make. ‘Crystalline silicon panels lose some power when the temperature rises, but amorphous silicon PV modules generate more power in the summer,’ says Tanikawa. ‘Amorphous silicon panels are able to provide maximum performance in that period when power is needed for the air conditioning in homes and offices.’ According to Kaneka’s statistics, the amorphous silicon panel is also able to extract more electrical power from a given quantity of sunlight, and the material is extremely environmentally friendly: a layer of amorphous silicon is 0.3 micrometers thick, and that is 1/600th the thickness of a crystalline silicon cell. Moreover, the energetic investment return-time for making an amorphous silicon panel is said to be only 1.6 years, which is six months less than that for producing a crystalline silicon panel.
Magic Cost Price
As far as environmental factors of solar panels are concerned, Stephan Hansen pointed to the approach taken by his company, First Solar. Anyone who has ever bought a CdTe solar panel from First Solar can make use of its recycling program. All costs attached to this, such as disassembly and transport, are paid for by First Solar, the 1999-founded company having set aside the money required for this through an international insurance company. Material from the used panel is reintroduced to the manufacturing process as far as is possible. Just as with so many other companies in the thin-film industry, First Solar’s goal is to achieve the magic price of $1 per Wp. Once that price has been reached, grid-parity will have been attained, and PV will be able to compete with the prevailing price of electricity. Hansen showed a number of graphs that indicated a gradually declining trend in terms of production costs. In the first quarter of 2006, for example, a panel cost $1.60 per Wp; in the first quarter, the price fell to $ 1.29, after which the price continued to fall with a few ups and downs to $ 1.18 per Wp in the first quarter of this year. By 2012, Hansen anticipates having saved a further 50 to 55 % of the module costs and almost another 60 % relating to matters such as the inverter, the mechanical and electrical installation, and overheads. Moreover, he referred to the approach once taken by automobile manufacturer Ford: ‘in 1914, the average time taken by the customary manufacturing process was 728 minutes. Ford reduced that to 93 minutes,’ says Hansen. ‘In the same way, First Solar’s module has been consistently standardized and cost-effectively optimized by means of a frameless glass-glass laminate and standard dimensions of 600 by 1200 mm. The fully automated manufacturing process has shortened the manufacturing process from 24 hours to less than 3, making lower investment necessary.’
Primary Author: Rijkert Knoppers