An expansion ring for a fluid connector including a including a first end, a second end, a radially outward facing surface, and a through-bore, wherein the expansion ring is slidably engaged with the connector body.

A connector that is in a fuel supply system capable of supplying a high-pressure fuel, and may reduce pulsation in a low-pressure pipe with a simple structure and extend the life of a mold is provided. A valve of the connector includes a valve seat contact surface and a tapering through hole. The valve seat contact surface axially separates from an annular valve seat and forms a forward-direction flow path due to pressure of the low-pressure fuel when the high-pressure fuel does not flow in reverse, and may come into contact with the annular valve seat when the high-pressure fuel flows in reverse. The tapering through hole is formed farther radially inward than the valve seat contact surface, forms an orifice flow path having a smaller cross-sectional area than the forward-direction flow path, and allows a reverse flow of the high-pressure fuel when the high-pressure fuel flows in reverse.

A technique facilitates connection of tubulars along a tubing string via a linear motion. A first tubular is provided with a first connector end having a non-circular transverse cross-section, and a second tubular is provided with a second connector end having a corresponding non-circular transverse cross-section. The non-circular cross-section and the corresponding non-circular cross-section are designed to matingly engage when the first and second tubulars are moved linearly toward each other to form a tubing string. A seal is provided to seal the first connector end with the second connector end once linearly engaged. A locking mechanism may be employed to linearly lock the first connector end with the second connector end.

An assembly, connector and method is disclosed for making a fluid connection between a vessel wall and a fluid tube. The assembly includes a male connector having a cylindrical body and an internal fluid passage through the male connector between a head portion located at an upper end of the male connector and a base portion on a lower end of the male connector. An aperture is formed on the vessel wall and at least first and second recesses are formed along an edge of the aperture. The base portion has at least first and second locking members located in a spaced relation to the other on opposite sides of the base portion and a sealing flange extends circumferentially about the base portion. The base portion is arranged to be installed in the aperture with each locking member accepted within a respective recess. Rotation of the male connector causes the locking members to rotate within the aperture and seal the sealing flange against the wall. A female connector connected to the fluid tube is installed on the male connector head portion.

A valve device (20) includes male and female housings (22, 24) that together define a fluid through-passage (28). The male and female housings have, respectively, exterior and interior annular channels (22a, 24a). The male housing is receivable into the female housing such that the exterior and interior annular channels together define a toroidal tube. First and second valve elements (30,32) are disposed, respectively, in the male and female housings. Ball locks (36) are receivable into the toroidal tube and axially lock the male and female housings together. A lock (40) engageable when the first and second valve elements are in functional alignment and which when engaged rotationally locks the male and female housings.

A metallic fitting assembly 10 employs a clip-to-body attachment for locking a tube end 12 of a fluid system component to the fitting assembly. The fitting assembly 10 includes a fitting body 14 defining a fluid flow path 26 between a first end and a second end opposite from the first end, wherein the first end is configured to receive a tube end 12 of a first fluid system component, and the fitting body 14 defines a clip slot 34 adjacent to the first end, and a material of the fitting body includes metal; and a clip 16 wherein a material of the clip includes metal. When the tube end 12 is inserted through the first end of the fitting body 14, the clip 16 is inserted through the clip slot 34 and around the tube end 12 to engage the tube end in a connected state in which the tube end 12 is locked within the fitting body 14. The fitting body 14 includes a main body 28 and a ring end 30 that define the clip slot 34 between the main body 28 and the ring end 30, the main body 28 and the ring end 30 being attached to each other by a bridge 32. For freeze resistance, the ring end 30 is configured to minimize distortion to 0.010″ (0.25 mm) or less at a tensile load of 500 lbf (2200 Newtons). A ratio of a cross-sectional area of the ring end to an inner diameter of the fitting body may be from 21 % to 73%. The bridge 30 may have a width within a range of 20% to 70% of an outer diameter of the fitting body.

A pipe connecting seat has a sleeve and two positioning members. The positioning members are disposed on the sleeve at a spaced interval. Each one of the two positioning members has a positioning arm and a positioning pin. The positioning arm is openably, positionably, and pivotally disposed on the sleeve, and has at least one reinforcing protrusion for increasing strength of the positioning arm. The positioning pin is disposed on the positioning arm and is located out of the positioning arm for positioning the positioning arm and limiting a pivoting opening range of the positioning arm. When the pipe connecting seat is connected to two pipes, the two positioning members are always located on the sleeve and are not prone to loss. The operating convenience of the pipe connecting seat is increased.

An embodiment of the present subject matter includes: a plurality of sockets connected to a plurality of hoses through which hot water is supplied and returned, and formed in a detachable structure; and clips provided outside the plurality of sockets with a clearance to support the plurality of sockets so as to have a degree of freedom.

A quick connector (QC) assembly comprises a housing defining a fluid passageway extending along an axis at an open end, a retainer ring disposed in the open end and defining a slot, a retainer clip secured to the housing and at least partially disposed within the fluid passageway at the open end, and a verification tab disposed within the slot. The tab is slideably displaceable along the slot between a negative position, where the tab is completely disposed within the housing, and a positive position, where a portion of the tab is visibly disposed above an exterior surface of the housing.

A fluid line quick connector serves to join fluid lines together in vehicle applications, as well as in industrial-manufacturing, aircraft, marine, and agricultural applications, among other possibilities. The fluid line quick connector has a retainer assembly with a primary latch and a secondary latch. A data matrix is provided, and can be in the form of a quick response (QR) code, as an example. In use, when the secondary latch is in the open position, the data matrix is partially or more concealed. And when the secondary latch is in the closed position, the partial or more concealment is absent and the data matrix can be properly read.