A retention apparatus for a shielded cable is described. In one embodiment, the apparatus comprises a substrate having a ground; a connector coupled to the substrate; a cable shielded with a conductive material and having an end connectable to the connector to electrically connect with the connector; an electrically conductive material coupled to the ground of the substrate; and a grounding retention mechanism to cause the electrically conductive material to electrically connect the cable to the ground of the substrate by applying a force to the cable shield.

A high-voltage connector assembly and a motor-operated compressor including the same are disclosed. The high-voltage connector assembly according to embodiments disclosed herein may include a cover defining an outer appearance and a shielding plate designed to shield an electrical noise signal. The cover and the shielding plate may be integrally formed by a double shot molding or insert injection molding. Accordingly, manufacturing time and costs of the cover and the shielding plate may be reduced. In addition, the cover and the shielding plate may be coupled to each other in a more stable manner. Further an outer circumferential portion of the shielding plate may have a higher roughness than the cover. Alternatively, the outer circumferential portion of the shielding plate may be provided with a plate protrusion or an uneven portion. Accordingly, a contact area between the shielding plate and the cover may be increased.

A high-voltage connector assembly and a motor-operated compressor including the same are disclosed. The high-voltage connector assembly according to embodiments disclosed herein may include a cover defining an outer appearance and a shielding plate designed to shield an electrical noise signal. The cover and the shielding plate may be integrally formed by a double shot molding or insert injection molding. Accordingly, manufacturing time and costs of the cover and the shielding plate may be reduced. In addition, the cover and the shielding plate may be coupled to each other in a more stable manner. Further an outer circumferential portion of the shielding plate may have a higher roughness than the cover. Alternatively, the outer circumferential portion of the shielding plate may be provided with a plate protrusion or an uneven portion. Accordingly, a contact area between the shielding plate and the cover may be increased.

A ground shield includes a plurality of contact members configured to contact the ground contacts of a column of contacts of an electrical connector, so as to electrically common the grounds to each other.

A ground shield includes a plurality of contact members configured to contact the ground contacts of a column of contacts of an electrical connector, so as to electrically common the grounds to each other.

A shield connector structure is provided that can increase the precision in the size of a connection portion of a shield electric wire and can improve the water-stop performance of the connection portion without being affected by the tolerance of the external diameter of a shield unit and an external insulating covering of the shield electric wire. A shield connector includes a connection member fixed to an outer surface of a metal case and a shield member connecting the connection member and a shield unit of a shield electric wire, and a shield pipe configured to fix an exposed portion of the shield unit to the shield member. A first tubular unit of the shield member is inserted between the exposed portion of the shield unit and an internal insulating covering.

A shield connector structure is provided that can increase the precision in the size of a connection portion of a shield electric wire and can improve the water-stop performance of the connection portion without being affected by the tolerance of the external diameter of a shield unit and an external insulating covering of the shield electric wire. A shield connector includes a connection member fixed to an outer surface of a metal case and a shield member connecting the connection member and a shield unit of a shield electric wire, and a shield pipe configured to fix an exposed portion of the shield unit to the shield member. A first tubular unit of the shield member is inserted between the exposed portion of the shield unit and an internal insulating covering.

A cable termination apparatus for an underwater cable with a conductive core, an axially extending annular insulation portion radially outwardly of the core and an axially extending annular conductive screen layer radially outwardly of the insulation portion. The apparatus having a stress control sleeve, located radially outwardly of the insulation portion and extending partially over the annular conductive screen layer. The stress control sleeve includes an insulating portion and a conductive portion. When the cable termination apparatus is assembled the conductive portion of the stress control sleeve is in contact with an end portion of the screen layer.

A cable termination apparatus for an underwater cable with a conductive core, an axially extending annular insulation portion radially outwardly of the core and an axially extending annular conductive screen layer radially outwardly of the insulation portion. The apparatus having a stress control sleeve, located radially outwardly of the insulation portion and extending partially over the annular conductive screen layer. The stress control sleeve includes an insulating portion and a conductive portion. When the cable termination apparatus is assembled the conductive portion of the stress control sleeve is in contact with an end portion of the screen layer.

In accordance with an embodiment, an electrical cable can be configured to electrically connect to contact pads that are carried by a substrate. The electrical cable can include at least one, such as a pair, of electrical signal conductors and at least one, for instance a pair, of electrically conductive drain wires. A drain wire in the electrical cable can define a first surface that is configured to face the signal conductors and a second surface that is opposite the first surface. The drain wire can define a width that is greater than 0.12 mm as measured from the first surface to the second surface along a straight line. At least one auxiliary wire can be attached to at least one drain wire. The auxiliary wire can be configured to attach to the substrate.