A spring return cartridge for a rotary actuated valve includes a torsion spring having a spring-loaded intermediate portion extending between first and second end portions and a spring carrier sleeved with the torsion spring. The spring carrier includes a first portion rotationally fixed with the first end portion of the torsion spring, and a second portion rotatably coupled with the second end portion of the torsion spring, such that the second end portion of the torsion spring is rotatable with respect to the spring carrier, and with respect to the first end portion of the torsion spring, between first and second rotational limit positions, with the intermediate portion of the torsion spring biasing the torsion spring second end portion to the first rotational limit position and maintaining a spring-loaded condition in the first rotational limit position.

A sealing assembly for controlling a flow of fluid through a fluid line has a housing having a first end opposite a second end with a hollow interior extending therebetween and an elastically resilient plug disposed within the hollow interior of the housing. The plug has a body engagable with a seat within the housing and a tension member having a first end connected to the body and a second end connected to the housing. The tension member is pre-loaded in tension to urge the body of the plug against the seat to seal the hollow interior of the housing. The body is movable away from the seat when the plug is acted upon by a fluid pressure greater than a pre-load force of the tension member.

The present invention provides a coupling device for coupling a rotary actuator to a mechanical device having a rotatable shaft. The coupling device comprises a spring return module with a first rotatable coupling configured to engage a first portion of the shaft, and a spring engaged with the first rotatable coupling, wherein the first rotatable coupling is rotatable about a rotation axis, and wherein rotation of the rotatable coupling about the rotation axis in a first direction causes mechanical energy to be stored in the spring. The coupling device further comprises an actuator coupling module comprising a second rotatable coupling. The second rotatable coupling is configured to engage a second portion of the shaft, the second rotatable coupling being further engageable with an output of the rotary actuator. The second rotatable coupling is rotatable about the rotation axis, the second rotatable coupling being rotatable relative to the first rotatable coupling about the rotation axis.

Valve components positioned in fluid connector assemblies, including universal fluid connector assemblies, are shown. A valve component is designed to open or close based on fluid pressure from a medical fluid applied to the valve component. Normally, when no force is acting on the valve component, the valve component is in an open position and portions of the valve components are spaced apart by a threshold force, thus forming a valve chamber. However, in an exemplary embodiment, when an applied force by the medical fluid is at least at the threshold force, the portions of the valve component contact each other and the valve component transitions to a closed position, thereby preventing the medical fluid from passing through the valve component, and accordingly, preventing the medical fluid from passing through the fluid connector assembly.

Disclosed is an electro-hydraulic relay valve and corresponding valve assembly for a SAHR brake. First actuators are arranged to act on a first end of a floating valve spool and second actuators are arranged to act on a second end of the valve spool. One of the second actuators can receive hydraulic pressure from a pilot valve. In a first valve position, the pressure supply port communicates with the working port and the tank port is closed. In a second valve position, the pressure supply port is closed and communicates via a first sense line with one of the first actuators, the working port directs pressure to the tank port, the tank port communicates via a second sense line with another of the first actuators, and the working port communicates via a third sense line with one of the second actuators. In a central position, all three ports are closed.

A valve spring is provided. The valve spring may include a first turn. The first turn of the valve spring may be disposed at a first angular orientation. The valve spring may further include a second turn. The second turn may be disposed at a second angular orientation. The second angular orientation may be different from the first angular orientation.

A valve assembly has a housing and a poppet-carrying portion. The housing includes an inlet port, an outlet port, an opening, and a assembly portion including helical grooves. The poppet-carrying portion is configured to be inserted through the opening and engage with the assembly portion. The poppet-carrying portion comprises a poppet head, a closure including protruding arms, convolutions, and a stopping portion. The convolutions extend between the poppet head and the closure and provide compliance such that the poppet head is movable relative to the closure. The stopping portion extends from the closure toward the poppet head and is spaced apart from the poppet head by a maximum compression distance. At a first fluid pressure, the protruding arms engage with the helical grooves, and the poppet head is positioned in a pre-load position that prevents the fluid from discharging through the outlet port.

A valve assembly includes a valve body defining an interior cavity extending to a bonnet portion, a valve stem including a valve element retained in the interior cavity of the valve body and an end portion extending beyond the bonnet portion, the valve stem being rotatable between first and second limit positions, and a spring return handle arrangement. The spring return handle arrangement includes a user graspable valve handle, a stem adapter, and a return spring. The stem adapter includes a first end portion secured to the valve stem and a second end portion secured to the valve handle. The return spring includes a first end portion secured to the valve body, an intermediate spring loaded portion, and a second end portion secured to the stem adapter to apply a torsional load to the stem adapter for returning the valve stem to the first rotational limit position.

A spring valve configured to provide automated movement of the control lever thereof so as to return the control lever to the first position. The spring valve includes a body having a first end and a second end configured to be releasably secured to pipes. The body has movably coupled thereto a control lever that is configured to be moved between a first position and a second position. The control lever is operably controlled with a torsion spring that is operably coupled therewith. The torsion spring includes a first end that is operably coupled to a spring end engagement member formed on the body. The second end of the torsion spring is operably coupled to control lever. Control lever includes tab member formed on the lower portion of the control member. The torsion spring is operable to apply torque to the control lever to return to its first position.

A valve assembly (300) comprising a valve body (302) and a mono-material plunger (304). The valve body (302 has a primary opening (314) and a secondary opening (315) that are axially spaced apart. The plunger (304) comprises a primary seal 5 portion (316) and a secondary seal portion (317). The plunger (304) comprises the following operational positions with respect to the valve body: a transit seal position in which the primary seal portion (316) of the plunger (304) is in contact with the valve body (302) in order to occlude the primary opening (314); and a fluid flow position in which the plunger (304) is maintained in the fluid flow position by an external force 10 and a force caused by a pressure differential across the valve assembly (300).