A plug (1) for a profiled safety edge section (2), comprising a first contact element for a first wire (3) of the profiled safety edge section (2), a second contact element for a second wire (4) of the profiled safety edge section (2), and an insertion nose (16), wherein the two contact elements are received in the insertion nose (16). The first contact element is a first support (8) with a first claw (9), and the second contact element is a second support (10) with a second claw (11).

A plug (1) for a profiled safety edge section (2), comprising a first contact element for a first wire (3) of the profiled safety edge section (2), a second contact element for a second wire (4) of the profiled safety edge section (2), and an insertion nose (16), wherein the two contact elements are received in the insertion nose (16). The first contact element is a first support (8) with a first claw (9), and the second contact element is a second support (10) with a second claw (11).

An electromagnetic terminal shield includes a shield body formed of sheet metal having a connector opening configured to receive a corresponding mating terminal shield and a cable opening configured to receive a wire cable and a plurality of cantilevered spring arms integrally formed with the shield body having fixed ends attached to the connector opening and free ends disposed within a shield cavity defined by the shield body. Each spring arm in the plurality of cantilevered spring arms has a free end that is in contact with the inner surface of the shield body within the shield cavity. A process for manufacturing an electromagnetic terminal shield and the electromagnetic terminal shield produced by this process are also presented herein.

An electromagnetic terminal shield includes a shield body formed of sheet metal having a connector opening configured to receive a corresponding mating terminal shield and a cable opening configured to receive a wire cable and a plurality of cantilevered spring arms integrally formed with the shield body having fixed ends attached to the connector opening and free ends disposed within a shield cavity defined by the shield body. Each spring arm in the plurality of cantilevered spring arms has a free end that is in contact with the inner surface of the shield body within the shield cavity. A process for manufacturing an electromagnetic terminal shield and the electromagnetic terminal shield produced by this process are also presented herein.

A structure for fixing a cable for a waterproof fan case according to the present disclosure includes: a frame on which a motor is installed, and a blade is rotatably installed in a state in which a driving shaft of the motor is connected to a front side thereof; an insertion tube which extends rearward from the frame, has therein an insertion hole to which a power line connected to the motor is penetratively coupled in a front and rear direction, and has a gap portion formed to be split at one side in a transverse direction; and a coupling ring which has a hollow portion that is penetratively formed in the front and rear direction so that the coupling ring is correspondingly coupled to an outer circumference of the insertion tube in a male-female manner, and has a pressing protrusion that is formed to protrude on an inner circumferential surface of the coupling ring so as to press and support an outer circumference of the power line through the gap portion when coupling the coupling ring to the insertion tube.

A structure for fixing a cable for a waterproof fan case according to the present disclosure includes: a frame on which a motor is installed, and a blade is rotatably installed in a state in which a driving shaft of the motor is connected to a front side thereof; an insertion tube which extends rearward from the frame, has therein an insertion hole to which a power line connected to the motor is penetratively coupled in a front and rear direction, and has a gap portion formed to be split at one side in a transverse direction; and a coupling ring which has a hollow portion that is penetratively formed in the front and rear direction so that the coupling ring is correspondingly coupled to an outer circumference of the insertion tube in a male-female manner, and has a pressing protrusion that is formed to protrude on an inner circumferential surface of the coupling ring so as to press and support an outer circumference of the power line through the gap portion when coupling the coupling ring to the insertion tube.

A signal transmission terminal, a sampling device, a battery module and a device are disclosed. The signal transmission terminal is used for the sampling device. The sampling device includes a conductive sheet. The signal transmission terminal includes a first connecting portion, a second connecting portion and a bendable portion. The first connecting portion is used for being connected to the conductive sheet and is provided with a raised portion. The second connecting portion is connected to the first connecting portion and is used for being connected to a sampling object. The bendable portion is used for being connected to the first connecting portion. The bendable portion is configured to press the conductive sheet between the first connecting portion and the bendable portion after being bent. The above signal transmission terminal can improve connection stability with the conductive sheet, such that reliability of sampling precision can be guaranteed.

A signal transmission terminal, a sampling device, a battery module and a device are disclosed. The signal transmission terminal is used for the sampling device. The sampling device includes a conductive sheet. The signal transmission terminal includes a first connecting portion, a second connecting portion and a bendable portion. The first connecting portion is used for being connected to the conductive sheet and is provided with a raised portion. The second connecting portion is connected to the first connecting portion and is used for being connected to a sampling object. The bendable portion is used for being connected to the first connecting portion. The bendable portion is configured to press the conductive sheet between the first connecting portion and the bendable portion after being bent. The above signal transmission terminal can improve connection stability with the conductive sheet, such that reliability of sampling precision can be guaranteed.

The present application provides a terminal body, a connection terminal and a sheet material for manufacturing a terminal body. The terminal body has an insertion portion including a first insertion plate and a second insertion plate. A gap is formed between the first insertion plate and the second insertion plate, which are commonly enclosed to form an insertion slot configured for a mating terminal to be inserted therein. The terminal body has a mounting structure, respectively arranged at the first insertion plate and the second insertion plate, and configured for fixing a limiting member; and a wiring portion, configured for connecting a core of a wire, and comprising a first wiring plate and a second wiring plate. At least a part of the first wiring plate and at least a part of the second wiring plate are stacked and in contact with each other. The core of the wire can be electrically connected to both the first wiring plate and the second wiring plate, which improves the conductivity and current-carrying performance of the wiring portion. The stacking arrangement of the first wiring plate and the second wiring plate not only reduces the space occupied by the wiring portion, and also improves the structural stability of the wiring portion.

The present application provides a terminal body, a connection terminal and a sheet material for manufacturing a terminal body. The terminal body has an insertion portion including a first insertion plate and a second insertion plate. A gap is formed between the first insertion plate and the second insertion plate, which are commonly enclosed to form an insertion slot configured for a mating terminal to be inserted therein. The terminal body has a mounting structure, respectively arranged at the first insertion plate and the second insertion plate, and configured for fixing a limiting member; and a wiring portion, configured for connecting a core of a wire, and comprising a first wiring plate and a second wiring plate. At least a part of the first wiring plate and at least a part of the second wiring plate are stacked and in contact with each other. The core of the wire can be electrically connected to both the first wiring plate and the second wiring plate, which improves the conductivity and current-carrying performance of the wiring portion. The stacking arrangement of the first wiring plate and the second wiring plate not only reduces the space occupied by the wiring portion, and also improves the structural stability of the wiring portion.