A method produces an injection molded part. A plastic material is injected into a cavity for forming the injection molded part. The plastic material in a flow line region of the cavity, where the plastic material from two directions coincides during an injection molding process, is at least partially removed from the cavity via at least two overflow points and, in so doing, is locally swirled or mixed between the overflow points.

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.

An injection molding method uses a die with a cavity into which molten resin is to be injected to fill the cavity. The die has a shape that causes the molten resin injected into the cavity to branch and merge. The injection molding method includes providing bubbles into the molten resin before the molten resin is injected, generating fine bubbles with the provided bubbles before the molten resin is injected, injecting the molten resin containing the fine bubbles, and bursting the fine bubbles of the injected molten resin containing the fine bubbles in a merging location where the molten resin merges.

In an injection foam molding method, a relationship between a flow front moving speed (cm/s) of a foamed resin material in an injection step of injecting the foamed resin material into a cavity and amount of gas generated per 1 g of a resin material (ml/g) is defined as follows: the amount of gas generated per 1 g of the resin material is 0.36 ml/g or more; and the flow front moving speed (cm/s) is 75×the amount of gas generated per 1 g of the resin material (ml/g)−35 or more and 12 cm/s or more.

In an injection foam molding method, a relationship between a flow front moving speed (cm/s) of a foamed resin material in an injection step of injecting the foamed resin material into a cavity and amount of gas generated per 1 g of a resin material (ml/g) is defined as follows: the amount of gas generated per 1 g of the resin material is 0.36 ml/g or more; and the flow front moving speed (cm/s) is 75the amount of gas generated per 1 g of the resin material (ml/g)35 or more and 12 cm/s or more.

Injection molded container article including a center portion having an outer perimeter. The center portion has a central flow leader defined therein, the central flow leader having a central flow leader thickness. A side wall portion extends from the outer perimeter to an outer rim portion. The center portion and the side wall portion together define a container space having a volume. The side wall portion includes a plurality of side wall flow leaders and a plurality of side wall panels extending between adjacent flow leaders and having side wall panel thickness less than the central flow leader thickness. Each side wall flow leader has a side wall flow leader thickness greater than the side wall panel thickness, and each flow leader extends between the central flow leader and the outer rim portion. Method of making the injection molded container article also provided.

An injection molding method uses a die with a cavity into which molten resin is to be injected to fill the cavity. The die has a shape that causes the molten resin injected into the cavity to branch and merge. The injection molding method includes providing bubbles into the molten resin before the molten resin is injected, generating fine bubbles with the provided bubbles before the molten resin is injected, injecting the molten resin containing the fine bubbles, and bursting the fine bubbles of the injected molten resin containing the fine bubbles in a merging location where the molten resin merges.

Described is an injection molding apparatus including a mold body having an inner surface defining a main cavity to contain primary molten polymeric material, a tank in fluid communication with the main cavity which contains auxiliary molten polymeric material, a pressurized vas injector in communication with the tank to inject the pressurized gas into the tank to displace part of the auxiliary molten polymeric material from the tank into the main cavity to prevent entry of the pressurized gas into the main cavity. The invention also relates to an injection molding plant for making an article and to an injection molding method for making an article. The apparatus, the plant and method for the injection molding of polymeric material according to the invention improve the mechanical properties and the aesthetic characteristics of an article to be made at or near the melt lines of the article.

A method produces an injection molded part. A plastic material is injected into a cavity for forming the injection molded part. The plastic material in a flow line region of the cavity, where the plastic material from two directions coincides during an injection molding process, is at least partially removed from the cavity via at least two overflow points and, in so doing, is locally swirled or mixed between the overflow points.

A cover anchor clip includes a base section having a plate shape extending in one direction, that is formed with through holes into which a foam body enters, and that is configured to be retained in the foam body; and an anchor portion including a pair of extension portions that extend upward from a surface of the base section and that are disposed facing each other, and a pair of anchor claws that are formed at respective leading ends of the pair of extension portions, and that is configured to anchor an anchored member attached to a cover for covering the foam body by sandwiching the anchored member therebetween. The through holes formed at the base section are aligned in the one direction, and plural hole-rows formed by the through holes aligned in the one direction are disposed separated by a spacing in an intersection direction intersecting the one direction. A gate mark that indicates an injection port for resin material during molding is formed at the back face of the base section between adjacent hole-rows. A plate thickness changing portion at which a thickness of the base section changes is formed between the gate mark and the through holes, as viewed from a back face of the base section along a plate thickness direction of the base section.