1366’s Direct Wafer process has the unique ability to locally-control wafer thickness and provide standard 180-200 micron thickness in stress-critical areas such as wafer perimeter or ribs where busbar soldering will occur, while reducing thickness to 100-120 microns for the remainder of the wafer. Image: 1366 Technologies
1366 Technologies has unveiled the first of a series of R&D achievements using its proprietary ‘Direct Wafer’ process to grow a three dimensional wafer or a thin wafer with a thick border, an advancement, deemed impossible with conventional ingot-based production technologies.
To decrease the amount of silicon used by photovoltaic wafers, manufacturers have long pursued methods to reduce wafer thickness. While wire sawing can be used to produce wafers thinner than the standard 180-200 micron thickness, these thin wafers have reduced mechanical integrity and break during cell fabrication, electrical interconnection and encapsulation in modules. As such, standard industry wafer thickness has remained between 180-200 microns.
1366’s Direct Wafer process has the unique ability to locally-control wafer thickness and provide standard 180-200 micron thickness in stress-critical areas such as wafer perimeter or ribs where busbar soldering will occur, while reducing thickness to 100-120 microns for the remainder of the wafer. The result cuts silicon consumption to ~1.5 g/W and creates a strong, thin wafer able to withstand typical manufacturing stresses. The 3D feature further reduces the amount of silicon required for each wafer without sacrificing strength, durability or performance. It also allows the dominant crystalline silicon PV supply chain to lower costs while leveraging its existing infrastructure.
Direct Wafer production of thin wafers with thick border.
1366’s Direct Wafer technology is a transformative manufacturing process that offers significant advantages over traditional ingot-based wafer production technologies, including the ability to introduce new wafer features that reduce cost and increase efficiency. The process makes wafers in a single step, pulling them directly from molten silicon instead of today’s multi-step, energy- and capital-intensive approach, resulting in significant wafer production cost savings.