The present disclosure provides a method of manufacturing a battery cell cover coupled to a battery cell, the method including: injecting an injection-molded product into a mold at a predetermined injection pressure (P.sub.M), discharging the gas or air within a cavity at a predetermined discharge pressure (P.sub.a) with a predetermined time difference while the injection-molded product is filled in the cavity within the mold; and curing the injection-molded product filled within the mold and separating a cured product in which the injection-molded product is cured.

An injection molding machine for foam molding includes: a heating cylinder; a screw disposed in the heating cylinder; and a plurality of inlet portions provided in the heating cylinder and configured to introduce inert gas. An inside of the heating cylinder includes a starvation section on an upstream side in which a pressure of the resin is decreased, and the inert gas from the plurality of inlet portions being to be supplied in the starvation section. Each of the plurality of inlet portions is provided with a check valve or an opening and closing mechanism. A product P×N of an interval P of the plurality of inlet portions and a number N of the inlet portions is 0.5H or more and 1.71H or less with respect to a length H of the starvation section.

A method for producing a foam-molded product uses a producing apparatus including a plasticizing cylinder. The plasticizing cylinder has a plasticization zone, a starvation zone, and an introducing port which is formed in the plasticizing cylinder and via which a physical foaming agent is introduced into the starvation zone. The method includes: plasticizing and melting a thermoplastic resin into a molten resin in the plasticization zone; introducing a pressurized fluid containing the physical foaming agent having a fixed pressure into the starvation zone; allowing the molten resin to be in the starved state in the starvation zone; bringing the molten resin in the starved state into contact with the pressurized fluid having the fixed pressure in the starvation zone; and molding the molten resin into the foam-molded product. At least one pressure boosting part is provided in the starvation zone.

A mold for encapsulating a Pin-Fin type power module with resin is disclosed. The power module includes a DBC or IMS, power chips and multiple terminals provided on a first surface of the DBC or IMS and a Pin-Fin structure provided on a second surface of the DBC or IMS. The mold further includes: a cavity for containing the power module; multiple terminal protecting elements corresponding to the terminals, respectively, each for receiving at least a part of a terminal; and an injection hole provided on the bottom of the mold or on the side wall of the mold, The first surface faces the bottom of the mold and the injection hole is below the first surface when the power module is placed in the cavity. A method for manufacturing a power module is also provided.

A plastic product having magnetic properties and a method for making the same is provided. The method comprises creating a mixture of a nylon and a metal, melting the mixture to create a melted mixture of the metal suspended in the nylon, injecting the melted mixture into a mold to harden the melted mixture and shape the melted mixture into the product's shape, applying an electrical current to the mold while the mixture is in a viscous state to align the poles of the metal suspended in the nylon in the mixture in a single direction before the mixture has hardened, and applying a magnetic field to the hardened mixture to provide the product with magnetic properties.

Anti-biofilm osseointegrating and/or tissue-integrating implantable biomaterial devices that optionally can elute therapeutic ions such as magnesium, silver, copper and/or zinc. In certain embodiments, the devices are engineered to produce structures suitable as implants having a relatively high surface population of zeolite. Methods of producing the devices are also disclosed.

Provided is a forming mold for a pressure container liner including a female serration on an upper face of a top portion. The forming mold includes an insert including a recessed-projecting portion by which the female serration is to be formed. The insert includes a lower layer and an upper layer divided from each other in the up-down direction. Bolt holes are formed in respective radial central parts of the upper layer and the lower layer. Gaps on contacting faces between the upper layer and the lower layer are set to a size that allows gas to pass through the gaps but does not allow nylon resin to pass through the gaps. An air-discharge passage via which a vicinal area of the recessed-projecting portion is connected to the bolt holes is formed on the contacting faces.

The present application belongs to the field of heat conducting materials technology, and in particular, to a preparation method of a heat conducting interface material. The present application discloses a preparation method of a heat-conducting interface material, which comprises: S1, stirring and mixing; S2. orientation process: putting a mixed material obtained in the step S1 into a hydraulic injection extruder, spitting the material out through a needle nozzle and arranging the material neatly in a container in a strip shape, and after stacking the material to ½-¼ of a height of the container, vibrating the material in a vibrating compactor and repeatedly performing stacking 2-4 times; S3, vacuum compaction; S4. curing; S5. slicing.

A mold for encapsulating a Pin-Fin type power module with resin is disclosed. The power module includes a DBC or IMS, power chips and multiple terminals provided on a first surface of the DBC or IMS and a Pin-Fin structure provided on a second surface of the DBC or IMS. The mold further includes: a cavity for containing the power module; multiple terminal protecting elements corresponding to the terminals, respectively, each for receiving at least a part of a terminal; and an injection hole provided on the bottom of the mold or on the side wall of the mold, The first surface faces the bottom of the mold and the injection hole is below the first surface when the power module is placed in the cavity. A method for manufacturing a power module is also provided.

The device for the suction of air in injection molds and the subsequent expulsion of molded pieces has a Venturi ejector connected to a first valve, that when the mold is closed causes the suction of air in a mold cavity, having at least one insert made from porous material through which and by means of a communication duct that defines a suction circuit, and a second valve, that after the solidification of the plastic material, causes the air to be blown towards the at least one insert made of porous material, cleaning the at least one insert made of porous material. The volume of air to be reduced in the second part of the injection cycle with the same empirical value of 90% efficiency of the Venturi ejector.