A hot-pressing device and process for an ACF bonding structure are provided. The hot-pressing device includes a transfer module and a first mounting plate connected to the transfer module. A negative-pressure adsorption module, at least one positioning module, and a lifting module are arranged on the first mounting plate. Pressing modules with hot-pressing assemblies are arranged at four corners close to the first mounting plate. Cleaning modules corresponding to the pressing modules are arranged in the transfer module below the first mounting plate. The present disclosure can quickly remove glue overflowing on a heat conduction element in the hot-pressing module by the cleaning module to ensure the surface flatness of a second part of the heat conduction element for hot-pressing and satisfactory resistance of an ACF connected to a substrate after hot-pressing.

A hot-pressing device and process for an ACF bonding structure are provided. The hot-pressing device includes a transfer module and a first mounting plate connected to the transfer module. A negative-pressure adsorption module, at least one positioning module, and a lifting module are arranged on the first mounting plate. Pressing modules with hot-pressing assemblies are arranged at four corners close to the first mounting plate. Cleaning modules corresponding to the pressing modules are arranged in the transfer module below the first mounting plate. The present disclosure can quickly remove glue overflowing on a heat conduction element in the hot-pressing module by the cleaning module to ensure the surface flatness of a second part of the heat conduction element for hot-pressing and satisfactory resistance of an ACF connected to a substrate after hot-pressing.

A method of anchoring a connector element (10) in a receiving object (66) comprises inserting a distal end of the connector element (10) into a mounting hole in an insertion direction along an insertion axis; inserting a sleeve (36) comprising a thermoplastic material into the mounting hole, the sleeve (36) enclosing the connector element (10); and transferring energy to liquefy at least a portion of the thermoplastic material of the sleeve (36). A machine (500) configured for carrying out the method and a connector element anchoring kit comprising a connector element (10) and a sleeve (36) comprising thermoplastic material.

Disclosed in the present invention is an auxiliary marking tape laying vehicle for laser scanning of the morphology of a long-span bridge, the laying vehicle comprising a laying portion, a guiding portion and a power transmission portion, wherein the laying portion is fixed on the top of the laying vehicle, a roller is provided on the top of the laying portion, the guiding portion is provided at the bottom of the laying vehicle, the power transmission portion is fixed outside the laying vehicle, a scroll is provided above the guiding portion, the surface of the marking tape in contact with the bridge is a rubber magnetic layer, and the other surface of the marking tape is provided with bulged reflection angles, which are used as teeth to make one end of the marking tape be connected with the roller through the teeth, and to make the other end of the marking tape be connected with the scroll through the teeth. The marking tape is installed at the bottom of the beam of the long-span bridge, and a plurality of bulges formed by the reflection angles of the marking tape are used to provide more reflection surfaces for the laser, to reduce the reflection angle, to improve the reflection effect, and then to improve the efficiency and accuracy of a three-dimensional laser scanner.

Disclosed in the present invention is an auxiliary marking tape laying vehicle for laser scanning of the morphology of a long-span bridge, the laying vehicle comprising a laying portion, a guiding portion and a power transmission portion, wherein the laying portion is fixed on the top of the laying vehicle, a roller is provided on the top of the laying portion, the guiding portion is provided at the bottom of the laying vehicle, the power transmission portion is fixed outside the laying vehicle, a scroll is provided above the guiding portion, the surface of the marking tape in contact with the bridge is a rubber magnetic layer, and the other surface of the marking tape is provided with bulged reflection angles, which are used as teeth to make one end of the marking tape be connected with the roller through the teeth, and to make the other end of the marking tape be connected with the scroll through the teeth. The marking tape is installed at the bottom of the beam of the long-span bridge, and a plurality of bulges formed by the reflection angles of the marking tape are used to provide more reflection surfaces for the laser, to reduce the reflection angle, to improve the reflection effect, and then to improve the efficiency and accuracy of a three-dimensional laser scanner.

A laser welding system for joining first and second thermoplastic workpieces, and including a clamp, an actuator, and a laser source. The clamp includes first and second clamping structures positioned together to engage opposite sides of the workpieces when they adjoin each other. The first clamping structure has a non-flat or irregular surface, facing the first workpiece. The actuator causes the clamping structures to press the first and second workpieces together. The laser source applies laser radiation having a wavelength of 2 microns toward the workpieces to be joined, while they are pressed together by the clamp, to melt irradiated portions of the workpieces to one another. The first clamping structure transmits substantially all of the energy of the laser radiation through the material. The first workpiece has a non-flat or irregular surface facing the first clamping structure, which substantially conforms with the surface of the first clamping structure.

An image forming system includes a sheet processing apparatus, a heat presser, an image forming apparatus, and control circuitry. The sheet processing apparatus separates a two-ply sheet in which two sheets are overlaid and bonded together at a portion of the two-ply sheet, and sandwiches a sheet medium between the sheets of the two-ply sheet. The heat presser heats and presses the two-ply sheet. The control circuitry performs a first mode to cause the sheet processing apparatus to sandwich the sheet medium, on which an image has been formed by the image forming apparatus, between the two sheets of the two-ply sheet and cause the heat presser to laminate the two-ply sheet, and a second mode to cause the heat presser to laminate a sheet set that includes the sheet medium sandwiched between the two sheets of the two-ply sheet by a user.

An image forming system includes a sheet processing apparatus, a heat presser, an image forming apparatus, and control circuitry. The sheet processing apparatus separates a two-ply sheet in which two sheets are overlaid and bonded together at a portion of the two-ply sheet, and sandwiches a sheet medium between the sheets of the two-ply sheet. The heat presser heats and presses the two-ply sheet. The control circuitry performs a first mode to cause the sheet processing apparatus to sandwich the sheet medium, on which an image has been formed by the image forming apparatus, between the two sheets of the two-ply sheet and cause the heat presser to laminate the two-ply sheet, and a second mode to cause the heat presser to laminate a sheet set that includes the sheet medium sandwiched between the two sheets of the two-ply sheet by a user.

A foil transfer device is configured to dispose a sheet on a foil film containing a foil and transfer the foil onto the sheet. The foil transfer device includes a heating member configured to heat the foil film and the sheet, a pressure member configured to nip the foil film and the sheet with the heating member, a first temperature sensor, and a controller. The controller determines whether the first temperature sensor has failed based on a voltage value of the first temperature sensor.

A foil transfer device is configured to dispose a sheet on a foil film containing a foil and transfer the foil onto the sheet. The foil transfer device includes a heating member configured to heat the foil film and the sheet, a pressure member configured to nip the foil film and the sheet with the heating member, a first temperature sensor, and a controller. The controller determines whether the first temperature sensor has failed based on a voltage value of the first temperature sensor.