The present application relates to a substrate transfer device, comprising a horizontally arranged cross beam, and support beams longitudinally arranged at two ends of the cross beam, wherein a substrate carrier is suspended on the cross beam, the substrate carrier is located between the two support beams, and the substrate carrier is parallel to a plane where the two support beams are located, the substrate carrier comprises two side walls oppositely arranged in a horizontal direction, and each of the support beams is provided with an auxiliary clamping structure for clamping the substrate carrier during transferring of the substrate carrier.

The present invention provides a vertical feeding and wafer inserting integrated machine, comprising a rack and a silicon wafer transfer device provided on the rack; a carrying-transporting water tank for carrying and transporting silicon wafers is provided on one end of the rack; the rack is further provided with a feeding unit for conveying the silicon wafers in the carrying-transporting water tank to a silicon wafer transfer belt a wafer inserting unit for inserting the silicon wafers into wafer baskets is provided on one end, away from the feeding unit, of the silicon wafer transfer device, and a wafer basket arraying mechanism is provided on the other end of the wafer inserting unit; and a washing manipulator for transferring grouped wafer baskets to a washing procedure is further correspondingly provided on the rack.

A substrate processing apparatus includes a carrier block on which a carrier configured to store a substrate is placed, first processing block including a plurality of first processing modules, and a first transport mechanism shared by the plurality of first processing modules to transport the substrate, second processing block overlapping the first processing block, including a plurality of second processing modules, and a second transport mechanism shared by the plurality of second processing modules to transport the substrate, and configured to transport the substrate to the carrier block. The substrate processing apparatus includes a lifting and transferring mechanism including a shaft extending in a horizontal direction and a support part configured to face and support the substrate, and a rotation mechanism configured to rotate the support part around the shaft such that an orientation of the support part is changed between a first orientation and the second position.

A substrate processing apparatus includes; a carrier block; a first processing block including first lower and upper processing blocks to deliver a substrate to and from the carrier block; a second processing block including second lower and upper processing blocks provided adjacent to the first lower and upper processing blocks; a relay block including a lifting and transferring mechanism that delivers the substrate between the second lower and upper processing blocks; a controller that controls an operation of each main transfer mechanism such that one of upper and lower processing blocks forms an outward path through which the substrate is transferred from the carrier block to the relay block and the other forms a return path through which the substrate is transferred from the relay block to the carrier block; and a bypass transfer mechanism provided for each of the first and second processing blocks.

A deposition apparatus includes a first substrate support for supporting a substrate in a substantially vertical orientation. The substrate has a first main surface, a second main surface opposite the first main surface and a side surface between the first main surface and the second main surface. The deposition apparatus includes a first deposition device for depositing a first conductive pattern or a first resist mask on the side surface of the substrate while the substrate is supported in the substantially vertical orientation by the first substrate support.

One object of this application is to provide an advanced substrate holder including a clamper. A substrate holder for holding a substrate by interposing the substrate between frames is disclosed. The substrate holder includes a front frame, a rear frame, and one or a plurality of clampers. Each of the clampers includes a hook portion including a hook base and a hook main body, and a plate including at least one claw. At least one of the clampers includes the plate including a first claw for a lock and a second claw for a semi-lock.

A transport system of the in-line coater moves the substrate holder from chamber to chamber in a direction perpendicular to the axis of its rotation and in each process chamber. The system moves the substrate holder to the working area along its axis of rotation. The process chamber has a cavity the size of which is determined by the dimensions of the substrate holder and is sufficient to place technology devices and monitoring instruments in it. In the first embodiment of the in-line coater, the supporting frame of the transport system on which the substrate holder is cantilevered, is configured to move from the chamber to the chamber both in horizontal and vertical positions. In the second embodiment of the in-line coater the supporting frame is configured to move only in a vertical position, and the in-line coater comprises additionally a substrate holder return chamber.

The present invention relates to an electronic component test handler comprising: a hand configured to pick up and transfer a plurality of devices; and a scanner configured to scan a region of a movement path of a device picked up by the hand at a predetermined angle. The electronic component test handler having a flying scan function according to the present invention is capable of scanning during a transfer process without a change in position after picking up a device, and thus, operations and time required for the scanning may be reduced, thereby improving efficiency.

The disclosure relates to a clipping mechanism for fastening a substrate for a surface treatment of the substrate, a clipping module for holding a substrate for a surface treatment of the substrate and a method for assembling a clipping mechanism for fastening a substrate for a surface treatment of the substrate. The clipping mechanism for fastening a substrate for a surface treatment of the substrate comprises a clipping bracket and an actuation unit. The clipping bracket comprises in a cross-section a first arm and a second arm. The first arm is moveable relative to the second arm to a receiving position for the substrate with a receiving distance between the first arm and the second arm. The first arm is moveable relative to the second arm to a fastening position for the substrate with a fastening distance between the first arm and the second arm. The fastening distance is smaller than the receiving distance. The actuation unit is at least partially surrounded by the clipping bracket. At least a portion of the actuation unit is moveable relative to the clipping bracket to move the first arm in the receiving position or the fastening position.

The present disclosure relates to an apparatus for transferring a light emitting diode (LED). The apparatus for transferring an LED includes: a pick-up unit configured to pick up at least some of multiple light emitting diodes (LEDs) arranged on one substrate, and, according to a received control signal, put down LEDs selected from among the picked-up LEDs on another substrate; and a controller configured to transmit the control signal to the pick-up unit so as to enable the pick-up unit to individually pick up or put down each of the multiple LEDs.