Abstract: A hydraulic restrictor comprising: a passage along which hydraulic fluid flows; a member which extends along said passage, said member restricting the flow along the passage; and means for selectively securing said member at a plurality of different positions along the passage thereby to enable variation in the restriction on flow along the passage, said securing means securing said member at each said position by securing the member against the side wall of the passage.

Abstract: The force feedback poppet valve includes a valve body having a main chamber, a first port, and a second port. The force feedback poppet valve further includes a main poppet disposed within the main chamber and movable between an open position and a closed position to control fluid flow between the first port and the second port. The main poppet forms a control chamber within the main chamber. The force feedback poppet valve further includes a first passage communicating the control chamber with the second port, a second passage communicating the control chamber with the first port, and a pilot valve having a pilot poppet for controlling fluid flow between the control chamber and the first port through the second passage. The force feedback poppet valve further includes a pressure compensator disposed within the main poppet, and fluidly connected to the second port via the first passage.

Abstract: The invention provides valves of the type employing a differential pressure regulator and a characterized valve with a mechanism to enhance control of fluid flow independently of system pressure. The valves of the invention are especially suitable for HVAC applications, and provide operation with improved accuracy over a greater flow range with a reduced risk of hunting. In one preferred aspect, the invention provides improvements by the employment in the differential pressure regulator of a diaphragm with a cup arranged to provide a small leakage, thereby dampening the response of the regulator. In another aspect, a baffle is provided to protect the downstream side of a control disk forming part of the differential pressure regulator.

Abstract: A constant flow valve is provided including a housing having a central flow passageway. The housing further includes an inlet portion, a cylindrical body portion, a frusto-conical valve portion, and an outlet portion. An obstruction plate is positioned within the housing so as to be longitudinally moveable upon a guide rod. The obstruction plate is biased by a spring for biasing the obstruction plate axially towards the inlet portion and away from the frusto-conical valve portion. The spring exerts a force against air flowing into the inlet and through the central flow passageway so as to maintain a constant flow rate due to increased pressure differential causing the obstruction plate to move axially into the frusto-conical valve portion. Preferably, the constant flow valve includes means for adjusting the biasing means.

Abstract: A flow regulator including a body that includes a first flow passageway and a second flow passageway, and a deformable blocking element disposed in the body, the deformable blocking element deforming due to pressure of fluid flow thereagainst, wherein the deformable blocking element is arranged to variably block the first flow passageway in accordance with its deforming due to pressure of fluid flow thereagainst, and wherein the deformable blocking element does not block fluid flow through the second flow passageway.

Abstract: An apparatus for preparing a beverage provided with a storage tank, a heater and a three-way valve. The three-way valve is provided with in inlet, a first outlet and a second outlet. The three-way valve is provided with a first member which is freely movable between a first and second extreme position wherein the first member can move under the influence of the liquid flow from the inlet to the first outlet and/or the second outlet from the first extreme position towards the second extreme position and in the second extreme position closes off the first outlet so that the liquid flow then extends from the inlet to the second outlet.

Abstract: A method and apparatus are provided for monitoring a liquid level in a closed tank with a differential pressure sensor module disposed in a bottom portion of the tank, by routing a pressure reference tube extending from the pressure sensor module through the interior of the tank and attaching an opposite, open, vented end of the pressure reference tube to the tank at a point inside of the tank in an upper portion of the tank.

Abstract: In one embodiment, a flow control valve includes a valve body having an inlet, an outlet, a flow passageway coupling the inlet to the outlet, and a cavity with first and second chambers. The valve further includes a hollow piston disposed in the first chamber and a seal separating the first and second chambers. The seal has a section within the piston that is exposed to the fluid in the first chamber. The section of the seal defines a first effective area. The valve also includes a biasing member configured to urge the piston, and a reference pressure passageway in fluid communication with the inlet and the second chamber. The valve can further include a piston seat that has a second inner effective area at least approximately equal to the first inner effective area.

Abstract: In a flow control valve, a spool is fitted into a cylindrical body including an input port and an output port. A spring is disposed between the spool and a flow rate setting plug at an end of the cylindrical body. A flow bypass communicating with the input port and the output port is provided on an outer peripheral portion of the cylindrical body. When a quantity of a fluid flowing through the flow control valve is reduced, the fluid flowing through the flow bypass compensates the reduction thereof. Accordingly, it is possible to maintain a constant flow rate.

Abstract: A proportional, pilot-operated flow control valve is disclosed which can include a cage, a hollow compensating spool slidably disposed within the cage, a hollow metering guide member slidably disposed within the compensating spool, a regulating spool slidably disposed within the guide member, a dampening guide slidably disposed inside the compensating spool to define a dampening chamber, a compensating spring disposed inside the dampening chamber and arranged to urge the dampening guide to engage the metering guide and the compensating spool to engage the cage, a regulating spring disposed inside the regulating spool and urging the regulating spool to abut the dampening guide, and a cartridge, the cartridge having a pilot valve assembly and an adaptor, the adaptor mounted to the cage, the pilot valve assembly mounted to the adaptor, the pilot valve assembly including an actuator.

Abstract: In one embodiment, a flow control valve includes a valve body having an inlet, an outlet, a flow passageway coupling the inlet to the outlet, and a cavity with first and second chambers. The valve further includes a hollow piston disposed in the first chamber and a seal separating the first and second chambers. The seal has a section within the piston that is exposed to the fluid in the first chamber. The section of the seal defines a first effective area. The valve also includes a biasing member configured to urge the piston, and a reference pressure passageway in fluid communication with the inlet and the second chamber. The valve can further include a piston seat that has a second inner effective area at least approximately equal to the first inner effective area.

Abstract: A flow regulator particularly for sub-sea chemical injection at low continuous rates includes a piston moveable in response to differential pressure and controlling via a lever connection an inlet valve. The differential pressure is balanced by a dual rate spring assembly which is positionally adjustable by means of a screw-threaded adjusting rod.

Abstract: In one embodiment, a flow control valve includes a valve body having an inlet, an outlet, a flow passageway coupling the inlet to the outlet, and a cavity with first and second chambers. The valve further includes a hollow piston disposed in the first chamber and a seal separating the first and second chambers. The seal has a section within the piston that is exposed to the fluid in the first chamber. The section of the seal defines a first effective area. The valve also includes a biasing member configured to urge the piston, and a reference pressure passageway in fluid communication with the inlet and the second chamber. The valve can further include a piston seat that has a second inner effective area at least approximately equal to the first inner effective area.

Abstract: Simple APCV, ADPCV and PICV's are provided. The APCV's are referenced to the atmosphere and control the gauge pressure, either upstream or downstream. The ADPCV's are the same as the APCV's, differing in that they are not referenced to the atmosphere. They are instead referenced to a second point in the fluid flow system and control the differential pressure. The PICV's are control valves connected in series with ADPCV's and control the fluid flow rate through the valve independently of variations in the line pressure. A preferred APCV has a valve body (1) with connections for a single-phase fluid line and a flow passage between the inlet (2) and the outlet (3) of said fluid line, with an opening having a defined seat orifice (7) intersecting the flow passage. A moveable assembly, comprising a disk (5) or cup is connected to a pressure sensing member (4), having essentially the same effective surface area.

Abstract: A constant flow valve not allowing a controlled fluid to remain standing in it and not contacting the controlled fluid except at diaphragms, enabling simple adjustment of differential pressure, and good in response, including a valve body, a valve action chamber and connecting channel formed at the valve body, a valve mechanism attached to the valve action chamber, and a restrictor provided at the connecting channel, wherein the valve action chamber is formed with a primary side fluid inlet port, valve seat, outlet port to the connecting channel, inlet port from the connecting channel, and secondary side fluid outlet port and wherein the valve mechanism is provided with a first diaphragm, a second diaphragm, and a third diaphragm moving together with a valve element, and a constant flow mixing method for effectively mixing a plurality of fluids using such constant flow valves.

Abstract: A pneumatic valve, includes a housing having first and second ports for entry and exit of an operating gas, a main connection line for linking the ports, and a cross bore intersecting the main connection line. A throttle includes a control element which is received in the cross bore and has a control opening with an effective area which progressively decreases from a first end position to a second end position, as the control element moves in a direction toward the second end position, whereby a counterforce is provided to oppose this movement of the control element. Disposed in the main connection line in series with the throttle is a flow orifice, wherein a gas pressure differential upstream and downstream of the flow orifice, as viewed in movement direction of the control element, is utilized to control the effective area of the control opening.

Abstract: The present invention relates to a regulating valve for regulating and automatically controlling a fluid for a constant flow, comprising a valve body, a valve stem in the body, a pressure difference transducer, a first clack, and a second clack whose main body is a sleeve. At the outside of the sleeve are provided two concentric projects and guiding ribs perpendicular to the projects. The invention, compared to the prior art, has advantages of good performance and reliability, simple and compact structure. The regulating valve according to the invention can automatically regulated with an electric actuator or a pneumatic actuator.

Abstract: According to one aspect of the invention, a fluid regulating control valve includes a housing having an upstream region and a downstream region and having a control orifice formed therein adjacent the downstream region and a piston slidably disposed within the housing. The piston has a fluid passage defining an intermediate region disposed between the upstream region and the downstream region and an edge adjacent the downstream region. The valve also includes an elastic member disposed within the housing for opposing translation of the piston within the housing and a throttling element adjacent the upstream region. The throttling element has a throttling surface adjacent the edge of the piston, in which the throttling surface and the edge define a throttling orifice therebetween.

Abstract: Quantity of fluid can be more precisely controlled without disassembling the valve by an automatic flow control valve, which can be quietly operated and repaired and maintained in simple and easy manner. In the control valve, a valve body has a fluid channel and a chamber, which are formed in the valve body and communicate with each other. A diaphragm is disposed in the chamber and has a fluid channel switching shaft connected to one surface thereof. A flow control member is assembled with the valve body and extends toward the fluid channel. A fluid transfer hole communicating with an entrance port is formed at an upper portion of a side surface of the chamber, so that an opening degree of the fluid channel can be automatically controlled by the fluid channel switching shaft connected with the diaphragm when the diaphragm is operated by pressure of the fluid transferred through the fluid transfer hole.

Abstract: According to one aspect of the invention, a fluid regulating control valve includes a housing having an upstream region and a downstream region and having a control orifice formed therein adjacent the downstream region and a piston slidably disposed within the housing. The piston has a fluid passage defining an intermediate region disposed between the upstream region and the downstream region and an edge adjacent the downstream region. The valve also includes an elastic member disposed within the housing for opposing translation of the piston within the housing and a throttling element adjacent the upstream region. The throttling element has a throttling surface adjacent the edge of the piston, in which the throttling surface and the edge define a throttling orifice therebetween.

Abstract: The invention relates to a variable flow regulator adopted to provide accurate flow rates at low flow and ultra low flow rates. The regulator comprises a wide-range flow regulator for low fluids flow, comprising a housing divided into a first and second chambers by means of an elastic diaphragm. The chamber is provided with a fluid inlet and an outlet connected to a labyrinth path.

Abstract: A constant flow valve not allowing a controlled fluid to remain standing in it and not contacting the controlled fluid except at diaphragms, enabling simple adjustment of differential pressure, and good in response, including a valve body, a valve action chamber and connecting channel formed at the valve body, a valve mechanism attached to the valve action chamber, and a restrictor provided at the connecting channel, wherein the valve action chamber is formed with a primary side fluid inlet port, valve seat, outlet port to the connecting channel, inlet port from the connecting channel, and secondary side fluid outlet port and wherein the valve mechanism is provided with a first diaphragm, a second diaphragm, and a third diaphragm moving together with a valve element, and a constant flow mixing method for effectively mixing a plurality of fluids using such constant flow valves.

Abstract: The invention relates to a metering unit for metering liquid and/or gaseous educts by means of a feed pump for a fuel cell system. The metering unit includes at least one lead line (16) for delivering an educt flow, at least one control piston (12), and a differential pressure valve (14) for regulating the educt flow; the differential pressure valve (14) has a regulatable throttling cross section (39), which is variable automatically, as a function of a flow pressure dictated by the control piston (12), in order to regulate the educt flow. The lead line (16) leads to the control piston (12), and between the control piston (12) and the differential pressure valve (14) a first and a second connecting line (28, 29) are provided.

Abstract: Quantity of fluid can be more precisely controlled without disassembling the valve by an automatic flow control valve, which can be quietly operated and repaired and maintained in simple and easy manner. In the control valve, a valve body has a fluid channel and a chamber, which are formed in the valve body and communicate with each other. A diaphragm is disposed in the chamber and has a fluid channel switching shaft connected to one surface thereof. A flow control member is assembled with the valve body and extends toward the fluid channel. A fluid transfer hole communicating with an entrance port is formed at an upper portion of a side surface of the chamber, so that an opening degree of the fluid channel can be automatically controlled by the fluid channel switching shaft connected with the diaphragm when the diaphragm is operated by pressure of the fluid transferred through the fluid transfer hole.

Abstract: A flow regulator particularly for sub-sea chemical injection at low continuous rates includes a piston moveable in response to differential pressure and controlling via a lever connection an inlet valve. The differential pressure is balanced by a dual rate spring assembly which is positionally adjustable by means of a screw-threaded adjusting rod.

Abstract: A pneumatic valve, includes a housing having first and second ports for entry and exit of an operating gas, a main connection line for linking the ports, and a cross bore intersecting the main connection line. A throttle includes a control element which is received in the cross bore and has a control opening with an effective area which progressively decreases from a first end position to a second end position, as the control element moves in a direction toward the second end position, whereby a counterforce is provided to oppose this movement of the control element. Disposed in the main connection line in series with the throttle is a flow orifice, wherein a gas pressure differential upstream and downstream of the flow orifice, as viewed in movement direction of the control element, is utilized to control the effective area of the control opening.

Abstract: A fluid flow regulator in which fluid is passed through an impeller chamber having a pressure differential-operated impeller piston for monitoring changing inlet and outlet fluid pressures to maintain a constant fluid flow rate. A needle valve mounted on the body at one end of the impeller chamber engages an orifice opening to precisely change the fluid flow rate.

Abstract: A flow regulator for a water pump, comprising a control valve. The control valve is mounted on an inlet pipe of a water pump and has a chamber, housing a flat-shaped control plate, the upper part of which forms a piston plate, vertically gliding in an upper chamber. The upper chamber is connected with an outlet pipe. The control valve is exposed to water pressure in the outlet pipe, with the control plate driven downward by the water pressure, countered by two springs at two lateral sides of the control plate. The control plate thus has a varying vertical position according to the water pressure.

Abstract: A pressure compensating flow control device is disclosed which has a needle valve/spring assembly as a reference restriction which is in axial alignment with a reducing valve situated in a housing of the device. A piston and piston rod is provided in axial alignment with the needle valve and reducing valve to provide compensation for alterations to pressure differential about the piston. The piston rod has an internal channel to allow for fluid communication between inlet and outlet chambers and to allow for passive control of pressure differential. The device provides pressure control for low fluid flows and low pressures.

Abstract: A controller for controlling a medium flow fed from a supply to at least one hydrostatic or aerostatic pocket of a bearing, a threaded spindle nut or a guide, having a housing and having pressure chambers which are separated by a control element, movable against the force of a spring element, and of which a first pressure chamber, subjected to a first pressure level, is directly connected to the medium supply, a second pressure chamber, subjected to a lower, second pressure level, is connected to the medium supply via a first flow resistance, and a third pressure chamber, which is subjected to a third pressure level which corresponds to that in the pocket, is connected to the pocket, a control element forming a variable second flow resistance is arranged between the second and third pressure chambers influencing the medium flow to the pocket and whose magnitude is raised by the action of the force of the first pressure chamber but is lowered by the action of the spring force and by the actions of the forces o

Abstract: A flow regulator for a water pump, working in conjunction with a water pump, having a pump, an inlet pipe, an outlet pipe with a water pressure, and a container. The flow regulator comprises: a main body, installed at the inlet pipe and having a passageway for water flowing through the inlet pipe; a chamber inside the main body; an entrance on the main body, conducting the water pressure in the outlet pipe to the chamber; a control element, mounted inside the chamber and glidingly movable therein back and forth; a spring; and an adjustable cover, mounted on the main body and connected to the spring. The water pressure causes the control element to move within the chamber, resulting in the passageway to be narrowed. The spring counters the water pressure, such that when the water pressure decreases the passageway is widened. By varying the position of the adjustable cover, the elastic force of the spring is adjusted.

Abstract: An automatic regulating valve apparatus comprises a main valve unit, and a pilot valve unit operatively connected to the main valve unit to control the main valve unit. The main valve unit comprises a main valve casing, a main valve element disposed in the main valve casing, and a main valve driving member disposed in the main valve casing together with the main valve element and having a pressure receiving area greater than that of the main valve element, the main valve element is disposed on the upstream side of a valve seat so as to form a restricting passage between the main valve element and the main valve seat, and the main valve driving member is disposed for sliding movement in a space defined by a cylindrical wall formed in the main valve casing so as to define a main valve driving pressure chamber together with the cylindrical wall.

Abstract: A fluid flow regulator of a type having a variable outlet defined by a spacing between an outlet aperture and a flexible diaphragm, and in which the position of the flexible diaphragm varies as a function of a pressure differential between a sensing chamber on a first side of the diaphragm and an outlet chamber on a second side of the diaphragm. The regulator includes an adjustable flow impedance configuration in the flow path from the sensing chamber to the outlet chamber has a two elements providing opposing cylindrical surfaces in sliding contact. One of the cylindrical surfaces has a groove configured to define a flow-attenuating passageway having a net flow vector substantially parallel to the axis of the cylindrical surfaces. Axial relative movement between the elements causes a variation in an extent of overlap between the cylindrical surfaces, thereby varying an operative length of the flow-attenuating passageway.

Abstract: A flow-rate controller comprises hollow casing 1, main 2 and additional 3 outlet branch pipes, and outlet branch pipe 4. Piston-type slide valve 13 with skirt 14 is located between front 5 and rear 10 guide bushes. The starting fuel component flows through the controller via branch pipe 3, hole 22, inlet space 7, holes 24 and 23, passage space 8, outlet orifices 11 and outlet branch pipe 4. It is followed by the main fuel component supplied to the system through the controller via branch pipe 2, open nonreturn pressure control valve 27, open front orifices 9, passage space 8, outlet orifices 11 and outlet branch pipe 4. Constant rates of flow of both the starting and the main fuel components through the controller are assured by the aforesaid original design slide valve and by the corresponding channels.

Abstract: The invention pertains to a regulator for regulating a medium flow to at least one hydrostatic or aerostatic pocket of a bearing, a nut for threaded spindles or a guidance from a medium supply, with pressure chambers that are separated by a variable flow resistance control element that can be moved against the force of a spring element. A first pressure chamber is directly connected to the medium supply, a second pressure chamber that is charged with a lower pressure level is connected to the medium supply via a first flow resistance, and a third pressure chamber is charged with a third pressure level that corresponds to the pressure in the hydrostatic or aerostatic pocket.

Abstract: The present invention provides adjustable flow control valves 10 for controlling flow of a fluid from a fluid supply. The valves of the present invention can accurately regulate a wide range of flow rates and require a relatively small amount of torque to adjust the flow rate of the valve during operation. The valves of the present invention include a flow control component 12 and a pressure control component 14. The adjustable flow control valves of the present invention are capable of accurately regulating a wide range of fluid flow rates. The valves of the present invention possess a very high turndown ratio, preferably up to about 200:1.

Abstract: A hydraulic valve with a housing, having an inlet connection and an outlet connection with a hollow space between them, in which a valve slide is arranged to reciprocate, and, depending on its position, sets a flow cross section between the inlet connection and the outlet connection more or less free. In such a valve it is intended to improve the operational behaviour, that is, on the one hand to prevent a jamming and on the other hand to keep the leakage small. For this purpose, the valve slide is surrounded by a bush, which is arranged to be radially expandable in the hollow space.

Abstract: A bi-directional flow control valve includes a two-port housing, and a hollow cage within the housing. The hollow cage has rows of cross-sectional holes that communicate with the ports. A hollow compensating spool is slidably arranged within the hollow cage between the cross-sectional holes. Pressure differential between the ports induces movement in the compensating spool. This movement causes the compensating spool to reduce the opening of one row of cross-sectional holes and increase the opening of the other. In this manner, the valve provides consistent flow control characteristics in each flow direction.

Abstract: There is provided a liquid flow regulator, having a split housing (2) including an upper portion (4) connectable to a source of liquid to be dispensed, the upper portion having an inlet port (10) and a lower portion engaging the upper portion and having a control output port leading to the consumer of the liquid, an elastically deformable diaphragm (32) disposed in the housing (2) and defining with a bottom surface of the upper housing portion a first chamber (34), and with a bottom surface of the lower housing portion in which the output control port (24) is made, an output control chamber (36), and a tubular flow attenuator (42) disposed in the housing (2), forming a liquid flow path between the first chamber (34) and the control chamber (36), characterized in that the thickness of the diaphragm (32) is at least equal to the distance between the diaphragm (32) in its state of rest and the output control port (24).

Abstract: A flow regulator is provided which comprises a housing defining a chamber therein and including inlet and outlet ports that are adaptable to allow fluid to flow into and out of the chamber. A piston assembly, including an orifice defining member in which is formed an orifice, is movably disposed in the chamber and is capable of moving in directions toward and away from the outlet port. An urging device, such as a spring, magnetic or electromagnetic device, urges the piston assembly away from the outlet port. As fluid flows into the flow regulator, the fluid flows through the orifice. The clearance between a control surface of the piston assembly and the outlet port automatically adjusts so that an equilibrium condition occurs in the flow regulator in which the difference between the pressure of the fluid upstream of the orifice and the pressure of the fluid downstream of the orifice is maintained essentially constant.

Abstract: The invention pertains to a regulator for regulating a medium flow to at least one hydrostatic or aerostatic pocket of a bearing, a nut for threaded spindles or a guidance from a medium supply, with pressure chambers that are separated by a variable flow resistance control element that can be moved against the force of a spring element. A first pressure chamber is directly connected to the medium supply, a second pressure chamber that is charged with a lower pressure level is connected to the medium supply via a first flow resistance, and a third pressure chamber is charged with a third pressure level that corresponds to the pressure in the hydrostatic or aerostatic pocket.

Abstract: A 2-way fitted valve (2) includes a main piston (6) guided in a valve bush (4) and allowing flow of a hydraulic fluid therethrough, whereby an inlet port (B) is connected with an outlet port (A). In the region of a throttle point (8) of the main piston (6) an effective surface (D-d) is provided, so that due to the pressure drop at the throttle point (8) a pressure force acts on the main piston (6) such as to urge it in the direction towards its home position.

Abstract: A flow control valve has two successively arranged throttle locations. The first throttle location serves as an adjusting member for the through-flow. The second throttle location controls the pressure difference across the first throttle location to a constant value. The first throttle location is formed by a control member (4) which co-operates with a first valve seat (5) of a valve insert (7) which is fixedly connected to the valve housing (6). The second throttle location is formed by a pressure regulating member (9) which co-operates with a second valve seat (10) of the valve insert (7). The control member (4) and the pressure regulating member (9) are displaceable in an identical direction (12) and connected by means of a resilient diaphragm (13). The inlet chamber (1) is communicated with a pressure chamber (15) which acts on the diaphragm (13) and on the pressure regulating member (9). The operative surface which transmits the pressure (p.sub.

Abstract: A flow regulator having a first and second stages of regulation. The first stage is a pressure regulation stage that maintains the pressure within an intermediate chamber (formed by a series of interconnected passageways and cavities) within a predetermined range above the pressure in an outlet port. The second stage maintains the flow rate within a predetermined range about a target flow rate. Both stages sample the pressure in the outlet port and automatically adjust the flow of fluid to ensure that fluctuations in pressure at the inlet and outlet ports do not affect the flow rate. The flow rate is set and controlled by a piston and valve arrangement. The pressure is regulated by a similar piston and valve arrangement. A flexible membrane is used to allow pressures in one chamber to be transferred into a control signal that operates a control valve in another chamber.

Abstract: Disclosed is a 2-way flow control valve whereby a constant hydraulic fluid volume flow may be adjusted by serial arrangement of a restrictor orifice and a control orifice. In the case of a reverse flow through the flow control valve of the present invention, a check actuating element of the flow control valve may be displaced against the bias of its own check spring in such a way that a bypass channel which bypasses the restrictor orifice can be controlled open.

Abstract: An I.V. Flow Controller incorporating an adjustable, differential pressure regulator that provides a constant but adjustable differential pressure across a fixed orifice. One end of the adjustment range provides shut-off and the other end full-flow. The adjustment range covers flow rates from zero to 250 ml/hr. At a given setting, the flow rate is independent of the total hydrostatic head height between the supply reservoir and a patient, provided the head height is greater than the pressure drop across the orifice at the maximum regulated flow rate, plus venous pressure, plus the pressure drop in the indwelling catheter.

Abstract: A first pressure chamber and a second pressure chamber are provided with means for continuously exerting a constant inward pressure on a first diaphragm part and a third diaphragm part respectively. A valve chamber having a flow control portion wherein a flow rate of the controlled fluid flowing from an inflow chamber to an outflow chamber is controlled by changing a size of the opening defined between a valve part and a valve seat, caused by a displacement of the valve part of a valve mechanism. A differential pressure chamber connects with the outflow chamber and has a bypass opening of a bypass passage connecting to the outflow passage.

Abstract: A low flow, high pressure fluid regulator in which fluid is passed successively through two impeller chambers, each having a pressure differential operated impeller for monitoring changing inlet and outlet fluid pressures to maintain a constant fluid flow rate. The impeller in the second impeller chamber limits the pressure drop of fluid discharged from the first impeller chamber.

Abstract: A valve comprises a valve body having an inlet and an outlet defining a flow passage through the valve body. A piston is mounted in a bore intersecting the flow passage and the piston divides the bore into first and second chambers. The piston remains substantially motionless during upstream pressure fluctuations after the desired fluid flow rate through the valve has been established. A reference pressure passage communicates with the inlet and the first chamber of the bore. Springs in the second chamber bias the piston against the fluid pressure from the first chamber. A sleeve on the piston is configured to variably sheath a cover over the outlet such that reciprocation of the piston during initiation of fluid flow through the valve varies the effective area of openings in the cover to achieve the desired differential pressure across the flow control throttle, thus setting the flow rate constant unless the throttle position is changed.

Abstract: An electrically controlled flow regulator valve assembly having a diaphragm operated pressure regulator valve with a solenoid operated valve for by-passing the diaphragm to control flow to the regulator valving chamber. In one embodiment the regulator valving chamber communicates through a small restricting orifice with a closed dampening chamber. In another embodiment a second closed dampening chamber is formed to communicate through a second small restrictive orifice with a chamber on the inlet pressure side of the diaphragm.