Provided is a joint device which can be connected by quick and simple operation while being subjected to high-pressure high-flow-rate pressurized operating oil. The present invention comprises: a closed chamber 27 provided in a hydraulic circuit on which pressurized fluid acts, the pressurized fluid circuit having an upstream side and a downstream side, which are closed by an upstream-side stop valve 211 and a downstream-side stop valve 212; a male joint 30 provided at a position in communication with the closed chamber 27; and a female joint 40 connectable to the male joint 30 and provided in an emergency hydraulic circuit connected to the hydraulic circuit. The present invention is configured so that the female joint 40 is connected to the male joint 30 while the closed chamber 27 is closed by the upstream-side stop valve 211 and the downstream-side stop valve 212.

Formation of a sterile connection includes inserting a first aseptic coupling device into a second aseptic coupling device while a locking ring of the first aseptic device is in an indexed initial position, rotating the locking ring to a secured position in which a compressive force is created and in which a first membrane from the first aseptic coupling device and a second membrane from the second aseptic coupling device can removed thereby resulting in a first a first sealing member of the first aseptic coupling device sealing with a second sealing member of the second aseptic coupling device to form a sterile fluid passageway.

Formation of a sterile connection includes inserting a first aseptic coupling device into a second aseptic coupling device while a locking ring of the first aseptic device is in an indexed initial position, rotating the locking ring to a secured position in which a compressive force is created and in which a first membrane from the first aseptic coupling device and a second membrane from the second aseptic coupling device can removed thereby resulting in a first a first sealing member of the first aseptic coupling device sealing with a second sealing member of the second aseptic coupling device to form a sterile fluid passageway.

A female coupling for a fluid quick connector and configured to be removably connected to a male coupling of the connector. The female coupling includes a valve assembly with a valve alternating between closed and open positions. The flow of a fluid from the female coupling towards the male coupling occurs in the open position. The female coupling includes a hollow body defining an inner cavity with a longitudinal axis for the flow of the fluid. The female valve assembly is housed in the inner cavity. The hollow body includes an end portion configured to be housed in a housing seat of an interface manifold. With the end portion in the housing seat, the tubular inner cavity is placed in fluid connection with at least one inner channel of the interface manifold. A constraint prevents rotation/translation of the end portion of the hollow body with respect to the housing seat.

This fluidic coupling (R) comprises a male element (A) comprising a male body (2), a valve (20) and a spring (24) pushing the valve (20) back toward its closed position, and a female element (B) having a sealing gasket (35), a piston (38), a slide valve (34) mounted around the piston (38) between a closed position, in which the sealing gasket (35) cooperates with the slide valve (34) and the slide valve (34) cooperates sealably with the piston (38), and a retracted open position. In a coupling phase, the male body (2) pushes the slide valve (34) back toward its open position and the piston (38) pushes the valve (20) back toward its open position. The piston (38) is mounted with the possibility of movement between a rear position and a forward position. The female element (B) comprises a lever (42) for converting the movement of the slide valve (34) into movement of the piston (38). During the coupling, from the closed position of the slide valve (34) to an offset position of the slide valve (34), in which the male body (2) cooperates with the sealing gasket (35) of the female body (26), the lever (42) is disengaged from the slide valve (34) and/or the piston (38), and the piston (38) is in the rear position. From the offset position of the slide valve (34) to the open position of the slide valve (34), the lever (42) is engaged with the slide valve (34) and with the piston (38), and moves the piston (38) toward its forward position. In the coupled configuration, the piston (38) is in its forward position and extends partially in the male body (2), a fluid passage being formed around the piston (38).

This fluidic coupling (R) comprises a male element (A) comprising a male body (2), a valve (20) and a spring (24) pushing the valve (20) back toward its closed position, and a female element (B) having a sealing gasket (35), a piston (38), a slide valve (34) mounted around the piston (38) between a closed position, in which the sealing gasket (35) cooperates with the slide valve (34) and the slide valve (34) cooperates sealably with the piston (38), and a retracted open position. In a coupling phase, the male body (2) pushes the slide valve (34) back toward its open position and the piston (38) pushes the valve (20) back toward its open position. The piston (38) is mounted with the possibility of movement between a rear position and a forward position. The female element (B) comprises a lever (42) for converting the movement of the slide valve (34) into movement of the piston (38). During the coupling, from the closed position of the slide valve (34) to an offset position of the slide valve (34), in which the male body (2) cooperates with the sealing gasket (35) of the female body (26), the lever (42) is disengaged from the slide valve (34) and/or the piston (38), and the piston (38) is in the rear position. From the offset position of the slide valve (34) to the open position of the slide valve (34), the lever (42) is engaged with the slide valve (34) and with the piston (38), and moves the piston (38) toward its forward position. In the coupled configuration, the piston (38) is in its forward position and extends partially in the male body (2), a fluid passage being formed around the piston (38).

The present invention relates to a hydraulic and/or pneumatic multi-coupler connector of the type comprising at least one pair of couplers inserted into a containment body and equipped with a lever actuated mechanism comprising an actuation lever maneuverable by the user for the relief of the residual pressure of the couplers and the connection thereof to corresponding male couplers.

A fluid coupling element has a body, a valve with a peripheral groove receiving a sealing gasket, a member for resiliently returning the valve, and a skirt positioned inside the body and movable between a first position axially freed relative to the gasket and a second position radially covering the gasket. The element has at least one hitching member axially secured to the skirt and radially movable between a first radial position for axially securing the skirt and the body and for relative axial movement of the valve relative to the skirt, and a second position for axially securing the skirt and the valve and for relative axial movement of the skirt and the body, in a configuration where the skirt covers the gasket.

A fluid coupling element has a body, a valve with a peripheral groove receiving a sealing gasket, a member for resiliently returning the valve, and a skirt positioned inside the body and movable between a first position axially freed relative to the gasket and a second position radially covering the gasket. The element has at least one hitching member axially secured to the skirt and radially movable between a first radial position for axially securing the skirt and the body and for relative axial movement of the valve relative to the skirt, and a second position for axially securing the skirt and the valve and for relative axial movement of the skirt and the body, in a configuration where the skirt covers the gasket.

The invention relates to a connector (10) for a fluid conduction system comprising: a female coupling part (12); a male coupling part (14) for inserting into the female coupling part (12) along a longitudinal axis (16) of the connector (10); and controlling means for locking/unlocking the inserted male coupling part (12) within the female coupling part (14) and for controlling the fluidic coupling of the two coupling parts (12, 14) by rotating said two coupling parts (12, 14) against one another about the longitudinal axis (16); wherein a portion of each of the coupling parts (12, 14) is realized as a shut-off valve (18, 24) with a valve body (20, 26) and a rotatable slider element (22, 28), wherein the rotatable slider element (22, 28) of each shut-off valve (18, 24) is in a compulsory closed position when the two coupling parts (12, 14) are unlocked; and wherein the rotatable slider element (22, 28) of each shut-off valve (18, 24) is transferable between the closed position and an open position only if the two coupling parts (12, 14) are locked by use of the controlling means. The invention further relates to a corresponding fluid conduction system.