Some embodiments include a construction having a horizontally-extending layer of fluorocarbon material over a semiconductor construction. Some embodiments include methods of filling openings that extend into a semiconductor construction. The methods may include, for example, printing the material into the openings or pressing the material into the openings. The construction may be treated so that surfaces within the openings adhere the material provided within the openings while surfaces external of the openings do not adhere the material. In some embodiments, the surfaces external of the openings are treated to reduce adhesion of the material.

Some embodiments include a construction having a horizontally-extending layer of fluorocarbon material over a semiconductor construction. Some embodiments include methods of filling openings that extend into a semiconductor construction. The methods may include, for example, printing the material into the openings or pressing the material into the openings. The construction may be treated so that surfaces within the openings adhere the material provided within the openings while surfaces external of the openings do not adhere the material. In some embodiments, the surfaces external of the openings are treated to reduce adhesion of the material.

A fixture, system, and method for coating a glove with a coating material are described. A fixture includes a support member and a clamping member movable relative to the support member to a closed position. The clamping member is configured to be at least partially received in a cuff of the glove. In the closed position, the cuff is captured between the clamping member and the support member. In this configuration, a majority of an external surface of the glove is exposed for being coated. A glove-coating system can include one or more fixtures on a conveyor that move the fixture around various processing stages of the glove-coating system. In certain methods of coating a glove, coating material is applied to the glove while the glove is suspended from the fixture. The coated glove can be removed from the fixture without being everted.

A fixture, system, and method for coating a glove with a coating material are described. A fixture includes a support member and a clamping member movable relative to the support member to a closed position. The clamping member is configured to be at least partially received in a cuff of the glove. In the closed position, the cuff is captured between the clamping member and the support member. In this configuration, a majority of an external surface of the glove is exposed for being coated. A glove-coating system can include one or more fixtures on a conveyor that move the fixture around various processing stages of the glove-coating system. In certain methods of coating a glove, coating material is applied to the glove while the glove is suspended from the fixture. The coated glove can be removed from the fixture without being everted.

The present invention is a unique process of manufacturing rigid members with precise shape keeping properties and with reflective properties pertaining to radio frequency energy, so that air, land, sea and space devices or vehicles may be constructed including parabolic reflectors formed without discrete permanent layering. Rather, such parabolic reflectors or similarly, vehicles, may be formed by homogeneous construction where discrete layering is absent, and where energy reflectivity or scattering characteristics are embedded within the homogeneous mixture of carbon nanotubes and associated graphite powders and epoxy, resins and hardeners. The mixture of carbon graphite nanofiber and carbon nanotubes generates higher electrode conductivity and magnetized attraction through molecular polarization. In effect, the rigid members may be tuned based on the application. The combination of these materials creates a unique matrix that is then set in a memory form at a specific temperature, and then applied to various materials through a series of multiple layers, resulting in unparalleled strength and durability.

A door panel manufacturing process is provided by constructing a high load conveyor line capable of controlling speed and duration, subsequently placing a finished door panel mold on the high load conveyor line. The conveyor line can be used to control a shifting speed and duration, and a de-molding agent can be sprayed inside the door panel mold, followed by spraying a high-density foam resin to form a shell. The door panel mold further has a framework or a reinforcement member mounted therein, and a low-density foam resin is injected; after the foam resin is formed and cooled, the door panel made of foam resin is completed. The process solve issues of high defective rate and insufficient surface strength associated with the conventional foam door panel, and is capable of significantly reducing the electricity required as well as reducing logging of woods, thereby realizing environmental protection.

A door panel manufacturing process is provided by constructing a high load conveyor line capable of controlling speed and duration, subsequently placing a finished door panel mold on the high load conveyor line. The conveyor line can be used to control a shifting speed and duration, and a de-molding agent can be sprayed inside the door panel mold, followed by spraying a high-density foam resin to form a shell. The door panel mold further has a framework or a reinforcement member mounted therein, and a low-density foam resin is injected; after the foam resin is formed and cooled, the door panel made of foam resin is completed. The process solve issues of high defective rate and insufficient surface strength associated with the conventional foam door panel, and is capable of significantly reducing the electricity required as well as reducing logging of woods, thereby realizing environmental protection.

A method for manufacturing a composite structure. The method includes depositing a plurality of thermoplastic particles onto at least one of a surface of a filler member and a surface of a structural member. The method further includes assembling the filler member with the structural member such that the plurality of thermoplastic particles are disposed proximate an interface between the filler member and the structural member.

Simulated anatomical components, such as simulated vascular vessels, produced by a method that includes forming an anatomical component mold from a soluble polymer such that the mold defines an interior void of the simulated anatomical component. One or more layers of an elastomeric material is applied around the anatomical component mold and the material is allowed to cure to form a wall of the simulated anatomical component. At least a portion of the mold is dissolved to form a passage for liquid within the simulated anatomical component. Simulated anatomical components are connectable to other components of a surgical simulation system and can be modularized.

Simulated anatomical components, such as simulated vascular vessels, produced by a method that includes forming an anatomical component mold from a soluble polymer such that the mold defines an interior void of the simulated anatomical component. One or more layers of an elastomeric material is applied around the anatomical component mold and the material is allowed to cure to form a wall of the simulated anatomical component. At least a portion of the mold is dissolved to form a passage for liquid within the simulated anatomical component. Simulated anatomical components are connectable to other components of a surgical simulation system and can be modularized.