A mechanical shutdown valve for preventing an over pressure condition is described. A valve body has an inlet, an outlet, and a channel extending from the inlet to the outlet. A valve seat and a diaphragm are positioned in the valve body. The diaphragm controls a fluid flow through the valve body. A mesh is coupled to the diaphragm such that the mesh and the diaphragm separate an upstream portion of the channel from a downstream portion of the channel. The mesh extends from the diaphragm to an inner surface of the valve body and limits fluid flow between the diaphragm and the valve body. A spring biases the diaphragm towards the open position. A characteristic of the spring determines a differential pressure threshold between the upstream portion of the channel and a downstream portion of the channel at which the diaphragm engages the valve seat.

It is provided a valve, particularly for a bowl and/or a bottle for receiving and/or mixing fluids, comprising a vent for injecting a fluid, wherein the vent comprises an inlet connected to a discharge opening via a discharge channel, a flexible diaphragm for covering the discharge opening of the vent, wherein the flexible diaphragm comprises a holding collar for receiving a measuring cylinder, particularly in a press-fitted manner, and a fastening means for loss-proof receiving the flexible diaphragm between the fastening means and the vent , wherein the fastening means is releasably connected to the vent, wherein the vent comprises a support collar supporting the holding collar, wherein the holding collar comprises a sealing rim protruding mainly radially outwards, wherein the sealing rim is arranged between the fastening means and the support collar and is in sealing contact to the fastening means.

It is provided a valve, particularly for a bowl and/or a bottle for receiving and/or mixing fluids, comprising a vent for injecting a fluid, wherein the vent comprises an inlet connected to a discharge opening via a discharge channel, a flexible diaphragm for covering the discharge opening of the vent, wherein the flexible diaphragm comprises a holding collar for receiving a measuring cylinder, particularly in a press-fitted manner, and a fastening means for loss-proof receiving the flexible diaphragm between the fastening means and the vent , wherein the fastening means is releasably connected to the vent, wherein the vent comprises a support collar supporting the holding collar, wherein the holding collar comprises a sealing rim protruding mainly radially outwards, wherein the sealing rim is arranged between the fastening means and the support collar and is in sealing contact to the fastening means.

A valve device includes: a body formed with a valve chamber, a first inflow passage, a second inflow passage, an outflow passage, and an annular groove and provided with a valve seat; and a diaphragm configured to communicate with and interrupt the second inflow passage and the outflow passage. An end portion of the second inflow passage is open to the valve chamber. The valve seat is provided on a peripheral edge of a location where the valve chamber and the second inflow passage communicate with each other. The annular groove is open to the valve chamber and is formed around the second inflow passage. An end portion of the outflow passage is open to the annular groove. The first inflow passage has a plurality of flow passages including an inflow port and a plurality of outflow ports, and each outflow port is open to the annular groove.

A valve device includes: a body formed with a valve chamber, a first inflow passage, a second inflow passage, an outflow passage, and an annular groove and provided with a valve seat; and a diaphragm configured to communicate with and interrupt the second inflow passage and the outflow passage. An end portion of the second inflow passage is open to the valve chamber. The valve seat is provided on a peripheral edge of a location where the valve chamber and the second inflow passage communicate with each other. The annular groove is open to the valve chamber and is formed around the second inflow passage. An end portion of the outflow passage is open to the annular groove. The first inflow passage has a plurality of flow passages including an inflow port and a plurality of outflow ports, and each outflow port is open to the annular groove.

A fluid shut-off device has a valve body delimiting an inlet duct and an outlet duct and having an intermediate portion delimiting an intermediate chamber that provides fluid connection between the inlet and outlet ducts. The inlet duct has an inlet duct connection edge. The intermediate chamber has a sealing surface and accommodates a diaphragm having a diaphragm sealing portion that in a closing position of the inlet duct, cooperates, by a diaphragm support surface, with the sealing surface to occlude the inlet duct. The diaphragm has a diaphragm bending portion permanently connecting the diaphragm sealing portion to the valve body to exclusively operate under bending. The diaphragm sealing portion delimits a diaphragm seat. A control element has a control stem with predetermined transverse control stem dimension and integrally received in the diaphragm seat, which transmits movement to the diaphragm sealing portion at least between the closing position and an opening position of the inlet duct.

A fluid shut-off device has a valve body delimiting an inlet duct and an outlet duct and having an intermediate portion delimiting an intermediate chamber that provides fluid connection between the inlet and outlet ducts. The inlet duct has an inlet duct connection edge. The intermediate chamber has a sealing surface and accommodates a diaphragm having a diaphragm sealing portion that in a closing position of the inlet duct, cooperates, by a diaphragm support surface, with the sealing surface to occlude the inlet duct. The diaphragm has a diaphragm bending portion permanently connecting the diaphragm sealing portion to the valve body to exclusively operate under bending. The diaphragm sealing portion delimits a diaphragm seat. A control element has a control stem with predetermined transverse control stem dimension and integrally received in the diaphragm seat, which transmits movement to the diaphragm sealing portion at least between the closing position and an opening position of the inlet duct.

A valve block includes a fluid-transfer plate with multiple inlet bores connecting to a common inlet channel, and multiple outlet bores connecting to a common outlet channel. The inlet bores and the outlet bores are arranged in a curved shape. The valve block also includes a pressure plate and diaphragm aligned and connected to the fluid-transfer plate in a way that allows pressurized material in the pressure plate to control the state of the channels formed by the inlet and outlet bores.

A valve block includes a fluid-transfer plate with multiple inlet bores connecting to a common inlet channel, and multiple outlet bores connecting to a common outlet channel. The inlet bores and the outlet bores are arranged in a curved shape. The valve block also includes a pressure plate and diaphragm aligned and connected to the fluid-transfer plate in a way that allows pressurized material in the pressure plate to control the state of the channels formed by the inlet and outlet bores.

A gas control device includes a pump, a valve, a cuff, and a controller. The valve includes a first plate having a first vent hole and a first vent hole, a channel forming plate having an exhaust hole and an exhaust channel, a second plate having a second vent hole, and an edge separation plate. A manchette rubber tube in the cuff is joined to the periphery of the second vent hole in the second plate by an adhesive, and thus the valve is connected to the cuff. The exhaust hole is opened to the atmosphere. The pump includes a pump housing having a discharge hole and a discharge hole. The upper surface of the pump housing is joined to the bottom surface of the edge separation plate.