A first connector, that is a first connector that mates with a second connector, containing: a first connector main body; a first terminal attached to the first connector main body; a first high-frequency terminal attached to the first connector main body; and a first shield surrounding an entire circumference of the first connector main body; wherein the first shield contains an oblique part that extends obliquely downward, formed on an inner edge at the upper end, and also contains a plurality of linear parts and a plurality of curved parts; the first connector main body being integrally connected at the curved parts, and the first connector main body being separated at the linear parts.

A first connector, that is a first connector that mates with a second connector, containing: a first connector main body; a first terminal attached to the first connector main body; a first high-frequency terminal attached to the first connector main body; and a first shield surrounding an entire circumference of the first connector main body; wherein the first shield contains an oblique part that extends obliquely downward, formed on an inner edge at the upper end, and also contains a plurality of linear parts and a plurality of curved parts; the first connector main body being integrally connected at the curved parts, and the first connector main body being separated at the linear parts.

A high-speed circuit assembly includes a high-speed circuit including at least one waveguide/transmission line, and a radiation absorbing material disposed in contact with or in close proximity with the waveguide/transmission line.

A high-speed circuit assembly includes a high-speed circuit including at least one waveguide/transmission line, and a radiation absorbing material disposed in contact with or in close proximity with the waveguide/transmission line.

An upper cover of a cover body of a high-frequency high-speed transmission cable module is provided, including a main body and a heat dissipation block. Two ends in the length direction of the main body are respectively defined as a first end and a second end, and the first end is provided with a through hole. The heat dissipation block is embedded in the through hole and exposed on the top surface of the first end. As such, the present invention can use the heat dissipation block to directly transfer heat to the heat dissipation fins without indirectly passing through the main body, so the heat dissipation efficiency is greatly improved.

An upper cover of a cover body of a high-frequency high-speed transmission cable module is provided, including a main body and a heat dissipation block. Two ends in the length direction of the main body are respectively defined as a first end and a second end, and the first end is provided with a through hole. The heat dissipation block is embedded in the through hole and exposed on the top surface of the first end. As such, the present invention can use the heat dissipation block to directly transfer heat to the heat dissipation fins without indirectly passing through the main body, so the heat dissipation efficiency is greatly improved.

The present invention relates to an electrical connector including a first connector housing with a wall arranged substantially perpendicular to the connecting axis. The wall has an opening for insertion of a second connector housing. A first collar extends from the wall concentrically around the opening. A second collar extends from the wall concentrically around the first collar. The first collar and the second collar are spaced apart. A sleeve-shaped coding element is attached with a first end to the free end of the first collar. The first collar and the sleeve-shaped coding element are arranged concentrically around the opening. A sealing element is arranged in a sealing area between the first collar and the second collar. The sleeve-shaped coding element includes a supporting feature at its first end which is suitable for holding the sealing element in its position.

The present invention relates to an electrical connector including a first connector housing with a wall arranged substantially perpendicular to the connecting axis. The wall has an opening for insertion of a second connector housing. A first collar extends from the wall concentrically around the opening. A second collar extends from the wall concentrically around the first collar. The first collar and the second collar are spaced apart. A sleeve-shaped coding element is attached with a first end to the free end of the first collar. The first collar and the sleeve-shaped coding element are arranged concentrically around the opening. A sealing element is arranged in a sealing area between the first collar and the second collar. The sleeve-shaped coding element includes a supporting feature at its first end which is suitable for holding the sealing element in its position.

A luminaire (10) is disclosed with built-in surge protection. The luminaire comprises an electrically conductive structure including a carrier (11) carrying at least one active circuit component (15, 16) and a shielding element (13) at least partially covering the carrier inside a housing, a set of active conductors (17, 19) connected to the active circuit component for connecting the active circuit component to a mains supply including a neutral (N) and live (L) terminal, wherein one of said terminals is further connected to the shielding element by a connection (19′) bypassing the at least one active circuit. The housing comprises a cover (21) over the electrically conductive structure, wherein the shielding element defines a clearance (25) between the electrically conductive structure and the cover, said clearance comprising a pinch point (27) between the shielding element and the cover.

A luminaire (10) is disclosed with built-in surge protection. The luminaire comprises an electrically conductive structure including a carrier (11) carrying at least one active circuit component (15, 16) and a shielding element (13) at least partially covering the carrier inside a housing, a set of active conductors (17, 19) connected to the active circuit component for connecting the active circuit component to a mains supply including a neutral (N) and live (L) terminal, wherein one of said terminals is further connected to the shielding element by a connection (19′) bypassing the at least one active circuit. The housing comprises a cover (21) over the electrically conductive structure, wherein the shielding element defines a clearance (25) between the electrically conductive structure and the cover, said clearance comprising a pinch point (27) between the shielding element and the cover.