RU2639987C2 - Plate assembly with lateral hole for fluid flow control device - Google Patents

Abstract

FIELD: machine engineering.SUBSTANCE: fluid flow control device comprises a valve body including an inlet, an outlet and a valve port disposed between the inlet and outlet and a drive mechanism. The drive mechanism is connected to the valve body to regulate the fluid flow from the inlet to the outlet through the valve port and is provided with a plate assembly and a membrane operatively connected with the plate assembly. The plate assembly is disposed in the valve body and is displaceable relative to the valve port in accordance with pressure changes sensed by the membrane. The plate assembly comprises a plate element, a plate holder, an outlet, a side channel and an annular groove formed in the plate holder. The discharge opening is formed in the first side of the plate holder along the central axis of the assembly. The annular groove is formed in the first side of the plate holder and is coaxial with the discharge opening to accommodate a portion of the ring plate element. The side channel is formed in the plate holder and provides communication between the discharge opening and the annular groove, so that during usage, the pumped fluid which is accumulated in the annular groove between the plate element and the plate holder can be discharged through the discharge opening through the side channel.EFFECT: reduction of wear and abrasion of the plate assembly.31 cl, 5 dwg

Description

FIELD OF TECHNOLOGY

[0001] The present invention relates to poppet assemblies for a fluid flow control device, and more particularly, to poppet assemblies of a control element for a fluid regulator.

BACKGROUND

[0002] The pressure at which typical gas distribution systems supply gas may vary depending on the requirements of the system, climate, power source, and / or other factors. However, most end-user installations equipped with gas appliances such as boilers, stoves, etc., require that the gas be supplied at a predetermined pressure and at or below the maximum functionality of the gas regulator. Thus, gas controllers are designed in these distribution systems to ensure that the gas supplied meets the requirements of end-user installations. Conventional gas regulators typically include a closed-loop control system for measuring and regulating the pressure of the supplied gas.

[0003] Various operating parameters, such as temperature and pressure, can adversely affect the overall service life of the components of the regulator, considered in any quantity. For example, as shown in FIG. 1, the controls for conventional controllers may typically comprise a poppet assembly 10 for opening and closing the control valve channel 20, thereby controlling the flow of gas supplied to a subsequent consumer. The conventional plate assembly 10 comprises a metal plate holder 12 that accommodates a rubber plate element 14 serving to provide a fluid tight seal with the control valve channel 20 in the closed position.

[0004] At high operating temperatures (eg, 80 ° C and above), conventional plate assemblies 10 may be more susceptible to wear and abrasion. For example, at elevated operating temperatures, the rubber plate element 14 may be more prone to physical deformation, especially at high pressures (for example, 150 psi and higher), while the steel plate holder 12 remains undeformed. As shown by the arrows in FIG. 1, it is possible that a pressurized fluid in this situation will penetrate into any gap 18 between the outer circumference of the plate element 14 and the inner wall of the plate holder 12. This pressure can ultimately build up behind the poppet 14. Therefore, when the poppet 10 opens and moves away from the valve channel 20, the accumulated pressure can at least partially displace the poppet 14 from its intended position. FIG. 2 illustrates one possible result with the lateral edge portion A of the poppet element 14 extruded from the tray holder 12 relative to the rest of the poppet element 14. This ultimately leads to the sealing surface of the poppet element 14 being angled relative to the valve channel 20, which may adversely affect the planned operation of the device.

SUMMARY OF THE INVENTION

[0005] One aspect of the present invention is a fluid flow control device comprising a valve body and a drive mechanism. The valve body has an inlet, outlet and valve channel located between the inlet and outlet. The drive mechanism is connected to the valve body to control the flow of fluid from the inlet to the outlet through the valve channel and is equipped with a poppet assembly and a membrane operably connected to the poppet assembly. The plate assembly is located in the valve body and is made with the possibility of displacement relative to the valve channel in accordance with the pressure changes perceived by the membrane. The plate assembly comprises an annular plate element, a cylindrical plate holder, an outlet, a circular groove and at least one side channel. The cylindrical plate holder has a first side facing the valve channel and a second side facing the valve channel. An outlet is made in the first side of the plate holder along its central axis. The annular groove is made in the first side of the plate holder and is located coaxially with the outlet, and accommodates at least a portion of the annular plate element. At least one side channel is provided in the plate holder and provides fluid communication between the outlet and the annular groove, so that any pumped fluid in the valve body that accumulates in the annular groove between the annular plate element and the plate holder can be discharged through outlet through the side channel.

[0006] Another aspect of the present invention is a tray assembly that includes an annular tray element, a cylindrical tray holder, a discharge opening, an annular groove, and at least one side channel. The cylindrical plate holder has a first side facing the valve channel and a second side facing the valve channel. An outlet is made in the first side of the plate holder along its central axis. The annular groove is made in the first side of the plate holder and is located coaxially with the outlet, and accommodates at least a portion of the annular plate element. At least one side channel is provided in the plate holder and provides fluid communication between the outlet and the annular groove, so that any pumped fluid in the valve body that accumulates in the annular groove between the annular plate element and the plate holder can be discharged through outlet through the side channel.

[0007] Another aspect of the present invention is a tray assembly for a fluid flow control device that includes a tray element, a tray holder, a groove and at least one fluid channel. The plate holder has a first side and a second side. The groove is made in the first side of the plate holder and accommodates at least a portion of the plate element. At least one fluid channel is provided in the plate holder and extends between the groove and the outer surface of the plate holder so that during use, a pumped fluid that builds up in the groove between the plate element and the plate holder can be discharged through the fluid channel.

BRIEF DESCRIPTION OF THE DRAWINGS

[0008] FIG. 1 is a cross-sectional side view of one conventional plate assembly located, for example, relative to a valve channel of a fluid regulator.

[0009] FIG. 2 is a perspective side view of a conventional plate assembly of FIG. 1 illustrating a plate element in a partially extruded state that may result from use under high temperature conditions.

[0010] FIG. 3 is a cross-sectional side view of one example of a fluid flow control apparatus comprising a plate assembly constructed in accordance with the principles of the present invention.

[0011] FIG. 4 is a cross-sectional side view of one example of a plate assembly of FIG. 3.

[0012] FIG. 5 is a cross-sectional side view of an alternative plate assembly constructed in accordance with the present invention.

DETAILED DESCRIPTION

[0013] The present invention is directed to a plate assembly and a fluid flow control device equipped with a plate assembly, the plate assembly being designed and configured to minimize and / or prevent pressure build-up behind the plate element in the plate holder. In one embodiment of the poppet assembly described below, this is accomplished by creating a poppet holder with a fluid channel (e.g., an outlet) that is in fluid communication with the rear side of the poppet. With this configuration, any pressure accumulated behind the plate element can be released through the fluid channel without displacing the plate element from its intended position relative to the plate holder.

[0014] With reference to the drawings, FIG. 3 depicts a gas regulator 100 constructed in accordance with one embodiment of the present invention. The gas regulator 100 generally comprises a drive mechanism 102 and a control valve 104. The control valve 104 comprises an inlet 106 for receiving gas from a gas distribution system, for example, and an outlet 108 for supplying gas to an object having, for example, one or more devices. The actuator 102 is connected to a control valve 104 and includes a control unit 122 having a control member 127 equipped with a poppet assembly 200 made in accordance with the present invention. During the first or normal operating mode, the control unit 122 determines the pressure at the outlet 108 of the control valve 104, i.e. the outlet pressure, through an external piping system, for example, and controls the position of the control element 127, so that the outlet pressure is approximately equal to the specified control pressure. In addition, in the event of a malfunction in the system, the controller 100 may perform the discharge function using an exhaust type safety valve 121, as is known in the art.

[0015] Continuing to refer to FIG. 3, the control valve 104 forms a tapered portion 110 and a valve mouth 112. The valve mouth 112 forms an opening 114 located along an axis that is generally perpendicular to the axis of the inlet 106 and the outlet 108. The tapered portion 110 is located between the inlet 106 and the outlet 108 and accommodates the valve channel 136. The valve channel 136 includes an input 150, an output 152, and an elongated hole 148 passing between the inlet 150 and the outlet 152. Gas must pass between the hole 148 in the valve channel 136 to pass between the inlet 106 and the outlet 108 of the control valve 104. In the illustrated embodiment, the inlet 150 further forms a seat ring 151, with which a tray assembly 200 from interaction control element 127 in the closed position. The poppet assembly 200, as shown, is mounted in the control valve 104 in a position between the outlet 108 and the valve channel 136 during operation of the device 100.

[0016] FIG. 4 shows the plate assembly 200 of FIG. 3 in more detail. The plate assembly 200 includes a plate element 202, a plate holder 204, and a pin 206, all of which are coaxially located on the center axis CA of the plate assembly 202. As shown, the plate element 202 comprises an annular plate element having a generally square or rectangular cross-sectional profile. The plate element 202 may be made of an elastomeric material, rubber, or any other material suitable for any given application. As shown, the poppet element 202 comprises a generally flat seating surface 208 that is configured to fit on the seat ring 151 of the valve channel 136 of the regulator 100, shown, for example, in FIG. 3. In the disclosed embodiment, the seating surface 208 and the seat ring 151 are located in parallel planes P1, P2, respectively, so that the seating surface 208 can provide a reliable seal with the seat ring 151. With this configuration, when the poppet element 202 is in the closed position shown in FIG. 4, parallel planes P1, P2 are coplanar.

[0017] With reference to FIG. 4, the plate holder 204 of the plate assembly 200 comprises a cylindrical element made of metal, such as, for example, stainless steel. As shown, the plate holder 204 includes a first side 210 facing the valve channel 136 of FIG. 4 and, more specifically, the inlet 150 of the valve channel 136, and the second side 212 facing away from the valve channel 136. The pin 206 of the poppet assembly 200 is attached to and protrudes from the second side 212 of the poppet holder 202 and, as shown in FIG. 3 is configured to couple to a control element 127 of a fluid flow control device.

[0018] The plate holder 204 further forms an outlet 214, an annular groove 216, and at least one side groove 218. In the disclosed example, the outlet 214 and the annular groove 216 are individually formed in the first side 210 of the plate holder 204. In another embodiment, the outlet 214 may be formed on the second side 212 of the plate holder 204, as will be described below. The annular groove 216 of the plate holder 204 in FIG. 4 has dimensions and is configured to accommodate at least a portion of the plate element 202, as shown. Accordingly, in said embodiment, the annular groove 216 includes a square or rectangular cross-sectional profile that resembles a square or rectangular cross-sectional profile of a plate element 202. More specifically, the cross-sectional profile of the annular groove 216 of FIG. 4 includes an inner cylindrical surface 217, an outer cylindrical surface 219, and a radial surface 221 extending between the inner and outer surfaces 217, 219. The radial surface 221 and, therefore, the annular groove 216 has a radial dimension R. Each of the inner and outer cylindrical surfaces 217, 219 and therefore the annular groove 216 have a dimension D in depth.

[0019] In the embodiment depicted in FIG. 4, the radial size R of the ring groove 216 may be slightly larger than the corresponding size of the plate element 202, while the depth dimension D of the ring groove 216 may be slightly smaller than the corresponding size of the plate element 202. This configuration facilitates the insertion of the plate element 202 into the ring groove 216 during assembly and at the same time opens a portion of the plate element 202 adjacent to the sealing surface 208 to expose the groove 216 from the outside. In such a configuration to help hold the plate element 20 2 in the annular groove 216, a binder or other fixing means may be used. In other examples, the cross-sectional profiles of the annular groove 216 and the plate element 202 may have the same dimensions. In the following examples, the radial dimension R of the cross-sectional profile of the annular groove 216 may be slightly smaller than the corresponding size of the plate element 202, thereby facilitating a friction fit with the plate element 202. Such a friction fit may further eliminate the use of a binder material or other holding means for holding plate element 202 in the annular groove 216.

[0020] As indicated, the plate holder 204 of the poppet assembly 200 disclosed here further comprises an outlet 214 and a side channel 218, which in combination may be referred to herein as a fluid channel. The outlet 214 includes a cylindrical blind hole made in the first side of the plate holder 204 at a location along the central axis CA of the poppet assembly 200 and has a depth dimension L that is larger than the depth dimension D of the annular groove 216. With this configuration, the annular groove 216 and the cymbal the element 202 of the previously specified plate assembly 200 surround at least a portion of the outlet 214, which is located next to the first side 210 of the plate holder 204.

[0021] The side channel 218 according to the present invention comprises a cylindrical through hole that provides fluid communication between the outlet 214 and the annular groove 216. As indicated, the branch channel 218 is formed in the plate holder 204 along the side axis BA, which is located at an angle α relative to the central axis CA of the plate assembly 200. In one example, the angle α may be approximately 40 °. However, the angle α of the side channel 218 may be, in general, any angle suitable for the intended purpose. For example, the angle α may be any angle between about 5 ° and about 90 °, or between about 30 ° and about 60 °.

[0022] As shown in FIG. 4, the side channel 218 according to a previously disclosed embodiment of the poppet assembly 200 includes a first end 230 in communication with the annular groove 216 and a second end 232 in communication with the outlet 214. The second end 232 of the side channel 218, as shown, simply punches or penetrates the side wall 235 of the outlet 214. The first end 230 intersects the annular groove 216 at the point where the inner cylindrical wall 217 intersects the radial wall 221 of the annular groove 216. Thus, the side channel 218 according to the disclosed wa The embodiment actually extends through or penetrates into the annular groove 216 in part of the inner cylindrical wall 217 and in the radial wall part 221 of the annular groove 216. In another example, however, the first end 230 of the side channel 218 can pass through or penetrate the annular groove 216, only through the radial wall 221 or only through the inner cylindrical wall 217.

[0023] As mentioned above, the poppet assembly 200 according to the present invention includes at least one side channel 218 extending between the annular groove 216 and the outlet 214. Thus, although in FIG. 4 shows only one side channel 218, an alternative embodiment of the poppet assembly 200 of FIG. 4 may have a plurality of side channels 218. Each of the plurality of side channels 218 may be substantially the same as the channel shown in FIG. 4 and spaced circumferentially around the outlet 214. In other embodiments, some of the plurality of side channels 218 may be made different from others. For example, one embodiment of the poppet assembly 200 may include a plurality of side channels 218 having first ends 230 pierce or pierce the annular groove 216 only through the radial wall 221, and another set of side channels 218 that pierce or penetrate the annular groove 216 only through the inner cylindrical wall 217. Naturally, other configurations may be used, and they are within the scope of the present invention.

[0024] Furthermore, although the outlet 214 of the embodiment of the poppet assembly 200 of FIG. 4 is described and depicted as being made in the first wall 210 of the plate holder 202, other variants of the plate assembly 200 may include an outlet 214 made in the second side 212 or even through the side wall of the perimeter of the plate holder 204. In one embodiment, made in accordance with an alternative embodiment and shown in FIG. 5, the outlet 214 may simply be a continuation of the side channel 218, so that the outlet 214 extends from the side channel 218 and the annular groove 216, still along the side axis BA, through the second side 212 of the plate holder 204, and finally outside the side wall of the pin 206, for example. In yet another embodiment of the plate assembly 200 shown in FIG. 5, the cymbal element 202 and the groove 216 may be cylindrical rather than annular since the outlet 214 is biased towards the second side 212 of the holder 204. Other options naturally should be within the scope of the present invention.

[0025] Regardless of which embodiment of the outlet 214 and / or side channel 218 is made, the poppet assembly 200 of the present invention is disposed and configured to discharge any fluid pressure that might otherwise accumulate in the annular groove 216 behind the poppet element 202. In particular, under various operating conditions, when the poppet assembly 200 is in a closed position, as indicated in FIG. 4, the inlet pressure of the fluid surrounding the poppet assembly 200 may penetrate into the poppet holder 204 between the poppet member and the outer cylindrical wall 219 of the annular groove 216. In some cases, this pressure may penetrate further between the poppet member 202 and the radial wall 217 of the annular groove 216 In the case where pressure penetration occurs, the fluid travels along the path of least resistance and naturally enters the side channel 218 and immediately into the outlet 214 where it can be discharged. 204 of the holder plate. Thus, it can be said that the side channel 218 and the outlet 214 in combination form a fluid channel formed in the plate holder 204 according to the present invention. This pressure relief function ensures that the plate element 202 is held securely in the annular groove 216 in the desired position and minimizes or eliminates the possibility that fluid pressure will force the plate element 202 out of the plate holder 204. This is particularly advantageous when used in the fluid regulator 100 of FIG. 3, under conditions of high pressure (for example, greater than or equal to 150 psi) and high temperature (for example, greater than or equal to 80 ° C).

[0026] For the sake of completeness, additional structural and functional details of the controller 100 of FIG. 3. As indicated, the controller 100 comprises a drive mechanism 102 and a control valve 104. The drive mechanism 102 comprises a housing 116 and a control unit 122. The housing 116 comprises an upper housing component 116a and a lower housing component 116b connected to each other, for example, by a plurality of fasteners. The lower housing component 116b forms the control cavity 118 and the mouth of the drive mechanism 120. The mouth of the actuator 120 is connected to the valve orifice 112 of the control valve 104 to provide fluid communication between the drive mechanism 102 and the control valve 104. The upper housing component 116a forms a discharge cavity 134 and the outlet channel 156. The upper housing component 116a further forms a vertical portion 158 for placing a portion of the control unit 122, as will be described later.

[0027] The control unit 122 comprises a membrane subassembly 121 and a control member 127. The membrane subassembly 121 mainly comprises a membrane 124, a plunger 132, and an adjustment spring 130. More specifically, the membrane 124 includes a plate membrane forming an opening 144 in its central portion. The membrane 124 is made of a flexible, essentially airtight material, and its edge is hermetically fixed between the upper and lower components 116a, 116b of the housing 116. Thus, the membrane 124 separates the discharge cavity 134 from the control cavity 118.

[0028] The plunger 132 according to the disclosed embodiment comprises a generally oblong rod-like member having a connecting device 135 that connects a portion of the plate sub-assembly 123 for attachment between the membrane sub-assembly 121 and the pop-up sub-assembly 123, as will be described.

[0029] The control spring 130 is located above the membrane 124 and inside the vertical portion 158 of the upper housing component 116a. The control spring seat 160 is screwed into the vertical portion 158 and compresses the control spring 130. In the disclosed embodiment, the control spring 130 comprises a compression coil spring. Accordingly, the control spring 130 is based on the upper housing component 116a and exerts a downward force on the membrane 124. In the disclosed embodiment, the force exerted by the control spring 130 is adjustable by adjusting the position of the control spring seat 160 in the vertical portion 158, and thus the control pressure of the regulator 100 is also adjustable.

[0030] The control spring 130 counteracts the pressure in the control cavity 118, which is perceived by the membrane 124. As already mentioned, this pressure is the same pressure as that which exists at the outlet 108 of the control valve 104. Accordingly, the force exerted by the control spring 130 sets an outlet pressure equal to the required or control pressure for the regulator 100. The diaphragm subunit 121 is operatively connected to the poppet subunit 123, as described above, by means of a connecting device 135.

[0031] In particular, the disk subassembly 123 includes a control lever 126 and a rod guide 162. The control lever 126 includes a stem 178, a lever 180, and a control member 127. The control element 127 of the disclosed embodiment includes a plate assembly 200, described in detail above.

[0032] The stem 178, the lever 180, and the poppet assembly 200 are made separately and assembled to form a control lever 126. In particular, the rod 178 is a conventional linear rod having a sock 178a and a groove 178b, which in the disclosed embodiment is, basically, rectangular. The lever 180 is a slightly curved rod and includes a support end 180a and a free end 180b. The supporting end 180a includes an opening 184 receiving a pivot pin 186 supported by a lower housing component 116b. The supporting end 180a also comprises a hinge 187 having an elliptical cross section and located in the groove 178b of the rod 178. The free end 180b extends between the upper part 135a and the lower part 135b of the connecting device 135 of the plunger 132. Thus, the connecting device 135 functionally connects the poppet node 123 with membrane unit 121.

[0033] The rod guide 162 comprises a substantially cylindrical outer portion 162a and a substantially cylindrical inner portion 162b. The outer part 162a of the rod guide 162 is dimensioned and can fit into the mouths 112, 120 of the control valve 104 and the lower housing component 116b without gap, respectively. The inner part 162b is made with dimensions and the possibility of sliding to hold the rod 178 of the control lever 126. Thus, the rod guide 162 serves to maintain the alignment of the control valve 104, the actuator housing 116 and the control unit 122, and more specifically, the rod 178 of the control lever 126 of the control unit 122.

[0034] FIG. 3 depicts a controller 100 according to the present invention with a poppet assembly 200 in a closed position. Thus, the poppet assembly 200 seals in a sealing manner with the seat ring 151 at the outlet 150 of the valve channel 136. With this configuration, the gas does not pass through the valve channel 136 and the control valve 104. This configuration is achieved because the outlet pressure, which corresponds to the pressure in the control cavity 118 housing 116 and is perceived by the membrane 124, more than the force exerted by the control spring 130. Accordingly, the output pressure presses the membrane 124, the plunger 132 and the poppet assembly 200 into the closed position. In this closed position, the pressure inside the control valve 104 surrounding the poppet assembly 200 may, under certain conditions, penetrate the poppet assembly 200, as described above, for example, with reference to FIG. 4. However, predominantly the outlet 214 and the side channel 218 guarantee that such pressure penetration will not adversely affect the design of the poppet assembly 200.

[0035] When commissioning a gas distribution system, for example, when a user starts a device, such as a boiler, stove, etc., the device takes a gas stream from the control cavity 118 of the regulator 100, thereby reducing the pressure that is perceived by the membrane 124. Because the pressure received by the membrane 124 drops, a static imbalance arises between the force of the control spring and the force of the output pressure on the membrane 124, so that the control spring 130 expands and moves the membrane 124 and the plunger 132 down relative to contact with the housing 116. This leads to the fact that the lever 180 rotates clockwise around the hinge pin 186, which, in turn, rotates the hinge 187 relative to the groove 178b in the rod 178. In this case, the rod 178 and the plate assembly 200 are moved from the seat ring 151 at the inlet 150 of the valve channel 136 to open the control valve 104.

[0036] A device arranged in this way can supply gas to the device after the regulator through the control valve 104 at a control pressure set by the control spring 130. In addition, the membrane subassembly 121 continues to sense the output pressure of the control valve 104. As long as the output pressure remains approximately equal to the control pressure, the control pressure 122 will hold the poppet assembly 200 in the same standard position. However, if the outlet pressure, i.e. the load decreases, thereby increasing the output pressure above the control pressure specified by the control spring 130, the membrane 124 senses the increased output pressure and moves upward against the preload of the control spring 130. Alternatively, if the output stream, i.e. the load increases, thereby lowering the output pressure below the control pressure, the membrane 124 senses a decrease in the output pressure, and the spring 130 pushes the membrane 124 and the plunger 132 down to open the control valve 104. Thus, small deviations from the output or control pressure lead to the response of block 122 control and regulation of the position of the plate assembly 200, respectively.

[0037] In view of the foregoing, the disclosed cymbal assembly 200 and the regulator 100 equipped with the cymbal assembly 200 can advantageously operate with a high degree of accuracy and extended service life under many operating conditions, including such high pressures and temperatures that could impair the integrity of the cymbal node of the prior art. A high degree of accuracy is achievable by eliminating any adverse effect of pressure buildup behind the plate element. This is further improved in that the plate element 202 according to the present invention is annular in shape, so that it has a smaller cross-sectional area than the conventional plate element shown in FIG. 1 and 2, for example. That is, instead of having a circular cross-sectional area, the surface of the plate element 202 according to the present invention, which faces the radial wall 221 of the groove 216 of the plate holder 204, is annular or ring-shaped. Such a smaller area reduces the available area that pressure buildup can act on, thereby also reducing its potential impact. Although the plate element 202 according to the present invention is described as ring-shaped, with slight modifications to the idea of depressurization disclosed herein, it may equally apply to cylindrical plate elements such as those disclosed in FIG. 1 and 2. For example, the embodiment depicted in FIG. 5 can be easily modified to include a cylindrical, as opposed to an annular, cymbal element.

[0038] The foregoing description is provided merely as an example of the invention and is not intended to limit the invention other than as defined in the following claims.

Claims (47)

1. A device for controlling the flow of fluid containing: a valve body including an inlet, an outlet and a valve channel located between the inlet and the outlet, and a drive mechanism connected to the valve body for regulating the flow of fluid from the inlet to the outlet through the valve channel and provided with a poppet assembly and a membrane operably connected to a poppet assembly located in the valve body and configured to bias relative to the valve duct in accordance with pressure changes, perceived by the membrane, while the plate assembly contains: ring plate element; a cylindrical plate holder having a first side facing the valve channel and a second side facing the valve channel, an outlet made in the first side of the plate holder along its central axis, an annular groove made in the first side of the plate holder, located coaxially with the outlet and accommodating at least a portion of the annular plate element, and at least one side channel formed in the plate holder and providing fluid communication between the outlet and the annular groove, so that any pumped fluid in the valve body that the annular groove between the annular plate element and the plate holder accumulates can be discharged through outlet through the side channel. 2. The device according to claim 1, in which the plate assembly is located in the valve body between the inlet and the valve channel. 3. The device according to p. 1 or 2, in which the outlet includes a blind hole, and the specified at least one side channel contains at least one through hole extending between the annular groove and the outlet. 4. The device according to any one of paragraphs. 1 or 2, in which at least one side channel extends at an angle relative to the central axis of the plate holder. 5. The device according to claim 4, in which the angle of the side channel is between about five degrees and about ninety degrees relative to the center axis of the plate. 6. The device according to claim 5, in which the angle of the side channel is between about thirty degrees and about sixty degrees relative to the center axis of the plate. 7. The device according to any one of paragraphs. 1 or 2, wherein at least one side channel includes a plurality of side channels. 8. The device according to any one of paragraphs. 1 or 2, in which the plate assembly further comprises a pin protruding from the second side of the plate holder and operably connected to the membrane. 9. The device according to any one of paragraphs. 1 or 2, in which the annular plate element includes an elastomeric material, and the plate holder includes a metal material. 10. The device according to any one of paragraphs. 1 or 2, in which the ring plate includes a rubber material, and the plate holder includes stainless steel. 11. A plate assembly for a fluid flow control device, comprising: ring plate element; a cylindrical plate holder having a first side and a second side; an outlet made in the first side of the plate holder along its central axis; an annular groove made in the first side of the cylindrical plate holder, located coaxially with the outlet and accommodating at least a portion of the annular plate element; and at least one lateral channel formed in the plate holder and providing fluid communication between the outlet and the annular groove, so that during use, a pumped fluid that accumulates in the annular groove between the annular plate element and the plate holder can be discharged through outlet through the side channel. 12. The node according to claim 11, in which the outlet includes a blind hole, and the specified at least one side channel contains at least one through hole extending between the annular groove and the outlet. 13. The node according to any one of paragraphs. 11 or 12, in which the side channel extends at an angle relative to the central axis of the plate holder. 14. The assembly of claim 13, wherein the angle of the side channel is between about five degrees and about ninety degrees relative to the center axis of the plate. 15. The assembly of claim 14, wherein the angle of the side channel is between about thirty degrees and about sixty degrees relative to the center axis of the plate. 16. The node according to any one of paragraphs. 11 or 12, wherein at least one side channel includes a plurality of side channels. 17. The node according to any one of paragraphs. 11 or 12, which further comprises a pin extending from the second side of the plate holder to connect to a drive assembly of the fluid flow control device. 18. The node according to any one of paragraphs. 11 or 12, in which the annular plate element includes an elastomeric material, and the plate holder includes a metal material. 19. The node according to any one of paragraphs. 11 or 12, wherein the annular plate includes rubber material and the plate holder includes stainless steel. 20. A plate assembly for a fluid flow control device, comprising: plate element; a plate holder having a first side and a second side; a groove made in the first side of the plate holder and containing at least a portion of the plate element; and at least one fluid channel formed in the plate holder and extending between the groove and the outer surface of the plate holder such that during use, a pumped fluid that builds up in the groove between the plate element and the plate holder can be discharged through the fluid channel . 21. The assembly of claim 20, wherein the fluid channel includes an outlet and a side channel fluidly connected to the outlet, the side channel extending from a groove provided in the plate holder to the outlet, and the outlet from the side channel and the outside of the outer surface of the plate holder. 22. The node according to any one of paragraphs. 20 or 21, wherein the fluid channel extends from the groove and outward of the first side of the plate holder. 23. The assembly of claim 21, wherein the outlet includes a blind hole that extends from the first side of the plate holder along the center axis of the assembly. 24. The assembly of claim 23, wherein the side channel includes a through hole that extends from the groove to the outlet at an angle with respect to the center axis of the assembly. 25. The assembly of claim 24, wherein the angle of the side channel is between about five degrees and about ninety degrees relative to the center axis of the plate. 26. The assembly of claim 25, wherein the angle of the side channel is between about thirty degrees and about sixty degrees relative to the center axis of the plate. 27. The node according to any one of paragraphs. 20 or 21, wherein at least one fluid channel includes a plurality of fluid channels. 28. The node according to any one of paragraphs. 20 or 21, which further comprises a pin extending from the second side of the tray holder to connect to a drive assembly of the fluid flow control device. 29. The node according to any one of paragraphs. 20 or 21, in which the plate element includes an elastomeric material, and the plate holder includes a metal material. 30. The node according to any one of paragraphs. 20 or 21, wherein the plate includes rubber material and the plate holder includes stainless steel. 31. The node according to any one of paragraphs. 20 or 21, in which the plate element is an annular plate element, and the groove in the plate holder is an annular groove.

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