Disclosed herein are embodiments of a sanitary fitting for coupling a fluid conduit to a flexible container to facilitate sterile transfer therebetween, and methods of making and using such a sanitary fitting, whereby the sanitary fitting includes a first annular member having a first annular member bore extending between first annular member first and second ends, the first annular member second end terminating in a flange radially outwardly extending therefrom, the flange comprising a substantially planar face; a second annular member having a second annular member bore extending between second annular member first and second ends, the second annular member couplable to the first annular member to axially align the first and second annular member bores to provide a first fluid flow passageway; and a valve coupled to the second annular member, the valve operable to interrupt fluid flow through a fluid flow path which includes the first fluid flow passageway.

Disclosed herein are embodiments of a sanitary fitting for coupling a fluid conduit to a flexible container to facilitate sterile transfer therebetween, and methods of making and using such a sanitary fitting, whereby the sanitary fitting includes a first annular member having a first annular member bore extending between first annular member first and second ends, the first annular member second end terminating in a flange radially outwardly extending therefrom, the flange comprising a substantially planar face; a second annular member having a second annular member bore extending between second annular member first and second ends, the second annular member couplable to the first annular member to axially align the first and second annular member bores to provide a first fluid flow passageway; and a valve coupled to the second annular member, the valve operable to interrupt fluid flow through a fluid flow path which includes the first fluid flow passageway.

A system includes a flow control assembly having a first portion configured to be positioned within and coupled to a first passageway formed in a wellhead component and a second portion configured to be coupled to a second passageway formed in a body that is configured to be coupled to the wellhead component. An actuator of the second portion is configured to drive a valve member of the first portion into an open position to enable fluid flow across the flow control assembly.

A system includes a flow control assembly having a first portion configured to be positioned within and coupled to a first passageway formed in a wellhead component and a second portion configured to be coupled to a second passageway formed in a body that is configured to be coupled to the wellhead component. An actuator of the second portion is configured to drive a valve member of the first portion into an open position to enable fluid flow across the flow control assembly.

The invention relates to a connection fitting (102) for a valve coupling and/or measuring or test coupling (2) for fluid systems for detecting working pressures of fluid media, the coupling (2) comprising a coupling bushing (6) which is subject to operating pressure in the installed state and which has a connection part (16) and a borehole (10) in which a spring-loaded and mechanically actuatable non-return valve (32) is arranged, the valve body (18) of which, in the non-actuated state, is supported on a valve seat (52), the connection fitting (102) having an opening pin (114) having a more particularly circular, closed contact surface for the valve (32) and at least one passage (118) extending laterally to the contact surface, through which passage a connection can be established between the connection fitting (102) and the valve coupling and/or measuring or test coupling (2).

The invention relates to a connection fitting (102) for a valve coupling and/or measuring or test coupling (2) for fluid systems for detecting working pressures of fluid media, the coupling (2) comprising a coupling bushing (6) which is subject to operating pressure in the installed state and which has a connection part (16) and a borehole (10) in which a spring-loaded and mechanically actuatable non-return valve (32) is arranged, the valve body (18) of which, in the non-actuated state, is supported on a valve seat (52), the connection fitting (102) having an opening pin (114) having a more particularly circular, closed contact surface for the valve (32) and at least one passage (118) extending laterally to the contact surface, through which passage a connection can be established between the connection fitting (102) and the valve coupling and/or measuring or test coupling (2).

A coupling for use with comestible products having a first body with a first flow path extending therethrough and a second body with a second flow path extending therethrough. The first and second bodies are configured for coupling together such that the first and second flow paths form a continuous flow path through the coupling. The coupling further comprises a first valve member actuable between an open position, wherein product can pass through the first flow path, and a closed position, wherein the passage of product through the first flow path is prevented, and a first biasing member for biasing the first valve member into the closed position. The coupling is configured such that, if the first and second bodies become decoupled from one another, the first valve member is moved into the closed position. The first biasing member is isolated from the flow path passing through the coupling.

A coupling for use with comestible products having a first body with a first flow path extending therethrough and a second body with a second flow path extending therethrough. The first and second bodies are configured for coupling together such that the first and second flow paths form a continuous flow path through the coupling. The coupling further comprises a first valve member actuable between an open position, wherein product can pass through the first flow path, and a closed position, wherein the passage of product through the first flow path is prevented, and a first biasing member for biasing the first valve member into the closed position. The coupling is configured such that, if the first and second bodies become decoupled from one another, the first valve member is moved into the closed position. The first biasing member is isolated from the flow path passing through the coupling.

The connection assembly (100) which includes a flange (140) has two internal orifices (150) crossing through and centered on orifice axes (A150) parallel to each other, a front surface (142) and a rear surface (144) parallel to a transverse plane (P140) transverse to the orifice axes (A150), two fluidic coupling elements (170), that have a male body (172) received in a corresponding internal orifice, and a cover (120), configured for being attached to a support (110) in a mounted configuration of the connection assembly. The flange can move with respect to the cover according to a movement supported by the transverse plane, whereas for each male body, a second gasket (188) is interposed radially between the male body and an internal radial surface (S162) of the corresponding internal orifice, each male body being mounted in the corresponding internal orifice and can be tilted with respect to the corresponding orifice axis.

The connection assembly (100) which includes a flange (140) has two internal orifices (150) crossing through and centered on orifice axes (A150) parallel to each other, a front surface (142) and a rear surface (144) parallel to a transverse plane (P140) transverse to the orifice axes (A150), two fluidic coupling elements (170), that have a male body (172) received in a corresponding internal orifice, and a cover (120), configured for being attached to a support (110) in a mounted configuration of the connection assembly. The flange can move with respect to the cover according to a movement supported by the transverse plane, whereas for each male body, a second gasket (188) is interposed radially between the male body and an internal radial surface (S162) of the corresponding internal orifice, each male body being mounted in the corresponding internal orifice and can be tilted with respect to the corresponding orifice axis.