A cable conduit end for securing a cable to a cable abutment of a latch is provided. The cable conduit end including: a housing; an alignment feature incorporated into a surface of the housing; a pair of flexible retention features integrally formed with the housing of the conduit end, wherein the flexible retention features are spring biased into a first position.

A cable conduit end for securing a cable to a cable abutment of a latch is provided. The cable conduit end including: a housing; an alignment feature incorporated into a surface of the housing; a pair of flexible retention features integrally formed with the housing of the conduit end, wherein the flexible retention features are spring biased into a first position.

Disclosed are a jumper cable, a starting power supply and a jump start device. The jumper cable includes first and second input terminals respectively configured to be connected with positive and negative electrodes of a starting power supply; first and second clamps respectively configured to be clamped to positive and negative electrodes of a vehicle battery; the second input terminal and the second clamp are electrically connected; a switching device, wherein the first input terminal and the first clamp are electrically connected through the switching device; and a non-MCU controlling circuit electrically connected with a controlling terminal of the switching device, configured to control the switching device to be switched on when the clamps are properly connected to the electrodes of the vehicle battery, and configured to not control the switching device to be switched on when the clamps are reversely connected to the electrodes of the vehicle battery.

A method for manufacturing a female terminal (1) with a tubular portion (11) formed by bending a metal plate into a tubular shape and resilient contact pieces (12) extending from the tubular portion (11) in an axial direction of the tubular portion (11), folded inwardly of the tubular portion (11) and configured to resiliently contact a mating terminal inside the tubular portion (11) includes a joining step of joining metal members thinner than the metal plate to the metal plate, and a forming step of bending the metal members joined to the metal plate and forming the metal members as the resilient contact pieces.

A female terminal disclosed by this specification is a female terminal (10) to which a male terminal (50) is connected from front, and includes a bottom plate (15) long in a front-rear direction, a ceiling plate (16) disposed to face the bottom plate (15), a pair of side plates (17) linking both side edges of the bottom plate (15) and both side edges of the ceiling plate (16), a step portion (25) provided on a front end edge of the bottom plate (15) in a stepwise manner to be slightly higher than the bottom plate (15) and extending forward to be disposed between the pair of side plates (17), and a resilient contact piece (30) resiliently displaceably provided by being folded rearwardly from a front end edge of the step portion (25), the male terminal (50) being capable of resiliently contacting the resilient contact piece (30) from front.

A female terminal disclosed by this specification is a female terminal (10) to which a male terminal (50) is connected from front, and includes a bottom plate (15) long in a front-rear direction, a ceiling plate (16) disposed to face the bottom plate (15), a pair of side plates (17) linking both side edges of the bottom plate (15) and both side edges of the ceiling plate (16), a step portion (25) provided on a front end edge of the bottom plate (15) in a stepwise manner to be slightly higher than the bottom plate (15) and extending forward to be disposed between the pair of side plates (17), and a resilient contact piece (30) resiliently displaceably provided by being folded rearwardly from a front end edge of the step portion (25), the male terminal (50) being capable of resiliently contacting the resilient contact piece (30) from front.

A terminal with ribbed contact springs for receipt of a mating terminal therein. The receptacle terminal has a contact portion which includes a bottom wall with contact sections extending from opposed sides of the bottom wall. Each of the contact sections have at least two resilient arms which extend from the bottom wall to a mating terminal engagement member. The at least two resilient arms have arcuate portions which extend from the bottom wall to the mating terminal engaging members. Each of the at least two resilient arms has a reduced contact spring rate, thereby allowing the contact normal force to be more accurately controlled with the same manufacturing tolerances. More controlled normal force allows for a minimum contact normal force to be reliably maintained while reducing the insertion force required during mating.

Disclosed is a socket apparatus for ball grid array (BGA) balls, including a base member of electrically insulative material, a plurality of electrical contact members disposed in row and column configuration attached to the electrically insulative material, a plate member extending in a row direction, and a plurality of extension members connected to the plate member and configured to press BGA balls of a mounted BGA into the plurality of electrical contact members when the plate member is pulled in a first direction.

A belt connector is provided. The belt connector is configured to electrically connect a conductor of an electrode belt to a male portion of a snap connector electrode connected to a biometric device. The belt connector includes a frame, a fastener, and an engaging member. The frame includes a receiving hole having radial flexibility. The receiving hole is configured to receive and fasten the frame to a protrusion of the male portion of the snap connector electrode. The fastener is configured to fasten the frame to a first end of the electrode belt. The engaging member is adjacent to the receiving hole and engages the conductor of the electrode belt by the conductor passing through the receiving hole. When the male portion of the snap connector electrode penetrates the receiving hole, the conductor is forced into contact with a lateral surface of the male portion of the snap connector electrode.

A belt connector is provided. The belt connector is configured to electrically connect a conductor of an electrode belt to a male portion of a snap connector electrode connected to a biometric device. The belt connector includes a frame, a fastener, and an engaging member. The frame includes a receiving hole having radial flexibility. The receiving hole is configured to receive and fasten the frame to a protrusion of the male portion of the snap connector electrode. The fastener is configured to fasten the frame to a first end of the electrode belt. The engaging member is adjacent to the receiving hole and engages the conductor of the electrode belt by the conductor passing through the receiving hole. When the male portion of the snap connector electrode penetrates the receiving hole, the conductor is forced into contact with a lateral surface of the male portion of the snap connector electrode.