A flow control valve uses two ceramic members having conforming surfaces which are coupled together to form a fluid-tight seal, and slidable relative to each other to control fluid flow. Elongated obround apertures in the members mate to each other to form a fluid path which is wholly contained within the ceramic members. The members slide along the elongated dimension of the obround apertures between a closed position and controllable open positions where the obround apertures overlap creating an obround flow path of a controlled size. The shaping of the first and second apertures and their interaction when the valve is opened and closed permits fine control of the flow of fluid through the apertures under controlled sliding movement of the ceramic members relative to each other.

A flow control valve uses two ceramic members having conforming surfaces which are coupled together to form a fluid-tight seal, and slidable relative to each other to control fluid flow. Elongated obround apertures in the members mate to each other to form a fluid path which is wholly contained within the ceramic members. The members slide along the elongated dimension of the obround apertures between a closed position and controllable open positions where the obround apertures overlap creating an obround flow path of a controlled size. The shaping of the first and second apertures and their interaction when the valve is opened and closed permits fine control of the flow of fluid through the apertures under controlled sliding movement of the ceramic members relative to each other.

A valve and method for flow control of dry materials comprising large hard particles. Providing clearance at the valve seat of at least slightly greater than the nominal diameter of the hard particles prevents capture of the hard particles between closing parts of the valve, which can damage the valve due to the hardness of the particle material. Clearance space as defined unexpectedly does not allow the particles to pass through when the valve closure member is positioned across the valve seat in a closed position.

Disclosed is a vacuum valve with a sensor arrangement having at least one inertial sensor, where the sensor arrangement is designed in such a way it detects a measuring signal with respect to an acceleration impacting on the valve.

Disclosed is a vacuum valve having a valve seat, which has a valve opening, defining an opening axis, and a first sealing surface, a valve closure having a second sealing surface corresponding to the first sealing surface, a drive unit coupled to the valve closure, which can be moved from an open position, in which the valve closure and the valve seat do not contact each other, to a closed position, in which there is a sealing contact between the first sealing surface and the second sealing surface by a seal there between, and the valve opening is sealed gastight as a result. The vacuum valve has at least one temperature sensor, where the temperature sensor is designed and arranged such that, from the temperature sensor, a measurement signal representing thermal information in respect of at least one part of the vacuum valve can be detected.

The sliding parts, the guides and interlocking portions of the interlocking guides and slides of a slide valve are all disposed away from a flow path through the valve. Additionally, the portions of the interlocking guide on the slide or disc of the valve that interlock with the guide on an orifice plate are connected to the slide or disc by welds instead of bolts, greatly increasing durability. As the slide or disc moves in and out to control the flow rate precisely, the guides of the slide or disc move with it. Because the sliding surfaces of the orifice plate and the slide or disc are outside of the flow path, they are consequently not subjected to erosion from the flow through the valve. Accordingly, all critical sliding surfaces are not exposed to the flow path and are greatly increased in durability.

An embodiment includes a gate valve comprising: a valve body including a cavity coupled to a channel having proximal and distal portions; a gate to seal and unseal the channel; proximal and distal seats adjacent the gate; wherein (a) the proximal seat traverses towards the gate and stops at a first position when the gate is closing and the proximal channel portion is more highly pressurized than the cavity, and (b) the distal seat slides away from the gate and stops at a second position when the gate is closing and the cavity is more heavily pressurized than the distal channel portion. Other embodiments are described herein.

A plant or refinery may include equipment such as condensers, regenerators, distillation columns, pumps, slide valves, or the like. Different operating methods may impact deterioration in equipment condition, thereby prolonging equipment life, extending production operating time, or providing other benefits. Mechanical or digital sensors may be used for monitoring equipment to determine whether problems are developing. Specifically, sensors may be used in conjunction with one or more system components to predict and detect slide valve sticking. An operating condition of the plant or refinery may be adjusted to prolong equipment life or avoid equipment failure.

A valve for controlling the flow of a solid material from an opening includes a gate having a first face adjacent the opening, a second face opposite the first, and an orifice. A support is disposed adjacent the second face of the gate and is configured so that the gate can move relative to the support from a first position permitting the material to flow from the opening through the orifice and a second position preventing the material from flowing through the opening. The support is movable in a direction substantially orthogonal to the first direction so that the distance from the first face to the opening can be varied.

Disclosed is a vacuum valve including a valve closure and a preferably pneumatic or electro-pneumatic drive unit having a pressure medium, said drive unit being coupled to the valve closure. The vacuum valve also has a pressure sensor such that a pressure of the pressure medium can be measured.