The present invention relates to the technical field of underwater communications, and discloses a bridging transmission device for underwater wireless signals, which includes a coaxial cable and two conversion assemblies. The coaxial cable can transmit the weak electric signal. The transmission device transmits and converts wireless signals by means of signal bridging between two or among more independent intelligent terminal devices, converts the electromagnetic wave signal and the weak electric signal to each other through two groups of conversion antennas, and transmits the weak electric signal under water through the coaxial cable, so the purpose of the remote transmission of underwater wireless signals can be achieved. The conversion assembly has no need to be wired to the intelligent terminal device through an interface, so the waterproof performance is good, and the universality is high.

A differential mode instrumentation cable for improving the signal integrity of audio signals in different environments including use of microphones, speaker cable, audiophile cables and analog audio balanced/differential tie lines comprising a first triaxial cable and a second triaxial cable placed side-by-side and mounted together, said first coaxial cable and said second coaxial cable including a wired connection that includes an active driven shield buffer circuit in each triaxial cable having an inner conductor for voltage in from the positive polarity and minus polarity and the voltage out driven guard shield with series breakout resistor connected to the each triaxial inner shield.

A corrosion resistant termination connector for connecting to a steel wire rope and a modular fitting for use on a magnetic influence minesweeping cable is provided. The connector body is made of a high strength composite material, and has a common channel. The body has three sections: A ribbed annular stem, an abutment band with uniform edges for forming sealing occlusions, and an externally threaded spelter socket with a conical channel. Strands of the wire rope are splayed and adhesively joined with a mixture of thermosetting resins forming a conical wedge that secures the rope within the conical channel. The modular fitting is screwed on the elongate socket section, and includes a pin with a thimble. A molded insular cover seals the steel wire rope and the ribbed stem.

It is aimed to externally fit a sleeve formed into a tubular shape to a braided wire. A mounting device is a device for mounting a tubular sleeve on a coaxial cable having a front end part of a braided wire exposed in front of a sheath to externally fit the sleeve to the braided wire, and is provided with an expansion restricting jig including an expansion restricting portion for restricting expansive deformation of the braided wire and relatively displaceable in an axial direction with respect to the braided wire with the expansion restricting portion held in contact with an outer peripheral surface of the braided wire. The expansion restricting jig is formed with a positioning portion for positioning the sleeve concentrically with the braided wire with the sleeve arranged forward of the expansion restricting portion.

A recessed, deployable ceiling box assembly comprising a ceiling frame-mounting member and a ceiling box member, a support member for securing the ceiling frame-mounting member to a ceiling structural member and one or more connector members for attaching the ceiling box member to the ceiling frame-mounting member. The ceiling box member is deployable from a retracted position, where the ceiling box member is retained within the ceiling frame-mounting member at or above the height of the ceiling, to a deployed position, where the ceiling box member hangs by the connector member below the height of the ceiling. A door may be used to cover the contents of the deployable ceiling box assembly.

The invention is directed to a cable assembly (1) comprising a coaxial cable (2) with an inner conductor (3) and a shield (4) and a dielectric (5) arranged between the inner conductor (3) and the shield (4). The cable assembly (1) further comprises an outer jacket (7) which encompasses the coaxial cable (2). One or several spacers (10) are arranged between the coaxial cable (2) and the outer jacket (7) such that the outer jacket (7) and the coaxial cable (2) are spaced a distance apart.

A cable assembly for a flame sensor apparatus includes an inner conductor electrically connected to a photodiode that generates a current. The inner conductor transmits the current from the photodiode. A first insulating layer circumferentially surrounds the inner conductor. The first insulating layer includes a mineral insulation material. An inner sheath circumferentially surrounds the first insulating layer. The inner sheath includes an electrically conductive material. A second insulating layer circumferentially surrounds the inner sheath. The second insulating layer includes a mineral insulation material. An outer sheath circumferentially surrounds the second insulating layer. The outer sheath includes an electrically conductive material. The cable assembly is for use in temperatures up to about 300 degrees Celsius or greater. A method of attaching a cable assembly for a flame sensor apparatus.

A conductor joint (1) is provided for connecting two conductors along a longitudinal direction. The conductor joint comprises a first segment having a first segment end (202) adapted connecting to an end portion of a first conductor and a second segment (300) comprising a second segment end (302) relative to the longitudinal direction adapted for receiving a second conductor end of a second conductor. The second segment further has an opposite second segment end (304) fixed, or forming an integral part with, an opposite first segment end (204) of the first segment (200), a tubular sleeve (310) and a core rod (320) wherein ends (310a, 320a) of the tubular sleeve (310) and the core rod (320) are arranged with a radial offset forming a sleeve opening for receiving at the end portion of the second conductor end of the second conductor.

A conductor joint (1) is provided for connecting two conductors along a longitudinal direction. The conductor joint comprises a first segment having a first segment end (202) adapted connecting to an end portion of a first conductor and a second segment (300) comprising a second segment end (302) relative to the longitudinal direction adapted for receiving a second conductor end of a second conductor. The second segment further has an opposite second segment end (304) fixed, or forming an integral part with, an opposite first segment end (204) of the first segment (200), a tubular sleeve (310) and a core rod (320) wherein ends (310a, 320a) of the tubular sleeve (310) and the core rod (320) are arranged with a radial offset forming a sleeve opening for receiving at the end portion of the second conductor end of the second conductor.

The present invention relates to the technical field of underwater communications, and discloses a bridging transmission device for underwater wireless signals, which includes a coaxial cable and two conversion assemblies. The coaxial cable can transmit the weak electric signal. The transmission device transmits and converts wireless signals by means of signal bridging between two or among more independent intelligent terminal devices, converts the electromagnetic wave signal and the weak electric signal to each other through two groups of conversion antennas, and transmits the weak electric signal under water through the coaxial cable, so the purpose of the remote transmission of underwater wireless signals can be achieved. The conversion assembly has no need to be wired to the intelligent terminal device through an interface, so the waterproof performance is good, and the universality is high.