The outer layer is peeled exactly a predetermined length from the end portion of the electromagnetic shielding tube. That is, the metal layer is exposed exactly a predetermined range at the end portion of the electromagnetic shielding tube. A flexible conductor is connected to the exposed metal layer. A separated portion is provided in the inner layer. The separated portion is formed along the length direction of the electromagnetic shielding tube. Additionally, a depth of the separated portion is the same value as the thickness of the inner layer. As such, the inner surface of the metal layer is exposed at the separated portion. It is preferable that the separated portion be formed at a plurality of locations in the circumferential direction. The inner layer is divided into a plurality of sections in the circumferential direction by the separated portion. The separated portion is a terminal processed portion, which mitigates the effects caused by differences in the physical properties of the inner layer and the metal layer.

A housing unit for an electronic component, in particular for an inverter of an electrical refrigerant compressor, wherein the housing unit includes a first housing element and a second housing element, which can be connected to a housing part of the refrigerant compressor, in particular to a motor housing of the refrigerant compressor, and in the process form a cavity which accommodates the electronic component, in particular the inverter.

A display assembly for an imaging device including a display panel, a display, a first control unit, a second control unit and a thermally insulating layer, and a housing. The thermally insulating layer divides the housing in at least a first cavity including the first control unit and a second cavity including the second control unit. The thermally insulating layer preventing heat generated in the first cavity or the second cavity from reaching the other cavity and including an electrically conductive material to at least partially shield electromagnetic radiation generated in the first or the second cavity from reaching the other cavity.

A method for producing a housing having shielding against electric and/or magnetic radiation is provided, in which an electrically and/or magnetically conductive foil is formed into a shape corresponding to and inner or an outer wall of a housing made of an electrically and/or magnetically non-conductive material, and the foil is arranged on the inner or outer wall of the housing. The foil shape may be formed separate from the foils application to the inner or outer wall of the housing, or may be shaped in conjunction with the forming of the non-conductive housing.

A housing and a method for manufacturing a housing are disclosed. In an embodiment a housing for an electric component includes a first housing part and a second housing part, wherein the first housing part and the second housing part are connected in a joining region, wherein the joining region is completely or partially covered by a metallic coating on an outside, wherein the first housing part is joined to the second housing part by a connecting agent, wherein the connecting agent is an adhesive or a solder material, wherein the metallic coating covers the first housing part only at an upper side of the first housing part accessible from the outside when the housing parts are joined by the connecting agent, and wherein the metallic coating extends laterally beyond the first housing part and at least partially covers the second housing part.

A personal communication device (PCD) holder includes: (i) a male housing component including a capped end and a first tubular wall extending from the capped end to a male mating end, the male housing component data signal blocking; (ii) a female housing component including a capped end and a second tubular wall extending from the capped end to a female mating end, the female housing component data signal blocking; (iii) a first liner material conforming to an inner surface of the male housing component; (iv) a second liner material conforming to an inner surface of the female housing component; and (v) a data signal blocking gasket positioned to reside between an exposed outer surface of the data signal blocking material of the male mating end and the exposed inner surface of the data signal blocking material of the female mating end.

A circuit module 2 comprises: a wiring structure 4; at least one electronic component 6a, 6b arranged on the upper surface of the wiring structure 4; an insulating resin layer 8 which is provided on the upper surface of the wiring structure 4 and in which at least one electronic component 6a, 6b is embedded; and a metal layer 10 provided on the upper surface of the insulating resin layer 8. The surface roughness of the portion 51 directly above each electronic component on the upper surface of the insulating resin layer 8 is expressed as R1. The surface roughness of the portion S2 other than the portion directly above all the electronic components on the upper surface of the insulating resin layer 8 is expressed as R2. At least one R1 satisfies the condition: R1>R2.

An electromagnetic wave shielding sheet according to the present embodiments is an electromagnetic wave shielding sheet for forming an electromagnetic wave shielding layer used for a component-mounting substrate including a substrate, an electronic component and an electromagnetic wave shielding layer, in which the electromagnetic wave shielding sheet includes at least one of a conductive layer before thermal pressing of the electromagnetic wave reflection layer and a conductive layer before thermal pressing of the electromagnetic wave absorption layer, the conductive layer before thermal pressing of the electromagnetic wave reflection layer includes a binder resin and a conductive filler, and the conductive layer before thermal pressing of the electromagnetic wave absorption layer includes a binder resin and an electromagnetic wave absorption filler. The Young's modulus of the conductive layer at 23? C. is set to 10 to 700 MPa.

Disclosed are exemplary embodiments of thermal management and/or electromagnetic interference (EMI) mitigation materials including coated fillers (e.g., coated thermally-conductive, electrically-conductive, dielectric absorbing, and/or electromagnetic wave absorbing particles, sand particles coated with a binder, other coated functional fillers, combinations thereof, etc.). For example, a thermal management and/or EMI mitigation material may comprise a thermal interface material (TIM) including one or more coated fillers (e.g., coated thermally-conductive particles, sand particles coated with a binder, etc.), whereby the TIM is suitable for providing a thermal management solution for one or more batteries and/or battery packs (e.g., a battery pack for electric vehicle, etc.), or other device(s), etc.

The outer layer is peeled exactly a predetermined length from the end portion of the electromagnetic shielding tube. That is, the metal layer is exposed exactly a predetermined range at the end portion of the electromagnetic shielding tube. A flexible conductor is connected to the exposed metal layer. A separated portion is provided in the inner layer. The separated portion is formed along the length direction of the electromagnetic shielding tube. Additionally, a depth of the separated portion is the same value as the thickness of the inner layer. As such, the inner surface of the metal layer is exposed at the separated portion. It is preferable that the separated portion be formed at a plurality of locations in the circumferential direction. The inner layer is divided into a plurality of sections in the circumferential direction by the separated portion. The separated portion is a terminal processed portion, which mitigates the effects caused by differences in the physical properties of the inner layer and the metal layer.