| TP SOLAR, INC. Patent applications |
| Patent application number | Title | Published |
|---|
| 20120132638 | Finger Drives for IR Wafer Processing Equipment Conveyors and Lateral Differential Temperature Profile Methods - A new class of work-piece conveyors, comprising zero-mass, shadow-less transport systems, with a drive having a pair of parallel, laterally spaced, movable chains defining a processing path, with fingers projecting transversely toward the process path centerline. The gap between fingers eliminates conveyor tube/rod supports, improving wafer quality and conserving energy. Implementations include wire chain, band and roller chain transports to which fingers are secured. Fingers are angled down so that the intersection of the bottom and side edges of the work-piece make only point contacts with each finger. A pair of finger chains implement a single lane drive; adding center bilateral finger drive chains with oppositely pointing fingers implement a multi-lane system. The inventive method includes individually configurable processing temperature profiles in side-by-side lanes, on a zone-by-zone, upper and lower half basis for broad processing flexibility. A novel transducer-based lamp-voltage control system provides stable lamp power for precise temperature control. | 05-31-2012 |
| 20110306160 | Diffusion Furnaces Employing Ultra Low Mass Transport Systems and Methods of Wafer Rapid Diffusion Processing - Multi-zone, solar cell diffusion furnaces having a plurality of radiant element (SiC) or/and high intensity IR lamp heated process zones, including baffle, ramp-up, firing, soaking and cooling zone(s). The transport of solar cell wafers, e.g., silicon, selenium, germanium or gallium-based solar cell wafers, through the furnace is implemented by use of an ultra low-mass, wafer transport system comprising laterally spaced shielded metal bands or chains carrying non-rotating alumina tubes suspended on wires between them. The wafers rest on raised circumferential standoffs spaced laterally along the alumina tubes, which reduces contamination. The bands or chains are driven synchronously at ultra-low tension by a pin drive roller or sprocket at either the inlet or outlet end of the furnace, with appropriate tensioning systems disposed in the return path. The high intensity IR flux rapidly photo-radiation conditions the wafers so that diffusion occurs >3× faster than conventional high-mass thermal furnaces. | 12-15-2011 |
| 20110013892 | Rapid Thermal Firing IR Conveyor Furnace Having High Intensity Heating Section - High reflectance element IR lamp module and method of firing multi-zone IR furnaces for solar cell processing comprising lamps disposed backed by a flat or configured plate of ultra-high reflectance ceramic material. Optionally, the high reflectance plate can be configured with ripples or grooves to isolate each lamp from adjacent lamps in the process zone. Furnace cooling air is exhausted and recycled upstream for energy conservation. Lamp spacing can be varied and power to each lamp individually controlled to provide infinite control of temperature profile in each heating zone. The high reflectance element may be constructed of dense ceramic fiber board, and then coated with high reflectance ceramic composition, and baked or fired to form the finished element. | 01-20-2011 |
| 20100267188 | Diffusion Furnaces Employing Ultra Low Mass Transport Systems and Methods of Wafer Rapid Diffusion Processing - Multi-zone, solar cell diffusion furnaces having a plurality of radiant element (SiC) or/and high intensity IR lamp heated process zones, including baffle, ramp-up, firing, soaking and cooling zone(s). The transport of solar cell wafers, e.g., silicon, selenium, germanium or gallium-based solar cell wafers, through the furnace is implemented by use of an ultra low-mass, wafer transport system comprising laterally spaced shielded metal bands or chains carrying non-rotating alumina tubes suspended on wires between them. The wafers rest on raised circumferential standoffs spaced laterally along the alumina tubes, which reduces contamination. The bands or chains are driven synchronously at ultra-low tension by a pin drive roller or sprocket at either the inlet or outlet end of the furnace, with appropriate tensioning systems disposed in the return path. The high intensity IR flux rapidly photo-radiation conditions the wafers so that diffusion occurs >3× faster than conventional high-mass thermal furnaces. | 10-21-2010 |
