Methods and systems for vacuum forming to form a final plastic product defining a notch, including providing a plastic material; providing a mold for a preform plastic product from which to form the final plastic product having a sacrificial forming feature associated with forming an inline trimmable part defining a notch area from which to form the notch, the sacrificial forming feature positioned on the mold within the notch area to be trimmed via an inline trimming operation to form the notch and shaped to selectively reduce a material thickness at a selective remaining location of the preform plastic product; disposing the plastic material on the mold to form an assembly; applying vacuum forming to the assembly to form the preform plastic product; and reducing the material thickness at the selective remaining location of the preform plastic product during vacuum forming to affect a corresponding localized stiffness reduction.

A method of forming a vacuum insulated structure includes providing a structural envelope an insulating cavity defined within the structural envelope. An expanding device is attached to opposing outer walls of the structural envelope and the interior cavity is expanded by pulling the opposing outer walls away from one another to define an expanded state. An insulating material is disposed within the insulating cavity to occupy substantially all of the insulating cavity in the expanded state. Gas is expressed from the insulating cavity to collapse the structural envelope to a final state and a final interior volume that is less than the expanded interior volume. The final state of the structural envelope defines a densified state of the insulating material within the insulating cavity. The vacuum port is then closed to hermetically seal the insulating cavity.

A method of forming a vacuum insulated structure includes providing a structural envelope an insulating cavity defined within the structural envelope. An expanding device is attached to opposing outer walls of the structural envelope and the interior cavity is expanded by pulling the opposing outer walls away from one another to define an expanded state. An insulating material is disposed within the insulating cavity to occupy substantially all of the insulating cavity in the expanded state. Gas is expressed from the insulating cavity to collapse the structural envelope to a final state and a final interior volume that is less than the expanded interior volume. The final state of the structural envelope defines a densified state of the insulating material within the insulating cavity. The vacuum port is then closed to hermetically seal the insulating cavity.

A method of manufacturing a fuel tank includes: passing a hollow molten resin projection, that projects-out in a wall-thickness direction and is formed at a molten resin sheet that becomes a tank structural member structuring a tank main body, through a mounting hole of a part-to-be-mounted that is placed on the molten resin sheet; and pressurizing the molten resin projection from an inner side, and causing at least a portion of the molten resin projection to jut-out to a peripheral portion of the mounting hole of the part-to-be-mounted.

A sealing plate for use with a packaging machine that integrates a seal formed indicia into a portion of a package seal. A package having a seal formed indicia integrated into the package seal, which when the package is opened undergoes undergo a visual transformation, and a method of making the same.

A receptacle stabilizer for stabilizing a receptacle may include a cover portion defining a cavity and at least one weight portion disposed within the cavity of the cover portion. The cover portion may include a top wall, a plurality of sidewalls extending downward from the top wall, and a lip portion extending outward from the plurality of sidewalls. The cavity may be defined between the top wall and the plurality of side walls. A method of forming a receptacle stabilizer may include heating a material to be formed into a cover portion of the receptacle stabilizer, placing the heated material over a mold, vacuum forming the heated material into the mold and forming the cover portion, and disposing at least one weight portion into a cavity of the cover portion.

A receptacle stabilizer for stabilizing a receptacle may include a cover portion defining a cavity and at least one weight portion disposed within the cavity of the cover portion. The cover portion may include a top wall, a plurality of sidewalls extending downward from the top wall, and a lip portion extending outward from the plurality of sidewalls. The cavity may be defined between the top wall and the plurality of side walls. A method of forming a receptacle stabilizer may include heating a material to be formed into a cover portion of the receptacle stabilizer, placing the heated material over a mold, vacuum forming the heated material into the mold and forming the cover portion, and disposing at least one weight portion into a cavity of the cover portion.

The invention relates to a process for making a medical component such as a medical implant for example a graft or stent-graft, said medical component comprising ultra high molecular weight polyethylene (UHMWPE) fibers, a medical component obtainable by said process as well as uses of said process and medical component.

The invention relates to a process for making a medical component such as a medical implant for example a graft or stent-graft, said medical component comprising ultra high molecular weight polyethylene (UHMWPE) fibers, a medical component obtainable by said process as well as uses of said process and medical component.

Embodiments of the present disclosure provide a refrigerator dispenser lever and a method for manufacturing the same. The lever is capable of reducing post-process activity required to assemble the components, enhancing a sense of unity between components and improving the quality and appearance of the lever by combining individual components during manufacturing using a single injection molding process.