A connector for facilitating fluid transfer includes first fitting, a second fitting, a rigid conduit, a first retaining connector, and a second retaining connector. The rigid conduit includes a flexible tube surrounded by a deformable sleeve. The rigid conduit is connected on a first end to the first fitting and on a second end to the second fitting. The first retaining connector connects the first fitting to the rigid conduit and the second retaining connector connects the second fitting to the rigid conduit. A lumen extends through the rigid conduit and is capable of being sealed. The rigid conduit and the flexible tube are capable of being severed while maintaining the seal of the lumen to separate the first fitting from the second fitting. The connections of the first fitting and the second fitting to the rigid conduit are capable of withstanding at least 1 bar of pressure without leaking.

A remotely-operated fluid connection assembly to hold higher internal pressures in larger diameters. The assembly comprises a fluid connection adapter and a fluid connection housing assembly. When the adapter enters the housing assembly: (A) locking elements on the housing assembly constrict about the adapter; and (B) at least a first seal section on the adapter sealingly contacts a first seal bore on the housing assembly. Progressive engagement of a locking ring upon the locking elements urges the locking elements to tighten against the adapter. Internal pressure encourages adapter displacement, which then further tightens the adapter against the locking elements as now restrained by the locking ring. Internal pressure further encourages the first seal section on the adapter to expand radially to tighten the contact with the first seal bore in the housing assembly.

The present invention relates to a connector for substantially aseptic connection, said connector comprising a connector member (1) having a connection end (13) and a coupling end (12), wherein the coupling end (12) comprises a coupling element (15) for engaging a similar coupling element (15) on a similar connector (100) to form a first seal (B), and a cover (2) arranged to enclose the coupling end (12) for providing an aseptic seal that separates the coupling end (12) from a surrounding, the cover (2) comprising at least two cover portions (21A, 22A), each cover portion (21A, 22A) being configured to be successively-positioned on or adjacent the coupling end (12) of the connector member (1), wherein each cover portion (21A, 22A) comprises a seal member (21, 22) for engaging a similar seal member on a similar connector thereby to form a second seal (A) when so positioned on or adjacent the coupling end (12) of the connector member (1). The invention also relates to a method for connecting and disconnecting two such connectors.

A removable hood for a fume extractor comprises a shield defining an internal cavity and having one or more vent openings in an upper portion, a welding opening in a rear portion, one or more viewing openings in one or more sides, and a pipe opening in a bottom portion of the shield. The pipe opening comprises arcuate portions on either side thereof for placement adjacent to a pipe. The hood also comprises a removable attachment mechanism on the upper portion of the shield configured to selectively couple the one or more vent openings to an extraction arm of the fume extractor, one or more layers of window material coupled to the shield to cover each of the one or more viewing openings, and one or more internal airflow spaces shaped to direct air flow to cool the window material when suction is applied to the vent openings.

A push-to-connect coupling with integrated filtration is disclosed. In one aspect, the coupling comprises a tube support, a collet and a filter element. The coupling may include a seal. The coupling connects to a cavity, which may be a portable fitting. The cavity may be a connection on a separate device or system, such as an air tank or other devices. The filter element may be dome-shaped. The tube support is easily assembled with the cavity, for example by threading, to capture the filter element. The tube is connected to the coupling by pushing the tube over the tube support and through the collet. The collet interacts with a reduced diameter section of the cavity to apply a clamping force from the collet on the tube and secure the tube in place. The tube is easily removed from the cavity simply by pushing the collet farther into the cavity to remove the clamping force on the tube, and then pulling the tube out.

A water delivery device includes a plurality of magnetic joints each including a plurality of magnetic members, and a plurality of conduit sections each rotatably coupled to each other by a magnetic joint of the plurality of magnetic joints. The plurality of conduit sections collectively define a spout of the water delivery device. The spout extends from a first portion configured to be coupled to a mounting surface to a second portion configured to discharge a fluid. The water delivery device is configured such that magnetic joints located closer to the first portion include a greater number of magnetic members than magnetic joints located closer to the second portion.

A pure electric modular subsea test tree is provided, which includes a connect-disconnect device, wherein the first channel is formed in the connect-disconnect device; the connect-disconnect device is provided with a locking assembly and a connection drive mechanism for driving the locking assembly, and the first electrical connection plug is embedded in the connect-disconnect device, and the connection drive mechanism is electrically connected with the first electrical connection plug; a shear-seal assembly, wherein a second channel communicated with the first channel is formed in the shear-seal assembly; the shear-seal assembly includes at least one shear-seal device capable of plugging the second channel; a connection part is formed on the shear-seal assembly; a heating device is arranged at one end of the shear-seal device far from the connection part. The disclosure relates to a pure electric modular subsea test tree, which has fast response speed and high operation safety.

A member linking mechanism, pairable with a gas chromatograph, which has a small and simple configuration, and is capable of linking two members together with a required fastening force even in a limited space. The member linking mechanism includes a first member having a member linking part with an opening at its distal-end surface; a second member to be linked to the member linking part of the first member; an elastic sealing member sandwiched between the first and second members so as to seal the opening of the distal-end surface of the member linking part; and a linking member for linking the first and second members together via pressure. The linking member includes: a linking member body configured to hold an end part, of the second member, adjacent to the first member; and an elastic deformation part provided to the linking member body.

A coupling sleeve (1) for a hydraulic coupling to a pressure medium line, for a coupling with a coupling plug (2), having a housing (3) and a sealing unit (4). The housing (3) has a flow channel (5) for a pressure medium and a coupling axis A. The sealing unit (4) includes a sleeve body (6), a pressure sleeve (7), and a valve tappet (8). The sealing unit (4) delimits part of the flow channel (5), the valve tappet (8) is held on the sleeve body (6) and is arranged in the flow channel (5). The pressure sleeve (7) encloses the valve tappet (8). The pressure sleeve (7) can be displaced along the coupling axis A and is held between a closing position, in which the flow channel (5) is locked, and an opening position, in which the flow channel (5) is unlocked. The pressure sleeve (7) is loaded by a pressure spring (10) in the closing direction. A coupling force must be applied by a user to produce a positive coupling to a coupling plug (2).

A multi-coupling assembly includes a housing, and a first female coupler and a second female coupler that are housed within the housing. Each of the first female coupler and the second female coupler are moveable between a coupling position connectable to a respective male coupler to permit a flow of fluid through the multi-coupling assembly, and a release position in which the male coupler is releasable from a respective female coupler. A rotational lever has a handle portion that is external from the housing and a shaft portion that extends from the handle portion into the housing. Rotation of the rotational lever moves one of the female couplers from the coupling position to the release position without affecting a connection state of the other of the female couplers. Such independent operation of the female couplers is achieved by rotating cams that are configured such that when one of the cams rotates to interact against its respective female coupler, the other of the cams does not act on its respective female coupler. Pressure relief valves are operated such that internal pressure within a female coupler is released prior to the female coupler reaching the release position during a disconnection operation of the male coupler, and prior to the female coupler reaching the coupling position during a connection operation of a male coupler.