News Article
Synova receives order from solar manufacturer
The company received a multi system order from a European solar cell manufacturer. Synova’s Laser MicroJet upends conventional approaches to address proprietary polysilicon wafer technology.
Synova, patent holder of water jet guided laser technology, announced a follow on order for its Laser MicroJet (LMJ) systems from a European based solar cell manufacturer. Representing one of Synova's largest equipment orders to date, the 25 LMJ systems will be integrated into its customer's edge defined film fed growth (EFG) process at its European based solar fab. These LMJ modules, the core of Synova's Laser MicroJet technology, will be used to cut the venture's 125 and 156 mm polysilicon EFG octagonal tubes into wafers for solar cell manufacturing. Several LMJ systems have already been shipped and installed, with the remaining modules to be integrated throughout 2009 and 2010.
Wafering, the cutting of silicon tubes into wafers, is a new application area for Synova's Laser MicroJet, which offers a superior alternative to conventional approaches, especially traditional lasers. Contrary to results by conventional lasers, Synova's LMJ approach offers a less abrasive cutting process without causing heat damage, micro cracks and burr formations that can weaken the wafers' fracture strength. In fact, Synova's LMJ approach results in wafers with a 250 percent higher fracture strength, a significant contributing factor to increasing solar cell yield and lifetime. Notably, since LMJ produces nearly damage free edges, it eliminates the need for extra processing steps, such as edge etching, reducing manufacturing costs. In addition, the technology's "wet" approach expels from the wafer surface the contaminants inherent to any cutting process, thereby increasing overall solar cell quality and efficiency.
Commenting on the announcement, Bernold Richerzhagen, Synova's chief executive officer, noted, "This major production order has provided Synova with a unique opportunity to help speed production, adoption and overall efficiency and quality of today's leading edge solar cells. This milestone order for LMJ systems not only represents an important order volume for the company, but is a testament to tremendous growth opportunity for Synova in the solar market. We are thrilled that our IP will be a key manufacturing ingredient to our customer's new breed of high quality solar cells."
Synova's Laser MicroJet system can be flexibly incorporated into the production line as either a standalone system or integrated into existing equipment. The LMJ systems purchased by the customer will be custom configured with a 200 watt dual cavity green laser source, maximising throughput. This order builds on Synova's recent momentum in the solar market. In February, Synova announced a collaborative R&D alliance with Europe's largest solar research organisation, the Fraunhofer Institute for Solar Energy Systems (ISE). This joint development project is chartered with investigating the use of LMJ for laser chemical processing (LCP) to further explore LMJ's wafering and microstructuring applications that will both speed processing and improve the performance of solar cells. In fall 2007, Synova licensed integration systems to solar equipment manufacturer Manz Automation, which unveiled its inline laser edge isolation system for photovoltaic (PV) manufacturing of mono and multi crystalline solar cells.
Wafering, the cutting of silicon tubes into wafers, is a new application area for Synova's Laser MicroJet, which offers a superior alternative to conventional approaches, especially traditional lasers. Contrary to results by conventional lasers, Synova's LMJ approach offers a less abrasive cutting process without causing heat damage, micro cracks and burr formations that can weaken the wafers' fracture strength. In fact, Synova's LMJ approach results in wafers with a 250 percent higher fracture strength, a significant contributing factor to increasing solar cell yield and lifetime. Notably, since LMJ produces nearly damage free edges, it eliminates the need for extra processing steps, such as edge etching, reducing manufacturing costs. In addition, the technology's "wet" approach expels from the wafer surface the contaminants inherent to any cutting process, thereby increasing overall solar cell quality and efficiency.
Commenting on the announcement, Bernold Richerzhagen, Synova's chief executive officer, noted, "This major production order has provided Synova with a unique opportunity to help speed production, adoption and overall efficiency and quality of today's leading edge solar cells. This milestone order for LMJ systems not only represents an important order volume for the company, but is a testament to tremendous growth opportunity for Synova in the solar market. We are thrilled that our IP will be a key manufacturing ingredient to our customer's new breed of high quality solar cells."
Synova's Laser MicroJet system can be flexibly incorporated into the production line as either a standalone system or integrated into existing equipment. The LMJ systems purchased by the customer will be custom configured with a 200 watt dual cavity green laser source, maximising throughput. This order builds on Synova's recent momentum in the solar market. In February, Synova announced a collaborative R&D alliance with Europe's largest solar research organisation, the Fraunhofer Institute for Solar Energy Systems (ISE). This joint development project is chartered with investigating the use of LMJ for laser chemical processing (LCP) to further explore LMJ's wafering and microstructuring applications that will both speed processing and improve the performance of solar cells. In fall 2007, Synova licensed integration systems to solar equipment manufacturer Manz Automation, which unveiled its inline laser edge isolation system for photovoltaic (PV) manufacturing of mono and multi crystalline solar cells.
