The present invention relates generally to aircraft propulsion systems and, more particularly, to a pressurizing and pressure regulating valve suitable for deployment within an aircraft fuel supply system.
Aircraft are commonly equipped with a fuel supply system that draws combustion fuel from a fuel source (e.g., a storage tank) and supplies it to a propulsion engine, such as a gas turbine engine. A representative fuel supply system includes a metering valve, a supply pump fluidly coupled between the metering valve and the fuel source, and a bypass valve fluidly coupled between the inlet and the outlet of the supply pump. The supply pump may be, for example, a fixed displacement pump that is mechanically coupled to a spool of the gas turbine engine. During operation, the supply pump provides combustion fuel to the metering valve, which meters the fuel in accordance with commands received from an engine controller. The metered combustion fuel is directed into the fuel manifold of the aircraft engine, mixed with air, and ignited to drive one or more engine turbines and to produce forward thrust. The bypass valve redirects excess fuel provided by the supply pump outlet back to the supply pump inlet.
In addition to the above-described components, an aircraft fuel supply system may further include a pressurizing valve fluidly coupled between the fuel metering valve and the aircraft engine. When the fuel pressure upstream of the pressurizing valve is undesirably low, the pressurizing valve impedes fuel flow to the aircraft engine to maintain fuel pressure upstream of the pressuring valve and downstream of the supply pump (e.g., at the supply pump outlet) above a predetermined minimum pressure, such as 250 pounds per square inch (psi). By maintaining the back pressure above a predetermined threshold in this manner, the pressurizing valve helps to ensure that pressure-sensitive components downstream of the supply pump (e.g., fuel-conducting servomechanism of the type described below) operate effectively and efficiently.
In addition to supplying combustion fuel to an aircraft engine manifold, an aircraft fuel supply system may also supply fuel to one or more fuel-conducting servomechanisms (“servos”). These servos perform various functions aboard the aircraft and may include, for example, a variable-geometry servo, a bleed air servo, and a metering valve actuator servo. The operation of such servos may be negatively impacted if the pressure of the fuel supplied thereto surpasses a maximum pressure. Thus, to prevent the pressure of the fuel supplied to the servos from surpassing a maximum pressure threshold, a pressure regulating valve may be disposed between the fuel supply system pump and the control servos. During operation, the pressure regulating valve selectively impedes fuel flow to maintain the pressure of the fuel supplied to the servos below a predetermined maximum pressure, which may be, for example, 300 psi.
It should thus be appreciated that aircraft fuel supply systems of the type described above commonly employ two separate pressure regulating devices; i.e., a pressurizing valve that maintains fuel pressure at supply pump outlet above a predetermined minimum pressure, and a pressure regulating valve that maintains a downstream fuel pressure (i.e., the pressure of the fuel supplied to one or more servos) below a predetermined maximum pressure. Each pressure regulating device generally includes a separate valve housing (e.g., a sleeve), valve element (e.g., a piston), spring, mounting hardware, and so on. As a result, the utilization of two independent pressure regulating devices negatively impacts the overall part count, cost, weight, and envelope of the fuel supply system.
Accordingly, it is desirable to provide a unitary and compact valve capable of performing both pressurizing and pressure regulating functions. It would also be desirable to provide a fuel supply system suitable for deployment on an aircraft that employs such a pressurizing and pressure regulating valve. Other desirable features and characteristics of the present invention will become apparent from the subsequent Detailed Description and the appended claims, taken in conjunction with the accompanying drawings and this Background.
A pressurizing and pressure regulating valve is provided. In one embodiment, the pressurizing and pressure regulating valve includes a sleeve, a first flow passage formed through the sleeve, a second flow passage formed through the sleeve, and a piston slidably disposed in the sleeve. The piston is configured to move between: (i) a pressurizing position wherein the piston impedes fluid flow through the first flow passage, and (ii) a pressure limiting position wherein the piston impedes fluid flow through the second flow passage. A sensing chamber is fluidly coupled to the first flow passage and configured to receive pressurized fluid therefrom. The piston is configured to move from the pressurizing position to the pressure limiting position when the pressure within the sensing chamber exceeds a predetermined minimum pressure.
A fuel supply system is also provided for use in conjunction with a fuel source, an engine, and a servomechanism. In one embodiment, the fuel supply system includes a supply pump having a supply pump inlet fluidly coupled to the fuel source and including a supply pump outlet, a metering valve fluidly coupled to the supply pump outlet, and a pressurizing and pressure regulating valve. The pressurizing and pressure regulating valve includes a sleeve, a first flow passage formed through the sleeve and fluidly coupled between the supply pump outlet and the servomechanism, a second flow passage formed through the sleeve and fluidly coupled between the supply pump outlet and the engine, and a piston slidably disposed in the sleeve. The piston is configured to move between: (i) a pressurizing position wherein the piston impedes fluid flow through the first flow passage to maintain the pressure at the supply pump outlet above a predetermined minimum pressure, and (ii) a pressure limiting position wherein the piston impedes fluid flow through the second flow passage to maintain the pressure of the fuel supplied to the servomechanism below a predetermined maximum pressure.
At least one example of the present invention will hereinafter be described in conjunction with the following figures, wherein like numerals denote like elements, and:
The following Detailed Description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. Furthermore, there is no intention to be bound by any theory presented in the preceding Background or the following Detailed Description.
As shown in
In the illustrated exemplary embodiment, piston 16 comprises: (i) a first end portion 34, (ii) a second end portion 36 substantially opposite first end portion 34, and (iii) an intermediate portion 38 extending between first end portion 34 and second end portion 36. First end portion 34 and second end portion 36 each extend radially outward to sealingly engage the inner surface of sleeve 14. Intermediate portion 38 has a reduced outer diameter relative to first end portion 34 and second end portion 36 and does not sealingly engage the inner surface of sleeve 14. However, piston 16 further comprises an annular flange 40 that is fixedly coupled to (e.g., integrally formed with) intermediate portion 38. As do end portions 34 and 36, flange 40 extends radially outward to sealingly engage the interior of sleeve 14. In so doing, flange 40 partitions flow chambers 30 and 32. Furthermore, as piston 16 translates within sleeve 14, flange 40 selectively obstructs fuel flow through flow passage 18, 24, 30 and through flow passage 20, 26, 32 as described in more detail below.
End portion 34 of piston 16 and sleeve 14 cooperate to further define a third chamber within sleeve 14, namely, a sensing chamber 42. A sensing channel 44 fluidly couples sensing chamber 42 to flow passage 20, 26, 32. In particular, sensing channel 44 fluidly couples sensing chamber 42 to flow chamber 32 of flow passage 20, 26, 32. In the exemplary embodiment shown in
As may be appreciated by comparing
During operation, pressurizing and pressure regulating valve 12 performs two main functions. First, pressurizing and pressure regulating valve 12 maintains the pressure upstream of inlet port 18 above a predetermined minimum pressure. Thus, valve 12 may conveniently be disposed downstream of a supply pump and pressure-sensitive components (e.g., a fuel metering valve) that operate most efficiently above a predetermined minimum pressure. Secondly, pressurizing and pressure regulating valve 12 prevents the pressure downstream of outlet port 26 from surpassing a predetermined maximum pressure. Thus, valve 12 is further conveniently positioned upstream of pressure-sensitive components (e.g., servomechanisms) that operate most efficiently below a predetermined maximum pressure. These characteristics render pressurizing and pressure regulating valve 12 ideal for use in conjunction with a fuel supply system of the type commonly deployed on an aircraft. For this reason, the operation of valve 12 will be described below in the context of fuel supply system 10.
In the exemplary embodiment shown in
In the exemplary embodiment illustrated in
As stated above, inlet ports 18 and 20 are fluidly coupled to the outlets of metering valve 54 and pump 52, respectively. In the exemplary context of system 10, outlet port 24 is fluidly coupled, and supplies combustion fuel, to the fuel manifold of an aircraft engine. Outlet port 26 is fluidly coupled, and supplies fuel, to one or more fuel-conducting servomechanisms. Outlet port 26 may be fluidly coupled to any suitable type of servo or servos. By way of example, outlet port 26 may be fluidly coupled to a servomechanism that controls an actuator (not shown) associated within metering valve 54 in accordance with commands issued from an engine controller. Additionally or alternatively, outlet port 26 may be fluidly coupled to a variable geometry servomechanism, a bleed valve servomechanism, and the like.
The fuel output of supply pump 52 typically varies during operation of system 10. For example, if supply pump 52 is driven by a gear train coupled to the spool of the aircraft's gas turbine engine, the fuel output of pump 52 will vary in relation to engine speed. Also, during operation of system 10, fuel flow across metering valve 54 fluctuates in relation to the position of metering valve 54, which is continually adjusted to accommodate the combustion requirements of the aircraft engine. This notwithstanding, the fuel output of pump 52 will generally well-exceed the fuel requirements of metering valve 54. This excess fuel flows through conduit 62 and into bypass valve 56, which redirects a portion of the excess fuel through conduit 64 and, therefore, back to the inlet of pump 52. The remaining portion of the excess fuel supplied by pump 52 is directed into inlet port 20; flows through flow passage 20, 26, 32; and is ultimately provided to the control servo or control servos downstream of outlet port 26.
The operation of pressurizing and pressure regulating valve 12 will now be described in conjunction with fuel supply system 10. Referring initially to
Referring still to
When the fuel output of pump 52 increases, so too does the pressure within flow passage 20, 26, 32 and, therefore, within sensing chamber 42. When the force exerted on piston 16 by the fuel within sensing chamber 42 exceeds the force exerted on piston 16 by spring 46 and the fuel within reference pressure chamber 50, piston 16 moves toward the pressure limiting position shown in
When piston 16 moves into the pressure limiting position illustrated in
The foregoing has described one exemplary pressurizing position (
When in a pressure limiting position, such as that shown in
It will be appreciated that the geometries (e.g., shape, flow area, etc.) of the inlet and outlet ports provided through sleeve 14 will inevitably vary amongst different embodiments. In general, the geometry of inlet port 20 will be determined, in large part, by fuel flow requirements of the servomechanisms downstream of valve 12. Similarly, the geometry of outlet port 24 will be determined, in large part, by the combustion flow requirements of the aircraft engine. In the majority of applications, the combustion flow will be substantially higher than the servo flow at their respective maximums; the flow port height in the piston translation direction and net width in the axial direction will generally be sized accordingly. Varying the shape of the ports provided through sleeve 14 from a conventional rectangular geometry may provide the benefit of added stability over a greater fuel flow range.
In view of the above, it should be appreciated that there has been provided at least one example of a pressurizing and pressure regulating valve that maintains the pressure upstream of a first flow passage above a predetermined minimum pressure and that maintains the pressure downstream of a second flow passage below a predetermined maximum pressure. There has also been provided an exemplary embodiment of a fuel supply system that includes such a pressurizing and pressure regulating valve and that is well-suited for deployment on an aircraft.
Alternative embodiments of the pressurizing and pressure regulating valve may also be employed with a separate servomechanism that is fluidly coupled between the servo outlet port (e.g., outlet port 26 in
While at least one exemplary embodiment has been presented in the foregoing Detailed Description, it should be appreciated that a vast number of variations exist. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. Rather, the foregoing Detailed Description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention. It being understood that various changes may be made in the function and arrangement of elements described in an exemplary embodiment without departing from the scope of the invention as set-forth in the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
2115637 | Leonard | Apr 1938 | A |
2430264 | Wiegand et al. | Nov 1947 | A |
2843140 | Lambeck et al. | Jul 1958 | A |
2963082 | Binford et al. | Dec 1960 | A |
3360199 | Sharpe | Dec 1967 | A |
3692038 | Hansen et al. | Sep 1972 | A |
3777773 | Tolbert | Dec 1973 | A |
4541451 | Wittren et al. | Sep 1985 | A |
4664137 | Leorat et al. | May 1987 | A |
4966196 | Meyer | Oct 1990 | A |
6102001 | McLevige | Aug 2000 | A |
6584762 | Snow et al. | Jul 2003 | B2 |
Number | Date | Country | |
---|---|---|---|
20090320937 A1 | Dec 2009 | US |