A removal module for removing a mis-assembled semiconductor light emitting diode includes a housing having an inner space formed by an upper plate having a nozzle hole and a lower plate spaced apart from the upper plate; a fluid supply part configured to supply a fluid outside the housing to the inner space; and a fluid control part configured to control spray of the fluid supplied to the inner space through the nozzle hole by adjusting a pressure of the inner space.

An adsorption device includes a substrate and a magnetic film on a surface of the substrate. The substrate has magnetic properties and is capable of generating magnetic field. The magnetic film partially covers the surface. The magnetic film generates a magnetic field having a direction that is opposite to a direction of the magnetic field generated by the substrate. Portions of the surface of the substrate not covered by the magnetic film form positions to attract and adsorb target objects, and other portion of the surface of the substrate covered by the magnetic film is not able to attract any target object.

Discussed is an assembly board including: a base portion; a plurality of assembly electrodes extending in one direction and disposed on the base portion at predetermined intervals; a dielectric layer stacked on the base portion to cover the plurality of assembly electrodes; and barrier ribs stacked on the dielectric layer and defining cells in which semiconductor light emitting diodes are seated at the predetermined intervals along an extending direction of the plurality of assembly electrodes so as to overlap a portion of the plurality of assembly electrodes, wherein the plurality of assembly electrodes include first electrodes and second electrodes disposed on different planes on the base portion, and wherein the first electrodes are disposed on one surface of the base portion, and the second electrodes are disposed on one surface of the dielectric layer.

Disclosed in the present specification are a substrate for transferring, with high reliability, a semiconductor light emitting element, and a method for manufacturing a display device by using same. Particularly, when a semiconductor light emitting element is self-assembled on an assembly substrate by using an electromagnetic field, an assembly groove in which a semiconductor light emitting element for alignment is assembled is formed in the assembly substrate. The semiconductor light emitting element for alignment, assembled in the assembly groove, is used for alignment in a step of being transferred to a final wiring substrate. Unlike conventional alignment keys, the semiconductor light emitting element for alignment reflects an alignment error of semiconductor light emitting elements that occurs during a transfer process after assembly. Therefore, when semiconductor light emitting elements are transferred to a wiring substrate on the basis of the semiconductor light emitting element for alignment, transfer accuracy can be improved.

The present invention relates to a display device manufacturing method and, particularly, to a chip tray for supplying a micro-LED. The present invention provides a chip tray for carrying semiconductor light emitting diodes in a fluid received in an assembly chamber. The chip tray includes a tray unit for receiving a plurality of semiconductor light emitting diodes; a chip alignment unit disposed on one side of the tray unit and having a plurality of magnets; and a transfer unit configured to move the tray unit and the chip alignment unit, wherein the transfer unit can vertically move one of the tray unit and the chip alignment unit with respect to the other one thereof.

Method and arrangement for assembling one or more microchips (415; 615; 715; 815; 915; 1015) into one or more holes (422; 722), respectively, in a substrate surface (421; 721) of a separate receiving substrate (420; 720; 820; 1020). The holes (422; 722) of the substrate is for microchip insertion out-of-plane in relation to said substrate surface. Each of said microchips is provided with a ferromagnetic layer (213; 613) of ferromagnetic material. The microchips are placed (503) on said substrate surface (421; 721) and it is applied and moved (504) one or more magnetic fields affecting said ferromagnetic layer (213; 613) of each microchip such that the microchips thereby become out-of-plane oriented in relation to said substrate surface (421; 721) and move over the substrate surface (421; 721) until assembled into said holes (422; 722).

A nanowire LED, a display module including the nanowire LED, and a method for manufacturing the display module are provided. The method for manufacturing a display module includes forming a template layer including a magnetic layer on a silicon substrate, growing a plurality of nanowire LEDs on the template layer, separating the plurality of nanowire LEDs from the template layer by ultrasonic waves, forming a plurality of unit cells in a state in which the plurality of nanowire LEDs are aligned to have a specific directivity, forming a plurality of unit pixels by transferring the plurality of unit cells onto a unit substrate, arranging the plurality of unit pixels on a thin film transistor (TFT) substrate through a fluidic self-assembly, and bonding the plurality of unit pixels to be connected to an electrode of the TFT substrate.

A transferring method includes providing an adsorption device, using the adsorption device to attract and hold a plurality of light emitting diodes (LEDs), providing a target substrate with a plurality of spots of anisotropic conductive adhesive on a surface of the target substrate; moving the adsorption device or the target substrate wherein each of the plurality of LEDs adsorbed by the adsorption device becomes in contact with one of the plurality of spots of anisotropic conductive adhesive; and curing the plurality of spots of anisotropic conductive adhesive on the target substrate and moving away the adsorption device.

A transferring method, a manufacturing method, a device and an electronic apparatus of micro-LED. The method for transferring micro-LED, comprises: forming micro-LEDs (202) on a laser-transparent original substrate (201), providing an anisotropic conductive layer (203) on a receiving substrate (204), bringing the micro-LEDs (202) into contact with the anisotropic conductive layer (203) on the receiving substrate (204), irradiating the original substrate (201) with laser from the original substrate side to lift-off the micro-LEDs (202) from the original substrate (201), and processing the anisotropic conductive layer (203), to electrically connect the micro-LEDs (202) with the pads (205′) on the receiving substrate (204).

The present invention discloses a assembling method, a manufacturing method, an device and an electronic apparatus of flip-die. The method for assembling a flip-die, comprises: temporarily bonding the flip-die onto a laser-transparent first substrate, wherein bumps of the flip-die are located on the side of the flip-die opposite to the first substrate; aligning the bumps with pads on a receiving substrate; irradiating the original substrate with laser from the first substrate side to lift-off the flip-die from the first substrate; and attaching the flip-die on the receiving substrate. A faster assembly rate can be achieved by using the present invention. A smaller chip size can be achieved by using the present invention. A lower profile can be achieved by using the present invention.