The present disclosure provides a compression teeth ring connection pipe fitting, which includes a pipe fitting body and a sealing component; the pipe fitting body includes a middle pipe section, a first flared section, and a second flared section; a diameter of the first flared section is greater than a diameter of the middle pipe section, and a first limit platform is formed at a connection position between the two; a diameter of the second flared section is greater than that of the first flared section, and a second limit platform is formed at a connection position between the two; the sealing component includes a sealing ring, a high temperature sealing ring, and a teeth ring that are coaxial and sequentially arranged; inner rings of the sealing ring, the high temperature sealing ring, and the teeth ring form a space for nesting a steel pipe body.

A conveying device for use in the field of plastics has a frame and a weighing cell connected to the frame. A separating unit is suspended from the weighing cell. A first coupling is connected to the frame and connects a vacuum source to the separating unit. A second coupling is connected to the frame and connects a conveying line for goods to be conveyed to the separating unit. At least one of the first coupling and the second coupling has a first coupling part connected to the separating unit and a second coupling part connected to the frame, wherein the first and the second coupling parts do not contact each other in a region of no contact. At least one sealing element is provided to seal the region of no contact between the first and the second coupling parts.

A reducing fibre optic cable tube connector with a plastic body having a connector at either end for connection to a respective tube. The body has a wide portion terminating at a wide end and a narrow portion terminating at a narrow end to receive tubes of a different diameters. The two portions meet at a central region of the body. Each portion includes an annular inner sleeve extending from the central region and spaced from an inner wall of the outer body to define an air gap. At the central region the annular sleeves extend toward one another so the first and second air gaps are axially spaced by less than 1 mm.

Provided is a pipe adapter assembly that can join different sized pipes together. The pipe adapter assembly may generally comprise a housing, an insert, and a grip actuator. The housing may comprise a lumen and a bore positioned inwardly from a first end. The insert may comprise a passage having a plurality of teeth and a tapered outer surface with at least one slot. The grip actuator may comprise a flanged body and a protrusion wherein the protrusion is configured to fit within the bore of the housing. The protrusion may further include an abutment surface that extends concentrically about an aperture through the grip actuator. In an embodiment, the pipe adapter is configured to receive a pipe member through the lumen, passage, and aperture and to selectively lock the housing to the pipe member.

A tube connector for attachment to an end of a tube of a pressurized fluid system has a housing, a main sealing element, a gripping element and a cone element. The main sealing element is arranged for sealing an inner surface of the housing to an outer surface of a tube. The gripping element comprises a gripping edge for engaging with an outer surface of a tube. The cone element limits a movement of the grip-ping element. The tube connector further has an integrated release element. The release element has a tubular part, a top part and an environmental sealing. A release edge of the tubular part engages with the gripping element and the environmental sealing is adapted for sealing a receptacle formed in the housing of the environment.

An apparatus (10) for coupling with a pipe (12), the apparatus (10) including a body assembly (13) having a body (14) adapted to fit with the pipe (12), and at least two gripping parts (16) moveably coupled to the body (14), the at least two gripping parts (16) being adapted to be moveable between an insertion condition, in which the gripping parts (16) are resiliently depressible to allow movement of the pipe (12) in a first insertion direction, and a gripping condition in which the gripping parts (16) each engage with opposing side walls (18) of the pipe (12) to restrict movement of the pipe (12) in a second opposing direction thereby coupling the apparatus (10) and the pipe (12).

A method for inhibiting separation of joined pipes including providing within a pipe bell a gasket including rigid segments, each segment having bell teeth configured for engaging the bell and a spigot tooth configured for engaging a pipe spigot seated in the bell. Upon pressurization and over-pressurization of the joint, resulting axial forces exerted on the joint, which can cause pipes to separate, are countered by wedging the segments between the bell and the spigot and rotating each segment so that the thrust forces are directed radially. To prevent radially-directed thrust forces from damaging the joint through over-rotation of the segments, the bell teeth and the spigot tooth are adapted and arranged to maintain the thrust forces load path carried by each segment within a desired angular range relative to the spigot by transferring the load path between adjacent bell teeth whereby the effective length of each segment is increased.

A fitting for a pipe has a cylindrical sleeve and a spigot fitted concentrically within the sleeve. The sleeve is slidable along the spigot in a proximal direction. The sleeve has a gripper ring cavity with a conical bearing surface with a diameter that is smaller at the distal end and a larger at the proximal end. One or more gripper rings fit within the cavity and slidingly engage the bearing surface. The spigot has an outer surface sized to fit within a proximal end of the pipe. The inner surface of the gripper rings and the outer surface of the spigot define an annular space with a first radial width sized to accept insertion of the proximal end of the pipe. When the sleeve is moved with respect to the spigot in the proximal direction toward a sealed position, the rings are inwardly compressed by the bearing surface to grip an outer surface of the pipe. The end of the pipe is drawn into a space between the sleeve and the spigot with radial width smaller than the first radial width.

A solenoid valve quick-connecting structure includes a main body having a three-way channel therein. A surface of the main body is formed with a first connecting opening, a second connecting opening and a third connecting opening. At least one of the first connecting opening and the second connecting opening is provided with an accommodating chamber. The accommodating chamber has a reduced section and an enlarged section. The enlarged section is connected to one side of the reduced section, distant from the first connecting opening or the second connecting opening. The accommodating chamber is provided with a positioning clamp that has an annular base and spaced clamping blocks. The clamping blocks are deformable through a gap defined between every adjacent two of the clamping blocks for clamping an external pipe. A solenoid valve body is disposed at the third connecting opening for opening or closing the three-way channel according to an electronic signal.

A pipe coupling device includes a body adapted for insertion into a pipe, the body having a through passage, and on its outer surface a groove for receiving a seal for forming a fluid-tight seal between the pipe and the body, the seal having a retaining portion and a sealing portion, wherein either the groove, the seal or both are constructed and arranged such that the retaining portion holds the seal within the groove when the sealing portion is subjected to the insertion force experienced when the pipe coupling device is inserted into a pipe. Further, the base portion may be axially wider than the sealing portion. Further, the seal may include reinforcing means adapted to prevent the seal leaving the groove.