A valve block for a piggable and/or solid-state conducting line system of a process technical plant can include one or more rotary control valves. The rotary control valve(s) can include one or more line inputs, one or more line outputs, and a rotatable control member with one or more through-channels. In an open position, a line input of the one or more line inputs is connected to a line output of the one or more line outputs through a through-channel of the one or more through-channels. In a closed position, the first control member separates the one or more line inputs from the one or more line outputs. The rotary control valves are rotatable about a same rotation axis and the control members are non-rotatably connected to each other. The one or more through-channels of respective rotary control valves are offset plane-parallel relative to each other in an axial direction of the rotation axis.

A valve arrangement including a sealing element is provided. The valve arrangement includes a housing having a port. A rotary valve body includes an opening, and the rotary valve body is arranged within the housing. The port of the housing and the opening of the rotary valve body are alignable with each other via rotation of the rotary valve body in the housing. A sealing element is arranged within the port. The sealing element includes a seal body having a first axial end engaged against the rotary valve body and a second axial end including a resilient axially compressible portion that engages against a seat in the housing. The resilient axially compressible portion of the sealing element preloads the sealing element axially against the rotary valve body.

A valve arrangement including a sealing element is provided. The valve arrangement includes a housing having a port. A rotary valve body includes an opening, and the rotary valve body is arranged within the housing. The port of the housing and the opening of the rotary valve body are alignable with each other via rotation of the rotary valve body in the housing. A sealing element is arranged within the port. The sealing element includes a seal body having a first axial end engaged against the rotary valve body and a second axial end including a resilient axially compressible portion that engages against a seat in the housing. The resilient axially compressible portion of the sealing element preloads the sealing element axially against the rotary valve body.

An apparatus includes a valve yoke comprising a hollow inner portion and an upper face, an adapter plate including a through-hole and a lower face, wherein the lower face provides an interface for connection to the upper face of the valve yoke, an actuator assembly having an exterior profile, wherein the actuator assembly is removably retained within the hollow inner portion, and a drive screw retained between the actuator assembly and the adapter plate. The drive screw is rotatable within the through-hole along an axis of rotation. The axis of rotation is parallel to an axis of reciprocation. The actuator assembly comprises a first axial cam and a first indexing pin rotatably driven by the drive screw to follow the first axial cam.

Valve with multi-piece stator assembly for use with liquid chromatography or other analytical systems. A separate and removable stator plate is provided with a mounting device to provide a multi-piece stator assembly. The mounting device is adapted on one side to engage and contact the stator plate, and on the other side includes a plurality of ports for fluidic connections which are in fluid communication with fluid passageways in the stator plate. By making the stator face a separate component, the overall costs of the valve can be reduced, different materials can be used for the mounting device and the stator, and the valve can be used for ultra-high pressure applications, including in liquid chromatography and other analytical instrument systems.

A ball valve is provided. The ball valve includes at least one load varying mechanism provided in the static body assembly. The load varying mechanism includes a biasing member pressing one of the ball seat seals against the outer surface of the ball of the ball valve with a variable sealing load force applied on the ball, toward the ball and coaxial with the direction of the fluid. The load varying mechanism also includes a movable member operatively connected to a cam and to the biasing member, a rotation of the cam translating the movable member coaxially to the direction of the fluid, in order to variably load the biasing member toward or away from the ball, based on the different positions of the ball.

A ball valve is provided. The ball valve includes at least one load varying mechanism provided in the static body assembly. The load varying mechanism includes a biasing member pressing one of the ball seat seals against the outer surface of the ball of the ball valve with a variable sealing load force applied on the ball, toward the ball and coaxial with the direction of the fluid. The load varying mechanism also includes a movable member operatively connected to a cam and to the biasing member, a rotation of the cam translating the movable member coaxially to the direction of the fluid, in order to variably load the biasing member toward or away from the ball, based on the different positions of the ball.

A valve arrangement including a sealing element is provided. The valve arrangement includes a housing having a port. A rotary valve body includes an opening, and the rotary valve body is arranged within the housing. The port of the housing and the opening of the rotary valve body are alignable with each other via rotation of the rotary valve body in the housing. A sealing element is arranged within the port. The sealing element includes a seal body having a first axial end engaged against the rotary valve body and a second axial end including a resilient axially compressible portion that engages against a seat in the housing. The resilient axially compressible portion of the sealing element preloads the sealing element axially against the rotary valve body.

A valve arrangement including a sealing element is provided. The valve arrangement includes a housing having a port. A rotary valve body includes an opening, and the rotary valve body is arranged within the housing. The port of the housing and the opening of the rotary valve body are alignable with each other via rotation of the rotary valve body in the housing. A sealing element is arranged within the port. The sealing element includes a seal body having a first axial end engaged against the rotary valve body and a second axial end including a resilient axially compressible portion that engages against a seat in the housing. The resilient axially compressible portion of the sealing element preloads the sealing element axially against the rotary valve body.

A ball valve is provided. The ball valve includes at least one load varying mechanism provided in the static body assembly. The load varying mechanism includes a biasing member pressing one of the ball seat seals against the outer surface of the ball of the ball valve with a variable sealing load force applied on the ball, toward the ball and coaxial with the direction of the fluid. The load varying mechanism also includes a movable member operatively connected to a cam and to the biasing member, a rotation of the cam translating the movable member coaxially to the direction of the fluid, in order to variably load the biasing member toward or away from the ball, based on the different positions of the ball.