A system for disassembling a display device includes a supporting part facing a window and supporting at least a portion of the window. A window fixing part is disposed on the supporting part and is configured to fix a position of the window with respect to the supporting part. A display panel stopper is positioned above the supporting part and is spaced apart from the supporting part by a predetermined distance. A window pressurizing part is configured to apply pressure to the second region of the window along a first orthogonal to an upper surface of the supporting part. A separating stick is movable along a second direction which intersects the first direction. The separating stick is configured to be inserted between the window and a display panel adhered to the window.

A method for manufacturing a display device includes a stage; a first guide unit positioned on one side of the stage in a first direction and extending in a second direction crossing the first direction; and a first peeling unit disposed on the first guide unit, wherein the first peeling unit includes a first moving part configured to move along the first guide unit, a first rotating part coupled to the other side of the first moving part in the first direction and configured to rotate about an axis extending in the first direction, and a first gripping part coupled to the other side of the first rotating part in the first direction and disposed to overlap the stage.

A wafer de-bonding device comprises a stage (1) for holding a device wafer and a carrier wafer bonded together, and a tool (2) with a gas outlet (2.2) disposed in proximity to the stage (1) through an adjustment device for control the tool (2) to move towards or away from the stage (1), the tool (2) being provided with a bit (2.1) to cut a notch into a film or an adhesive layer at a junction of the bonded wafers, the gas outlet (2.2) being provided on the tool bit (2.1), the tool (2) being further provided with a gas inlet (2.3) in communication with the gas outlet (2.2), the gas inlet (2.3) being connected to a gas jet generator so as to direct a gas jet towards the junction of the bonded wafers on the stage (2). The wafer de-bonding device has a high degree of automation and simple operations.

An object of the present invention is to make it possible to easily remove a carrier film when removing the carrier film from a gasket body in a carrier-film-equipped gasket, which includes a combination of a rubber-only type gasket body and a resinous carrier film that retains the gasket body, even if the gasket body is adhered to the carrier film. To fulfill the object, a step for peeling, against an adhesive force, the carrier film from the gasket body in a state in which the gasket body is fixed to a base, is carried out. As a preliminary step of the peeling step, the gasket body is pressed from the carrier film side by a pressing device thereby to decrease the adhesion area between the gasket body and the carrier film, and the peeling step is carried out in a state in which the adhesion area has been decreased.

A process is disclosed for using two polymeric bonding material layers to bond a device wafer and carrier wafer in a way that allows debonding to occur between the two layers under low-force conditions at room temperature. Optionally, a third layer is included at the interface between the two layers of polymeric bonding material to facilitate the debonding at this interface. This process can potentially improve bond line stability during backside processing of temporarily bonded wafers, simplify the preparation of bonded wafers by eliminating the need for specialized release layers, and reduce wafer cleaning time and chemical consumption after debonding.

In various embodiments, an assembly for handling a semiconductor die is provided. The assembly may include a carrier with a surface. The assembly may also include an adhesive tape fixed to the surface of the carrier. The adhesive tape may be configured to adhere to the semiconductor die. The adhesive tape may include adhesive, the adhesion of which can be reduced by means of electromagnetic waves. The assembly may further include an electromagnetic source configured to apply electromagnetic waves to the adhesive tape to reduce adhesion of the adhesive tape to the semiconductor die. The assembly may additionally include a die pick-up component configured to pick up the semiconductor die from the adhesive tape.

A wafer de-bonding device comprises a stage (1) for holding a device wafer and a carrier wafer bonded together, and a tool (2) with a gas outlet (2.2) disposed in proximity to the stage (1) through an adjustment device for control the tool (2) to move towards or away from the stage (1), the tool (2) being provided with a bit (2.1) to cut a notch into a film or an adhesive layer at a junction of the bonded wafers, the gas outlet (2.2) being provided on the tool bit (2.1), the tool (2) being further provided with a gas inlet (2.3) in communication with the gas outlet (2.2), the gas inlet (2.3) being connected to a gas jet generator so as to direct a gas jet towards the junction of the bonded wafers on the stage (2). The wafer de-bonding device has a high degree of automation and simple operations.

A system for disassembling a display device includes a supporting part facing a window and supporting at least a portion of the window. A window fixing part is disposed on the supporting part and is configured to fix a position of the window with respect to the supporting part. A display panel stopper is positioned above the supporting part and is spaced apart from the supporting part by a predetermined distance. A window pressurizing part is configured to apply pressure to the second region of the window along a first orthogonal to an upper surface of the supporting part. A separating stick is movable along a second direction which intersects the first direction. The separating stick is configured to be inserted between the window and a display panel adhered to the window.

A system and method for peeling a semiconductor chip from a tape using a multistage ejector is disclosed. A housing in the multistage ejector houses a plural sets of tape removing contacts. A pick and place unit is moved slowly to have contact with the chip. A vacuum source is utilized for generating vacuum to suck the tape. Plural sets of contacts such as inner, middle and outer contacts are independently or together moved below the tape at various stages by utilizing their respective actuation mechanism. A controller can independently control the movements of each contact to effectively remove or loosen the tape from the chip. A pick and place unit can then pick up the chip easily without any damage to chip.

This disclosure relates to a device for separating two substrates to be utilized in electronics, optics, optoelectronics and/or photovoltaics. The device separates the substrates at an interface, the device comprising a holder; a member for retaining the structure, the member being mounted on the holder; a tool for separating the two substrates, also mounted on the holder; and means for moving the separating tool and/or means for moving the retaining member relative to the holder so as to bring them closer together or move them farther apart from each other, preferably over a limited range of travel. This device is noteworthy in that the separating tool comprises a leading edge that has, in cross-section, in succession from its tip or its front edge to its back, a tapered portion that is extended by a flared portion.