Abstract: A manufacturing method of a porous biomedical implant includes the steps of providing a supporter having a bearing surface, forming the porous biomedical implant on the bearing surface by additive manufacturing and removing the supporter after additive manufacturing. The porous biomedical implant includes a solid part and a porous part, the solid part is coupled to the bearing surface of the supporter and the porous part is coupled to the solid part. Particularly, the solid and porous parts are created in same layers by additive manufacturing.

Abstract: A method for manufacturing metal strip comprises abutting at least two metal strips to form a abutment interface between each other, then welding the metal strips along the abutment interface by a laser light to form a weld pass with a welding penetration depth between the metal strips, and a reflected light is reflected from the weld pass, and finally receiving the reflected light by a spectrometer which can determine the welding penetration depth according to the reflected light spectrum. A welding parameter can be selectively adjusted according to the welding penetration depth to correct the welding penetration depth in real time, and the follow-up weld pass can conform to the specification for decreasing weld defective ratio.

Abstract: A heat dissipating device is provided for reducing the high production costs of conventional heat dissipating devices. The heat dissipating device is mounted on a heat generating object and includes a heat conductive base having a plurality of insertion holes. At least one heat generating region is formed in a contact area between the heat conductive base and a heat source of the heat generating object. A plurality of heat dissipating columns is disposed in the at least one heat generating region and is respectively inserted into and positioned in the plurality of insertion holes. Each heat dissipating column includes a heat conductive silicone layer disposed on an outer periphery thereof.

Abstract: An acetabular cup structure of the present invention includes a ball-and-socket prosthesis and a liner, where a ball wall of the ball-and-socket prosthesis has a groove formed by connecting at least two continuous straight lines, and the groove connects an outer surface of the ball wall to an inner surface of the ball wall, so that an expandable sheet is formed between the groove formed by connecting the at least two continuous straight lines and having an angle there-between and two ends of the groove that are not connected, and the liner, for connecting a femoral stem, is tightly attached to the inner surface of the ball wall, and when the liner is tightly attached to the inner surface of the ball wall, the liner presses the sheet and extends to the groove, so that the liner is attached to the ball-and-socket prosthesis more tightly.

Abstract: The present invention provides a method for manufacturing a negative plate of a secondary battery, which includes the following steps: providing multiple sheets of functional graphene; compressing the functional graphene to form a graphene target; providing copper foil, and forming a microstructure on a surface of the copper foil, so as to strengthen attachment between a graphene layer and the copper foil; depositing the graphene target on the microstructure of the surface of the copper foil, to form the graphene layer; and repairing the graphene layer by using an excimer laser. The foregoing manufacturing method can greatly prolong a cycle life of the whole graphene cathode, and increase a reversible capacitance of a battery.

Abstract: The present invention relates to a manufacturing method for advanced high-strength steel (AHSS) wheel, comprising the following steps. Take an AHSS with at least 590 MPa of tensile strength for rolling to circular ring of a rim. Apply low heat input welding, such as the cold metal transfer (CMT) welding or the gas tungsten arc welding/tungsten inert gas arc welding (GTAW/TIG), at the junction of the rim to form a hollow cylindrical rim. Then perform hole expanding and spinning/roll forming operations to the rim. Take another AHSS with at least 980 MPa of tensile strength for pressing and forming a disk. Apply low heat input welding, such as cold metal transfer (CMT) welding, to the rim and the disk to produce a wheel. According to the present invention, the welding quality of products can be improved significantly; the fatigue lifetime of wheels can be enhanced; and wheels are lightweight.

Abstract: A device having a rail and a block includes a rail and a block. The rail includes a body and a hollow inside, the hollow inside being located inside the body. The hollow inside of the rail is provided with a lightweight, shock absorption and sound absorption material, and the lightweight, shock absorption and sound absorption material is selected from a group consisting of foam metal material, polystyrene, asbestos, foam, plastic, and rubber. The block is adapted for sliding along the rail to finish a slide path.

Abstract: A method for modifying properties of graphene includes a graphene film provision step and a modification step. In the graphene film provision step, a graphene film is provided, and the graphene is formed on a substrate. In the modification step, the graphene film is placed in a vacuum environment and radiated by an electron beam to obtain a graphene material.

Abstract: The present invention relates to a manufacturing method for advanced high-strength steel (AHSS) wheel, comprising the following steps. Take an AHSS with at least 590 MPa of tensile strength for rolling to circular ring of a rim. Apply low heat input welding, such as the cold metal transfer (CMT) welding or the gas tungsten arc welding/tungsten inert gas arc welding (GTAW/TIG), at the junction of the rim to form a hollow cylindrical rim. Then perform hole expanding and spinning/roll forming operations to the rim. Take another AHSS with at least 980 MPa of tensile strength for pressing and forming a disk. Apply low heat input welding, such as cold metal transfer (CMT) welding, to the rim and the disk to produce a wheel. According to the present invention, the welding quality of products can be improved significantly; the fatigue lifetime of wheels can be enhanced; and wheels are lightweight.

Abstract: A device having a rail and a block includes a rail and a block. The rail includes a body and a hollow inside, the hollow inside being located inside the body. The hollow inside of the rail is provided with a lightweight, shock absorption and sound absorption material, and the lightweight, shock absorption and sound absorption material is selected from a group consisting of foam metal material, polystyrene, asbestos, foam, plastic, and rubber. The block is adapted for sliding along the rail to finish a slide path.