A gel filled electrical connector is disclosed and claimed. The connector has a base configured to house a gel fill insulating material and a plurality of 10-gauge or larger diameter wires; the base comprising a plurality of wire receptacles to receive a plurality of wires in a cavity in the base; a top cover sized to be securely and removably attached to the base, wherein the top cover comprises a plurality of wire connectors to strip insulation from the plurality of wire and to electrically connect the plurality of wires; and a gel deposited into the cavity to provide moisture resistance to the plurality of wires and plurality of wire connectors.

Components and systems are disclosed for implementing downhole splice connections such as within a wellbore. In some embodiments, a downhole splice connector includes at least one connector body having an inner diameter defining a cavity within which at least one connector receptacle is disposed, and at least one conductive center pin disposed within the at least one connector receptacle. The downhole splice connector further includes at least one pressure sleeve annularly disposed between an inner diameter of the connector body and an outer diameter of the center pin, such that a pressure barrier is formed between an outer diameter of the pressure sleeve and an inner diameter of the connector body and a pressure barrier is formed between an inner diameter of the pressure sleeve and an outer diameter of the center pin.

Connector comprising a substantially cylindrical base and a plug connectable to the base in a detachable manner, in which connector a plurality of contacts are mounted in a contact block. The block comprises a flexible membrane through which the contacts extend, the compression of the membrane allowing the sealing at the interface between said membrane and the contacts to be ensured.

Disclosed are an electrical penetration assembly, a manufacturing method thereof, and an electrical penetration device, which relate to the technical field of electrical penetration. The electrical penetration assembly comprises sealing glass (5), an outer tube (4) and a conductor (7) inserted into the outer tube (4), wherein both ends of the outer tube (4) are blocked by supporting and fixing blocks (8), and both ends of the conductor (7) respectively protrude from the corresponding supporting and fixing blocks (8); the sealing glass (5) is sintered between the conductor (7) and the outer tube (4) and is configured to divide an annular cavity jointly enclosed by the conductor (7), the outer tube (4) and the supporting and fixing blocks (8) into an upper cavity and a lower cavity; an optical fiber (14) penetrates the sealing glass (5), at least one end of the optical fiber (14) is connected to an optical fiber splice (3) after protruding from the corresponding supporting and fixing block (8), and a portion of the optical fiber (14) located in the sealing glass (5) is inscribed with a fiber Bragg grating to form a first fiber Bragg grating sensor (1). By utilizing the first fiber Bragg grating sensor (1) to monitor the strain and temperature of the sealing glass (5) in real time, not only can it judge whether the electrical penetration assembly meets the requirements for hermeticity, but also enable precise control of the sintering temperature.

An electrical connector includes an insulative cover having a dividing wall and defining a mating space in front of the dividing wall and a mounting space behind the dividing wall, an insulative housing received in the mounting space of the insulative cover, plural contacts insert-molded with the insulative housing and extending through the dividing wall to expose in the mating space, and a sealing member disposed between the dividing wall and the insulative housing.

A connection device for connecting an electrical or electronic component, which is accommodated in a thick-walled housing part, through a stepped bore in the wall of the housing part, includes a connection part having a stepped cylindrical body having a first cylindrical portion with a first outer diameter corresponding to the diameter of an inner bore portion of the stepped bore and a second cylindrical portion with a second outer diameter corresponding to the larger diameter of an outer bore portion, and a separate, essentially cylindrical contact carrier part fixed in the base body, which has contact pins protruding from an inner end face located on the inside of the thick-walled housing part. A fastener detachably fastens the connection part inserted in the stepped bore in the bore of the housing part.

A coaxial cable connector assembly includes a coupler defining an inner channel extending through the coupler and an outer conductor engagement feature extending inwardly from the inner channel, a rear body, positioned rearward of the coupler, defining a cable channel extending through the rear body, and structurally configured to receive the coaxial cable, and an adhesive reservoir positioned at least partially within the cable channel of the rear body, the adhesive reservoir including an adhesive and an adhesive reservoir breakable material that encapsulates the adhesive, where the adhesive reservoir breakable material is structurally configured to fracture upon the application of force exceeding a predetermined threshold, thereby releasing the adhesive from the adhesive reservoir to adhesively couple the coaxial cable to the rear body.

A connector includes a plurality of contacts made of metal material and arranged in an arrangement direction orthogonal to a fitting direction, an insulator made of insulating resin material and holding the plurality of contacts, and a reinforcement terminal made of metal material and attached to an end portion of the insulator in the arrangement direction, the insulator including a fitting portion extending along the arrangement direction and projecting in the fitting direction for fitting to a portion to be fitted of the counter connector, the reinforcement terminal including a terminal accommodating portion of recess shape for accommodating a reinforcement terminal of the counter connector, and a wall portion facing an end portion of the fitting portion in the arrangement direction across the terminal accommodating portion, the reinforcement terminal including a resin material flow passage penetrating the wall portion and reaching the end portion of the fitting portion.

A dispensing seal includes a base seal comprised of a first material. The base seal includes at least a top surface and a bottom surface and a cavity defined therein, wherein the bottom surface includes an opening to the cavity. A second material is located within the cavity of the base seal, wherein a viscosity of the second material is less than a viscosity of the first material.

The present disclosure discloses a waterproof connector including an integral insulating body, a number of conductive terminals, and an insulating block. The insulating body includes a rear end portion, a front end portion, and a middle portion. The rear end portion defines a number of terminal grooves. The front end portion defines a mating space. The middle portion includes a receiving channel communicating with the terminal grooves. The terminals are disposed in the terminal grooves and extend towards the mating space. The insulating block is injection-molded in the receiving channel and seamlessly fixes the conductive terminals in the terminal grooves. The waterproof connector of the present disclosure can prevent water and dust from entering therein. A method of manufacturing the waterproof connector is also provided.