A device and method for at least partial loosening of a connecting layer of a temporarily bonded substrate stack. The device has at least one ring, whereby the substrate stack can be placed within the at least one ring, the at least one ring having a plurality of nozzles. The nozzles are arranged distributed at least over a portion of the periphery of the at least one ring, the nozzles directed onto the connecting layer. The device sprays solvent from the nozzles onto an edge area of the connecting layer.

A method for manufacturing a circuit board includes: forming a first adhesive layer on a first surface of a vibration unit, in which the vibration unit includes at least one piezoelectric material layer; forming a first stacking structure on the first adhesive layer; and applying a voltage to the at least one piezoelectric material layer to cause the at least one piezoelectric material layer to vibrate, such that the first stacking structure is separate from the vibration unit.

Methods for separating a plurality of diamagnetic directed self-assembled diamagnetic components are provided. One method includes, for instance: contacting a release substrate to the plurality of diamagnetic components, the plurality of diamagnetic components including a non-diamagnetic component affixed to a diamagnetic portion by a first adhesive, and removing the release substrate, the non-diamagnetic component being affixed to a final substrate by a second adhesive and the release substrate being affixed to the diamagnetic portion by a third adhesive, and wherein the removing removes the diamagnetic portion and at least a portion of the first adhesive from the non-diamagnetic component.

A movable member is gripped in a delamination-start configuration, and the other-end side of a rib of a delamination member is pressed towards the other-end side of a flexible plate. The flexible plate then warps and deforms about the other end side of the flexible plate, which is supported by a support member, the flexible plate deforming along the direction in which delamination progresses. In concert with the delamination action, a reinforcing plate also warps and deforms along with the flexible plate, the reinforcing plate being vacuum-chucked to an air-permeable electroconductive sheet on the flexible plate, and the reinforcing plate is sequentially delaminated from a substrate 2 along the direction in which delamination progresses.

A technique for protecting a portion of a screen panel during a process for disassembling and servicing a display screen device is provided. A first part of the display screen device is separated from a screen panel part of the display screen device, where the screen panel part includes a main screen portion and a circuit of flexible printable circuit board (FPCB) portion. An encapsulant is applied onto a break protectable layer (BPL) of the circuit of flexible printable circuit board (FPCB) portion. The screen panel part is washed, with a solvent to remove residue from the main screen portion.

Systems and methods for debonding a carrier from a semiconductor device are disclosed herein. In one embodiment, a system for debonding a carrier from a semiconductor device includes a support member positioned to carry the semiconductor device and a fluid delivery device having an exit positioned to direct a fluid toward an adhesive layer between the carrier and the semiconductor device. The fluid directed from the fluid delivery device initiates debonding of the carrier from the semiconductor device by weakening or loosening at least a portion of the adhesive. The system further includes a liftoff device configured to releasably engage the carrier and apply a debonding force to the carrier to complete debonding of the carrier from the semiconductor device.

A method for separating different types of material layers of a composite component that has at least one material layer that is transparent for visible light and at least one further material layer, is provided, wherein the light from an external source falls through the at least one transparent material layer into the at least one further material layer and there is at least partially absorbed. With the help of at least one gas discharge lamp, the light-absorbing material layer is heated in less than one second to separate material layers of the composite component. A device that can be used for this method comprises at least one separation chamber and therein at least one gas discharge lamp suitable for irradiation.

A cover structure for a light source includes a frame having an inner space, a driver, and an oxygen discharger. The frame is combined with the light source such that an object disposed in the inner space is covered by the frame, and the inner space is sealed by the combined frame and light source to provide a closed space between the frame and the light source enclosing the object. The driver combines the frame and the light source by moving the frame toward the light source such that the frame contacts the light source. The oxygen discharger creates a low-oxygen state in the closed space by discharging oxygen from the closed space.

A film separation apparatus and a film separation method are disclosed. The film separation apparatus includes a mechanical arm, a needle and a stopping member; the needle has one end connected to the mechanical arm and the other end including a needle tip; the stopping member includes a connecting rod and a stopper, the connecting rod has one end connected to the mechanical arm and the other end connected to the stopper, the needle tip is configured to be inserted into a film to be separated, the stopper and the needle tip are configured to move with respect to each other in an extension direction of the needle so as to separate the film to be separated from the needle tip.

The present invention relates to a laminate and a device fabricated using the laminate. The laminate includes a debonding layer including a polyimide resin between a carrier substrate and a flexible substrate. The adhesive strength of the debonding layer to the flexible substrate is changed by a physical stimulus. According to the present invention, the flexible substrate can be easily separated from the carrier substrate without the need for further processing such as laser or light irradiation. Therefore, the use of the laminate facilitates the fabrication of the device having the flexible substrate. The device may be, for example, a flexible display device. In addition, the device can be prevented from deterioration of reliability and occurrence of defects caused by laser or light irradiation. This ensures improved characteristics and high reliability of the device.