A seal printing system including a three-dimensional printer and a seal blank is described. The seal blank has a non-functioning structure. The non-functioning structure includes a first completed end and an uncompleted end incapable of interlocking with each other. The printer is configured to receive the seal blank having the non-functioning structure. The printer is configured to print a second completed end of the seal blank. The second completed end is connected to the uncompleted end such that the first and second completed ends are capable of interlocking.

An apparatus, comprising an Integrated Circuit (IC) package comprising a dielectric, the IC package has a first surface and an opposing second-surface, wherein the first surface is separated from the second surface by a thickness of the IC package, wherein sidewalls extend along a perimeter and through the thickness between the first surface and the second surface, and a structure comprising a frame that extends at least partially along the perimeter of the IC package, wherein the structure extends at least through the thickness of the IC package and inwardly from the sidewalls of the IC package.

An apparatus, comprising an Integrated Circuit (IC) package comprising a dielectric, the IC package has a first surface and an opposing second-surface, wherein the first surface is separated from the second surface by a thickness of the IC package, wherein sidewalls extend along a perimeter and through the thickness between the first surface and the second surface, and a structure comprising a frame that extends at least partially along the perimeter of the IC package, wherein the structure extends at least through the thickness of the IC package and inwardly from the sidewalls of the IC package.

The invention relates to an anchoring element for a dental prosthetic arrangement, which anchoring element can be anchored in a jaw bone or implant in a first subregion (TB1) and is suitable for receiving or forming a dental prosthetic element (ZK) in a second subregion (TB2), wherein the anchoring element has, between the first subregion (TB1) and the second subregion (TB2), a radially projecting collar (KR) which at least partially encloses the circumference of the anchoring element, such that the region above the collar (KR) of the anchoring element is at least in part fully covered with a thermoplastic material. The invention further relates to a method for producing an abutment or implant, and to a method for producing a dental prosthetic arrangement using the abutment.

Various components and methods related to a leading edge assembly are disclosed. The leading edge assembly can include an outer strike shell and a foam core. The foam core can be located inside the outer strike shell. The leading edge assembly can include a heating element with a plurality of sensors and wires. A method of manufacturing a leading edge assembly can include forming a composite layer, applying a metallic layer to the composite layer, installing an electronic device, and inserting a foam core into a cavity bounded by the composite layer and/or the electronic device.

The present invention concerns a method for the production of a moulded body containing at least one volume hologram by means of injection moulding, comprising the following method steps: provision of a hologram film composite having two sides comprising at least one photopolymer layer with at least one volume hologram, a shear protective layer and a substrate layer, and optionally, further composite film layers, insertion of the hologram film composite into a metallic injection mould, such that one side of the hologram film composite is at least partially in contact with the injection mould wall, introduction of a molten thermoplastic polymer for the production of the moulded body, wherein at least the outermost layer of the hologram film composite on the side of the hologram film composite coming into contact with the molten polymer contains essentially the same polymer raw materials as the molten thermoplastic polymer, and extrusion coating of the hologram film composite with the molten thermoplastic polymer, and solidification of the molten thermoplastic polymer.

The invention also concerns a moulded body produced in this manner and advantageous applications of this moulded body.

A molding method for a composite material by disposing a reinforcing base material within a cavity of an openable/closable molding die, injecting resin into the cavity and curing the resin. In particular support member is caused to penetrate a reinforcing base material and is disposed such that at least one end portion of the support member projects from the reinforcing base material. Next, the reinforcing base material and the support member are disposed within a cavity of a molding die, the molding die is closed, at least one end portion of the support member is brought into contact with wall surfaces of the molding die that form the cavity. Finally, resin is injected into the cavity from an injection port of the molding die while a state in which the at least one end portion is brought into contact with the wall surface is maintained.

A molding method for a composite material by disposing a reinforcing base material within a cavity of an openable/closable molding die, injecting resin into the cavity and curing the resin. In particular support member is caused to penetrate a reinforcing base material and is disposed such that at least one end portion of the support member projects from the reinforcing base material. Next, the reinforcing base material and the support member are disposed within a cavity of a molding die, the molding die is closed, at least one end portion of the support member is brought into contact with wall surfaces of the molding die that form the cavity. Finally, resin is injected into the cavity from an injection port of the molding die while a state in which the at least one end portion is brought into contact with the wall surface is maintained.

A method of producing a fiber-reinforced plastic includes disposing a transparent film as an outermost layer on a lower die of a molding die, disposing a base sheet formed of a fiber fabric on the transparent film, closing the molding die with an upper die, and injecting a matrix resin into the molding die closed. The transparent film has grooves on a surface facing the base sheet. In the disposing, the base sheet is disposed such that the grooves are located between adjacent weaving gaps of the base sheet.

An engine block assembly includes a head structure assembly, and a cylinder structure assembly. A plurality of fasteners interconnect the head structure assembly and the cylinder structure assembly. An outer shell encapsulates and supports both the head structure assembly and the cylinder structure assembly. The outer shell is a unitary polymer structure that is simultaneously over-molded onto the head structure assembly and the cylinder structure assembly. The head structure assembly and the cylinder structure assembly are constructed of components that are designed to carry the operational loads of the engine with minimal weight. The outer shell provides additional structural integrity, and provides fluid passages for lubrication and cooling, as well as support for other engine components.