An embodiment method for separating semiconductor devices from a wafer comprises using a carrier which acts an adjustable adhesive force upon the semiconductor devices and removing the semiconductor devices from the carrier by applying a mechanical or acoustical impulse to the carrier.

The present invention provides a method of separating a bonded stack utilizing the force generated by a gas jet. The stack includes a carrier and a thinned workpiece such as device wafer that are bonded together through one or more layers therebetween. The gas jet can separate two adjacent layers having peeling strength therebetween in the range of from 0.01 to 50.0 g/cm. The invention can simplify the procedure and provide high throughput in separating thinned wafer from its carrier.

A separation device for a backlight source is provided. The separation device includes a machine table, at least one separation platform, where each separation platform is located above the machine table and secured at a fixed position relative to the machine table and is configured to support a display module and secure a backlight source of the display module thereon; a plurality of guide columns arranged perpendicular to the machine table, at least one adsorption mechanism arranged in a one-to-one correspondence with the at least one separation platform, where each adsorption mechanism is arranged at a side of the corresponding separation platform away from the machine table and configured to adsorb a display screen of the display module on the corresponding separation platform, and a driving unit configured to drive each adsorption mechanism to move in the lengthwise direction of the plurality of guide columns.

A method includes: a first step of disposing the superposed substrate at a position where the superposed substrate is not in contact with a first holding unit and a second holding unit in a space between the first holding unit and the second holding unit, and supplying an inert gas into the space; a second step of thereafter relatively moving the first holding unit and the second holding unit in the vertical direction, and holding the processing target substrate by the first holding unit and holding the supporting substrate by the second holding unit; and a third step of thereafter relatively moving the first holding unit and the second holding unit in the horizontal direction while heating the processing target substrate held by the first holding unit and the supporting substrate held by the second holding unit, to separate the processing target substrate and the supporting substrate from each other.

Disclosed is disassembly device for disassembling component such as touch display screen, the component comprising a first substrate and substrates which are arranged oppositely and between which adhesive is provided. The device comprises oppositely arranged two fixture mechanisms which fix the first substrate and the second substrate, respectively, and which can relatively move close to or away from each other. The device further comprises an adhesive processing mechanism, such that an adhesive force between the adhesive after processing and the first (and/or second) substrate is less than the adhesive force between the adhesive before processing and the first (and/or second) substrate. With the disassembly device according to the embodiments of the disclosure, the mutually attached first substrate and second substrate can be efficiently disassembled without damaging the first substrate and the second substrate.

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 peeling device for peeling off a substrate to be processed and a support substrate from an overlapped substrate, the overlapped substrate being formed by bonding the substrate to be processed and the support substrate by an adhesive, which includes: a first holding unit configured to heat the substrate to be processed and configured to hold the substrate to be processed; a second holding unit configured to heat the support substrate and configured to hold the support substrate; a moving mechanism configured to horizontally move at least one of the first holding unit and the second holding unit relative to each other; and an inert gas supply mechanism configured to supply an inert gas onto a bonding surface of the substrate to be processed or a bonding surface of the support substrate.

A cuff-blade attachment bushing removal tool system includes an alignment plate comprising alignment holes defined through the alignment plate in a pattern of a plurality of bushing holes of a blade root, a bladder plate connected to the alignment plate, and a bladder positioned on the bladder plate such that a gap is formed between the bladder and the alignment plate to receive a blade root to align the alignment holes and the bushing holes of the blade root, wherein the bladder is transitionable between an uninflated position where the blade root can be inserted into the gap and an inflated position where the blade root is clamped between the bladder and the alignment plate.

The present disclosure provides an apparatus for removing a chip, including: a loading station; a heating head arranged to soften an anisotropic conductive film on a substrate of a display panel for fixing the chip; a base table arranged on the loading station and arranged to support the display panel; and a base seat arranged on the loading station and arranged to support the heating head, wherein the heating head is rotatably mounted onto the base seat and the heating head has a rotation axis perpendicular to a surface of the loading station facing towards the base table. With the above apparatus, the face of the heating head facing towards the chip contacts with the face of the chip facing towards the heating head more sufficiently. The force to which the portion of the chip is subject is reduced and the force applied to the chip becomes more uniform.

Methods and apparatus relating to provision and/or utilization of a hidden feature for accessing and/or repairing mobile devices are described. An embodiment includes a wire physically adjacent to an adhesive. The adhesive bonds a first portion of a computing device and a second portion of the computing device. The wire is capable of being heated in response to application of electrical voltage or current. In turn, the heated wire causes cutting of the adhesive to allow for physical separation of the first portion of the computing device and the second portion of the computing device. Another embodiment utilizes a hidden end of an opening in a computing device to hide a fastener. Other embodiments are also disclosed and claimed.