The present disclosure generally relates to fluid control devices such as fluid regulators, and more particularly, to the configuration and assembly of a control member for a fluid control device.
Fluid control devices are used in variety of systems (e.g., natural gas delivery systems, chemical treatment systems, etc.) to control the flow of a fluid therethrough. Fluid control devices encompass various categories of equipment including control valves and regulators. In general, fluid control devices have a fluid flow path and a control member for adjusting a dimension of the fluid flow path.
The control member 32 is configured to reciprocate between an open position and a closed position in response to changes in pressure across the diaphragm 30. In the open position (not illustrated), the control member 32 is spaced apart from the valve seat ring 22, thereby allowing fluid to flow through the throat 20. In the closed position (illustrated in
The regulator assembly 10 includes a coil spring 34 that biases the control member 32 to the open position. When the outlet pressure of the valve body 12 is low, the coil spring 34 moves the control member 32 to the open position. By contrast, when the outlet pressure of the valve body 12 is high, the pressure exerted against the diaphragm 30 overcomes the biasing force of the coil spring 34, thereby moving the control member 32 to the closed position. Due to this arrangement of the coil spring 34, the regulator 10 is generally classified as a “fail-open” regulator. Other regulators are configured as “fail-closed” regulators, where the spring that biases the control member to the closed position.
As depicted in
Conventional control members typically have a bottom surface that is planar across its entire width. Therefore, as depicted in
The present disclosure sets forth fluid control devices and methods of assembling such devices embodying advantageous alternatives to existing fluid control devices and existing methods of assembly, and that may address one or more of the challenges or needs mentioned above, as well as provide other benefits and advantages.
In accordance with a first exemplary aspect, a fluid control device includes a valve body, a valve seat, an actuator casing, a control member, a biasing member, a valve stem, and a connection member. The valve body defines a flow path for a fluid. The valve seat may be disposed in the valve body along the flow path. The actuator casing may be connected to the valve body. The control member may be disposed in the valve body and movable between an open position in which the control member is spaced apart from the valve seat and a closed position in which the control member engages the valve seat. The connection member may be mounted around the valve stem and engaging a bottom surface of the control member. A through-bore may be formed in the bottom surface of the control member and aligned with the longitudinal axis. The through-bore may receive the valve stem. A first counter-bore may be formed in the bottom surface of the control member and aligned with the longitudinal axis. Additionally, the first counter-bore may receive the connection member.
In accordance with a second exemplary aspect, a control member for a gas regulator is provided. The control member may have a valve body defining a flow path for a fluid, a valve seat disposed in the valve body along the flow path, an actuator casing connected to the valve body, a biasing member disposed in the actuator casing and configured to bias the control member to a closed position or an open position, a valve stem connected between the biasing member and the valve seat, and a nut threadably engaging the valve stem. The control member may include a top surface configured to engage the valve seat when the control member is arranged in the closed position, and a bottom surface configured to engage the nut. A through-bore may be formed in the bottom surface of the control member and configured to receive the valve stem. A first counter-bore may be formed in the bottom surface of the control member and configured to receive the nut. Additionally, the first counter-bore may be aligned with the through-bore. Furthermore, a depth of the first counter-bore may be greater than or equal to a thickness of the nut so that the nut does not protrude from the first counter-bore when the nut engages the bottom surface of the control member.
In accordance with a third exemplary aspect, a method of assembling a gas regulator is provided. The method may include: (a) providing a biasing spring, a nut, a valve stem having a threaded end portion, and a control member having a through-bore and a first counter-bore aligned with the through-bore; (b) inserting the valve stem through the biasing spring and through the through-bore of the control member until the threaded end portion of the valve stem is disposed in the first counter-bore of the control member; and (c) rotating the nut about the threaded end portion of the valve stem so that the nut is threadably advanced along the threaded end portion of the valve stem and into engagement with a bottom surface of the control member.
In further accordance with any one or more of the foregoing first, second or third aspects, a fluid control device, a control member, and/or a method of assembling a gas regulator may further include any one or more of the following preferred forms.
In one preferred form, a thickness of the connection member may be less than or equal to a depth of the first counter-bore such that the connection member does not protrude from the first counter-bore.
In one preferred form, the connection member may have a first diameter, and the first counter-bore may have a second diameter, wherein the second diameter is greater than first diameter.
In one preferred form, the through-bore may have a third diameter which is less than the first diameter and the second diameter.
In one preferred form, the bottom surface of the control member may include a second counter-bore aligned with the longitudinal axis, and the second counter-bore may have a fourth diameter which is greater than the second diameter.
In one preferred form, the control member may include a top surface configured to engage the valve seat when the control member is arranged in the closed position.
In one preferred form, a diaphragm may be disposed in the actuator casing and operatively connected to the control member to move the control member in response to changes in an outlet pressure of the fluid control device.
In one preferred form, the connection member may have a threaded inner surface, and the valve stem may have a threaded outer surface, wherein the connection member may be tightened against the bottom surface of the control member by rotating the threaded inner surface of the connection member about the threaded outer surface of the valve stem.
In one preferred form, the biasing member may be configured to bias the control member to the open position.
In one preferred form, the first counter-bore may have a larger diameter than the through-bore.
In one preferred form, a second counter-bore may be formed in the bottom surface such that the first counter-bore is arranged between the through-bore and the second counter-bore, wherein the second counter-bore may have a larger diameter than the first counter-bore.
In one preferred form, the top surface of the control member may be planar.
In one preferred form, the bottom surface may include a first planar section and a second planar section, the first counter-bore may extend between the first planar section and the second planar section, and the first planar section may be configured to engage the nut when the nut is received in the first counter-bore.
In one preferred form, the depth of the first counter-bore may be equal to the thickness of the nut so that an end surface of the nut is level with the second planar section of the bottom surface when the nut is received in the first counter-bore and engages the first planar section of the bottom surface of the control member.
In one preferred form, a depth of the first counter-bore may be greater than or equal to a thickness of the nut so that the nut does not protrude from the first counter-bore when the nut arranged against the bottom surface of the control member.
In one preferred form, the control member may include a second counter-bore aligned with the first counter-bore, wherein the second counter-bore may have a larger diameter than the first counter-bore.
In one preferred form, the bottom surface of the control member may include a first planar section and a second planar section, and the first counter-bore may extend between the first planar section and the second planar section.
In one preferred form, a depth of the first counter-bore may be equal to a thickness of the nut, and wherein rotating the nut about the threaded end portion of the valve stem may comprise threadably advancing the nut along the threaded end portion of the valve stem and into engagement with the first planar section of the bottom surface of the control member, such that an end surface of the nut is level with the second planar section of the bottom surface of the control member.
It is believed that the disclosure will be more fully understood from the following description taken in conjunction with the accompanying drawings. Some of the figures may have been simplified by the omission of selected elements for the purpose of more clearly showing other elements. Such omissions of elements in some figures are not necessarily indicative of the presence or absence of particular elements in any of the exemplary embodiments, except as may be explicitly delineated in the corresponding written description. None of the drawings are necessarily to scale.
The present disclosure is generally directed to a control member, as used in fluid control devices (e.g., control valves, regulators, etc.), that provides increased stability, particularly during low fluid flow conditions. The control member includes a recess (e.g., a counter-bore) for receiving a connection member, such as a retaining nut, that couples the control member to a valve stem. By concealing the connection member partially, or completely, in the recess of the control member, the connection member is less likely to influence the fluid flow around the control member. Accordingly, a pressure differential between opposite sides of the control member is less likely to exist, or may even be eliminated. Therefore, as compared to conventional control members, which have an exposed and protruding connection member, the control member of the present disclosure is less likely to settle into a pattern of high frequency oscillations and thereby facilitates a stable output pressure of the fluid control device.
With reference to
Still referring to
In addition to the control assembly 116, the actuator 114 may include an actuator casing 130 having an upper portion 132 and a lower portion 134, as depicted in
Additionally, the actuator 114 may include a diaphragm assembly 150 including at least a flexible diaphragm 152, an upper diaphragm plate 154, and a lower diaphragm plate 156. As illustrated in
Still referring to
The lower end 180 of the valve stem 170 may include a second annular protrusion 186 distal to the terminal portion of the lower end 180 and a second threaded end portion 188 proximate to the terminal portion of the lower end 180. As discussed below in more detail, the second connection member 176, which in the present embodiment takes the form of a retaining nut having a threaded inner surface, may be rotated about the second threaded end portion 188 to fixedly connect the control member 172 to the lower end 180 of the valve stem 170, between the second annular protrusion 186 and the second connection member 176.
As shown in
Referring to
The control member 172 may also have a bottom surface 192 located on a side of the control member 172 opposite to the top surface 190. In some embodiments, the top surface 190 and the bottom surface 192 may be opposite axial end surfaces. As illustrated in
The through-bore 198 may extend through the entirety of the control member 172 and thus extend between the bottom surface 192 and the top surface 190. At one end, the through-bore 198 may open into the first counter-bore 194, and at an opposite end, the through-bore 198 may open into the portion of the throat 126 immediately adjacent to the top surface 190 of the control member 172. The through-bore 198 may have an inner diameter D2 which is greater than or equal to an outer diameter D3 of the valve stem 170, so that the valve stem 170 can be inserted through the through-bore 198 during assembly.
Still referring to
The first counter-bore 194 may be sized and dimensioned to receive the second connection member 176. Accordingly, the first counter-bore 194 may have an inner diameter D4 which is greater than or equal to the outer diameter D1 of the second connection member 176. Furthermore, the first counter-bore 194 may have a depth X1 which is greater than or equal to the thickness T of the connection member 176. In an embodiment where the depth X1 of the first counter-bore 194 is equal to the thickness T of the second connection member 176, the axial end surface 189 of the second connection member 176 may be level with the second planar section 202 of the bottom surface 192 of the control member 172 when the axial end surface 187 engages the first planar section 200 of the bottom surface 192 of the control member 172, as illustrated in
Since the second connection member 176 does not protrude outwardly from the control member 172, the second connection member 176 is less likely to interfere with the flow of fluid around the control member 172 during operation. Accordingly, it is less likely that a difference in fluid pressure will exist between the top surface 190 and the bottom surface 192 of the control member 172. Thus, unlike a conventional control member (see, e.g., the control member 32 of
Referring to
In the illustrated embodiments, the first counter-bore 194 and the second counter-bore 196, and the through-bore 198 each have a circular cross-section. However, other cross-sections are possible, including a polygonal cross-section, an oval cross-section, or any other suitable cross-section.
During assembly, with the upper portion 132 of the actuator casing 130 removed from the lower portion 134 of the actuator casing 130, the valve stem 170 may be inserted axially through the spring 162, then through the upper diaphragm plate 154, the diaphragm 152, the lower diaphragm plate 152, and finally through the through-bore 198 of the control member 194. As a result, the second threaded end portion 188 of the valve stem 170 is disposed in the first counter-bore 194 of the control member 172. Next, the second connection member 176 may be placed on and rotated about the second threaded end portion 188 of the valve stem 170 so that the second connection member 176 is threadably advanced along the second threaded end portion 188 of the valve stem 170 until the axial end surface 187 of the second connection member 176 engages the first planar section 200 of the bottom surface 192 of the control member 172. In this way, the second connection member 176 may fix the control member 172 to the valve stem 170. As discussed above, since the depth X1 of the first counter-bore 194 is greater than or equal to the thickness of the second connection member 176, the connection member 176 may be concealed within the control member 172, and thus prevented, or at least inhibited, from affecting the fluid flow around the control member 172.
During operation, when there is a decrease in the downstream demand for fluid flow, the fluid pressure in the cavity 142, by way of a control line (not illustrated connected to the opening 144, may increase to enable a slight upward movement of the diaphragm 152. As a result, the control member 172 may move to the closed position where the top surface 190 of the control member 172 sealingly engaging the valve seat ring 112, thereby preventing fluid from flowing through the throat 126. When there is an increase in the downstream demand for fluid flow, the fluid pressure in the control line as well as the fluid pressure in the cavity 142 may decrease to enable a slight downward movement of the diaphragm 152 under the biasing force of the spring 162. Consequently, the control member 172 may move to the open position where the top surface 190 of the control member 172 is spaced apart from the valve seat ring 112, thereby allowing fluid to flow through the throat 126.
While the fluid control device 100 of the present embodiment is disclosed as functioning as a regulator, alternative embodiments can be arranged differently, e.g., with fluid control device 100 being configured as a control valve. Also, while the fluid control device 100 of the present embodiment includes a biasing member that biases the control member to the open position (i.e., a fail-open configuration), alternative embodiments can be arranged with a biasing member that biases the control member to the closed position (i.e., a fail-closed configuration).
With reference to the experimental test data shown in
Looking to
From the foregoing, it can be seen that the present disclosure advantageously provides an improved control member for a fluid control device that effectively reduces and/or eliminates turbulence caused by a connection member for connecting the control member to a valve stem. This reduction and/or elimination of turbulence advantageously reduces the likelihood of fluttering of the control member, at least during low fluid flow conditions, and therefore increases the stability of the output pressure of the fluid control device.
While the present disclosure has been described with respect to certain embodiments, it will be understood that variations may be made thereto that are still within the scope of the appended claims.
The priority benefit of U.S. Provisional Application No. 62/240,377, filed Oct. 12, 2015, is claimed, and the entire contents thereof are expressly incorporated herein by reference for all purposes.
Number | Name | Date | Kind |
---|---|---|---|
2017739 | Tomlinson | Oct 1935 | A |
2800141 | Hedland | Jul 1957 | A |
2911994 | Branson | Nov 1959 | A |
3392749 | Gneiding et al. | Jul 1968 | A |
4326557 | Behle | Apr 1982 | A |
9639093 | Morgan | May 2017 | B2 |
20090146096 | Davies, Jr. et al. | Jun 2009 | A1 |
20120235069 | Richardson et al. | Sep 2012 | A1 |
20150276078 | Xiao et al. | Oct 2015 | A1 |
20150362070 | Lei | Dec 2015 | A1 |
Number | Date | Country |
---|---|---|
202884067 | Apr 2013 | CN |
1114955 | Jul 2001 | EP |
763134 | Dec 1956 | GB |
1184720 | Mar 1970 | GB |
Entry |
---|
International Search Report and Written Opinion dated Jan. 3, 2017 in counterpart International Application No. PCT/US2016/056493. |
Number | Date | Country | |
---|---|---|---|
20170102091 A1 | Apr 2017 | US |
Number | Date | Country | |
---|---|---|---|
62240377 | Oct 2015 | US |