A method for manufacturing an integrated multilayer structure for sensing applications, including obtaining at least one film including a sensing area; arranging the at least one film with reactance sensing electronics for sensing of one or more selected target quantities or qualities and conversion thereof into representative electrical signals, said sensing electronics including at least one sensing element and an electrical connection configured to connect the sensing element to an associated control circuitry; and molding or casting, and configuring, at least one plastic layer so that the plastic layer defines an integrated, intermediate layer between the sensing electronics and the sensing area and that the sensing area is superimposed with the sensing element of the sensing electronics, wherein it is further provided at least one physical feature to locally reduce the electrical distance between the sensing area and the sensing element to improve the associated sensing sensitivity.

A reusable surgical implement is provided that is formed of a core positioned within an enclosure. The core is formed of a suitable rigid, and optionally flexible material to enable the implant to conform to the desired use for the implement in a surgical procedure. The material forming the enclosure is also stretchable and flexible to accommodate the configuration and/or any flexing of the core, and is biologically inert to enable the implant to be sterilized after use for use in subsequent surgical procedures while protecting the material forming the core. The enclosure can be molded around the core in separate portions or components using multiple molding steps to form an enclosure with the desired attributes.

Provided is a coating composition suitable for in-mold coating and suitable particularly for a coating material for exterior applications. A two-pack coating composition comprising a main resin and a curing agent, wherein the main resin comprises a polyol, a curing catalyst, and a light stabilizer; the curing agent comprises an isocyanurate compound; a hydroxyl value of the polyol is 300 mg KOH/g or more and 1000 mg KOH/g or less; an average number of hydroxy groups of the polyol is 3 or more; a content of the curing catalyst is 0.25 parts by mass or more and 10 parts by mass or less based on 100 parts by mass of the polyol; the light stabilizer comprises a hindered amine-based compound; a common logarithm pKb of a base dissociation constant of the hindered amine-based compound is 6.5 or more and 14 or less; and a content of a solvent is 30% by mass or less.

A method produces plastic/metal hybrid components, in particular for the automotive field. A plastic compound is injected into a tool mold, and the tool mold has a core onto which a metal is injected. The plastic compound is then injected into the tool mold such that the metal is back-molded with the plastic compound and is fixed to the plastic in order to produce a blank. The tool mold is used to produce at least one depression in the surface of the blank, the depression being at least partly filled with a metal as part of a first additional processing.

A molded article includes a first plateable region spaced apart from a second plateable region the first plateable region by a barrier of electrically insulating material. Each of the plateable regions include an associated plateable layer of electrically conductive material for being electroplated with a different plateable finish. Several different geometries and configurations of the barrier and/or the plateable regions are provided to prevent migration of plating material from one of the plateable regions acting as bipolar electrode while another one of the plateable regions is being electroplated. A non-plateable insert may be disposed between the plateable regions to prevent migration of plating material from one of the plateable regions onto the other one of the plateable regions. A conducive robber in electrical communication with one of the one of the plateable regions, and which may be removable, may also be used to prevent migration of plating material.

The present invention is a container having a label that is embedded in the container and a method of temporarily marking the container over the label. The container is sufficiently transparent to allow indicia formed on the label to be ascertained through a wall of the container. The exterior wall of the container may be written upon with a marker that leaves marks that are erasable from the exterior of the container. A method of producing the container is described.

A reusable surgical implement is provided that is formed of a core positioned within an enclosure. The core is formed of a suitable rigid, and optionally flexible material to enable the implant to conform to the desired use for the implement in a surgical procedure. The material forming the enclosure is also stretchable and flexible to accommodate the configuration and/or any flexing of the core, and is biologically inert to enable the implant to be sterilized after use for use in subsequent surgical procedures while protecting the material forming the core. The enclosure can be molded around the core in separate portions or components using multiple molding steps to form an enclosure with the desired attributes.

A method for manufacturing an integrated multilayer structure for sensing applications, including obtaining at least one film including a sensing area; arranging the at least one film with reactance sensing electronics for sensing of one or more selected target quantities or qualities and conversion thereof into representative electrical signals, said sensing electronics including at least one sensing element and an electrical connection configured to connect the sensing element to an associated control circuitry; and molding or casting, and configuring, at least one plastic layer so that the plastic layer defines an integrated, intermediate layer between the sensing electronics and the sensing area and that the sensing area is superimposed with the sensing element of the sensing electronics, wherein it is further provided at least one physical feature to locally reduce the electrical distance between the sensing area and the sensing element to improve the associated sensing sensitivity.

An integrated multilayer structure for use in sensing applications and a method of manufacture are presented. The multilayer structure includes at least one molded or cast plastic layer and a film layer on both first and second sides of said plastic layer. The film layer on the first side of said plastic layer is provided with reactance sensing electronics. The sensing electronics includes at least one sensing element and an electrical connection for connecting the sensing element to an associated control circuitry. The film layer on the second side of the plastic layer has a sensing area superimposed with the sensing element of the sensing electronics. The electrical distance between the film layer on the second side of the plastic layer and the sensing element are locally reduced by a physical feature at the position of the sensing area of the film layer to improve the associated sensing sensitivity.

The present invention is a container having a label that is embedded in the container and a method of temporarily marking the container over the label. The container is sufficiently transparent to allow indicia formed on the label to be ascertained through a wall of the container. The exterior wall of the container may be written upon with a marker that leaves marks that are erasable from the exterior of the container. A method of producing the container is described.