One embodiment can provide a system for curing conductive paste applied on photovoltaic structures. The system can include a wafer carrier for carrying a plurality of photovoltaic structures and a heater. The wafer carrier can include a surface element that is in direct contact with the photovoltaic structures and is substantially thermally insulating. The heater can be positioned above the wafer carrier. The heater can include a heated radiation surface that does not directly contact the photovoltaic structures.

A system for depositing one or more layers, particularly layers including organic materials therein, is described. The system includes a load lock chamber for loading a substrate to be processed, a transfer chamber for transporting the substrate, a vacuum swing module provided between the load lock chamber and the transfer chamber, at least one deposition apparatus for depositing material in a vacuum chamber of the at least one deposition chamber, wherein the at least one deposition apparatus is connected to the transfer chamber; a further load lock chamber for unloading the substrate that has been processed, a further transfer chamber for transporting the substrate, a further vacuum swing module provided between the further load lock chamber and the further transfer chamber, and a carrier return track from the further vacuum swing module to the vacuum swing module, wherein the carrier return track is configured to transport the carrier under vacuum conditions and/or under a controlled inert atmosphere.

Pallets for transporting one or more glass substrates in a substantially vertical orientation through a sputtering system. In some cases, a pallet comprising a frame with an aperture and an adjustable grid array within the aperture. The adjustable grid array is configurable to hold a plurality of glass substrates of different shapes and/or sizes. In one case, the adjustable grid array comprises a system of vertical and horizontal support bars, wherein the vertical support bars configured to both support the plurality of glass substrates at their vertical edges, wherein the horizontal support bars are configured to support the plurality of glass substrates at their horizontal edges, wherein the ends of the horizontal support bars are slideably engaged with the vertical support bars.

A printer deposits material onto a substrate as part of a manufacturing process for an electronic product; at least one transported component experiences error, which affects the deposition. This error is mitigated using transducers that equalize position of the component, e.g., to provide an “ideal” conveyance path, thereby permitting precise droplet placement notwithstanding the error. In one embodiment, an optical guide (e.g., using a laser) is used to define a desired path; sensors mounted to the component dynamically detect deviation from this path, with this deviation then being used to drive the transducers to immediately counteract the deviation. This error correction scheme can be applied to correct for more than type of transport error, for example, to correct for error in a substrate transport path, a printhead transport path and/or split-axis transport non-orthogonality.

Disclosed herein is a resin composition for fixing a plate-shaped workpiece. The resin composition includes a composition and a photopolymerization initiator added to the composition. This composition is composed of (meth)acrylate and a plasticizer or a reactive diluent. Preferably, the composition constituting the resin composition contains 30% to 45% by mass of (meth)acrylate having an urethane bond, 5% to 15% by mass of (meth)acrylate not having an urethane bond, and 40% to 65% by mass of plasticizer, which is an ester.

A control system for a wafer transport vehicle is provided. The control system includes a control apparatus, a database, an onboard interface of the wafer transport vehicle and an operation control center. The control apparatus is arranged in a container of the wafer transport vehicle and configured to detect a environmental parameters in a container of the wafer transport vehicle and regulate the internal environment of a container of the wafer transport vehicle. The database is in communication with the control apparatus and configured store the environmental parameters detected by the control apparatus. The onboard interface is in communication with the control apparatus and configured to remotely control the control apparatus. The operation control center is in communication with the control apparatus and the onboard interface of the wafer transport vehicle and configured to receive the environmental parameters detected by the control apparatus.

Embodiments of an enclosed coating system according to the present teachings can be useful for patterned area coating of substrates in the manufacture of a variety of apparatuses and devices in a wide range of technology areas, for example, but not limited by, OLED displays, OLED lighting, organic photovoltaics, Perovskite solar cells, and organic semiconductor circuits. Enclosed and environmentally controlled coating systems of the present teachings can provide several advantages, such as: 1) Elimination of a range of vacuum processing operations such coating-based fabrication can be performed at atmospheric pressure. 2) Controlled patterned coating eliminates material waste, as well as eliminating additional processing typically required to achieve patterning of an organic layer. 3) Various formulations used for patterned coating with various embodiments of an enclosed coating apparatus of the present teachings can have a wide range of physical properties, such as viscosity and surface tension. Various embodiments of an enclosed coating system can be integrated with various components that provide a gas circulation and filtration system, a particle control system, a gas purification system, and a thermal regulation system and the like to form various embodiments of an enclosed coating system that can sustain an inert gas environment that is substantially low-particle for various coating processes of the present teachings that require such an environment.

A glass sheet semiconductor deposition system (20) for coating semiconductor material on glass sheets is performed by conveying the glass sheets vertically suspended at upper extremities thereof by a pair of conveyors (38) through a housing (22) including a vacuum chamber (24). The glass sheets are conveyed on shuttles (42) through an entry load station (26) into the housing vacuum chamber (24), through a heating station (30) and at least one semiconductor deposition station (32, 34) in the housing (22), and to a cooling station (36) prior to exiting of the system through an exit load lock station (28). The semiconductor deposition station construction includes a deposition module (102) and a radiant heater (104) between which the vertical glass sheets are conveyed for the semiconductor deposition.

The present inventions relate to the formation of a thin polymer film on a substrate. Apparatus is described for transforming a solid polymer resist into an aerosol of small particles, electrostatically charging and depositing the particles onto a substrate, and flowing the particles into a continuous layer. Apparatus is further described for transforming solid resist into an aerosol of small particles by heating the resist to form a low viscosity liquid such as is compatible with nebulization and applying the techniques of jet or impact nebulization and aerosol particle sizing to form the aerosol. A method is further described of using ionized gas to confer charge onto the aerosol particles and using a progression of charging devices establish an electric field directing the flow of charged particles to the substrate. The progression of charging devices and associated apparatus results in high collection efficiency for the aerosol particles.

A substrate carrier unit includes a substrate carrier and a phase transition material. The substrate carrier defines an isolated space therein. The phase transition material is filled into the isolated space of the substrate carrier and has a melting point ranging between 18° C. and 95° C. The phase transition material is capable of absorbing thermal energy from the substrate carrier as latent heat to change the phase from solid to liquid.