The present invention generally relates to automatic valves employed on municipal water utility systems. More particularly, the present invention relates to a hydraulically adjustable pressure management control valve designed to control downstream pressure between selected set points.
There is a general understanding throughout the worldwide water supply industry that instances of water loss are common in many water distribution networks and in many instances the level of water loss can be relatively high. The amount of water loss in the system is due to a variety of leak sources, such as improperly tightened pipe flange connections, leaking flange gaskets, leaking valve seals, failed seals, old pipes (with pinhole bursts), loose fittings, leaky faucets, etc. The sum of these sources of leakage can add up to a substantial amount of water loss. Maintaining the entry point pressure at all times at the level necessary to provide adequate pressure at the distant points for periods of high demand can result, during periods of low demand, in excessive pressure at the consumer's premises, and thus increased waste of water by unnecessary consumption and leakage. The volume of water lost through leakage is directly related to pressure in the system.
Automatic pressure reducing valves are used in water distribution systems to reduce pressure to a pre-determined value or sub-point that is adequate, but does not expose normal components, such as household hot water tanks, to overpressure. The sub-point is typically determined to provide minimum pressure that meets criteria of the water utility, particularly under maximum or “peak” demand conditions which can occur when a fire is being fought. The pressure required for peak demand is usually significantly higher than that required for “off-peak” or typical nighttime conditions. Under low demand conditions, not only does leakage form a higher proportion of the total demand, but investigation has implied that some leak orifices can actually increase in area with pressure, aggravating the problem if excessive pressures are maintained at all times.
Various attempts have been previously made to reduce such losses by introducing a degree of control over the supply pressure in response to demand. One known system uses electrical circuit means with pressure and flow-rate sensors from monitoring pressure and flow-rate and then processing the information obtained and using it in turn to control suitable electrically operated valve means. Such systems are, however, relatively complex and expensive and require a continuous external power supply giving rise to additional capital and running costs and reliability problems.
There also exist flow-driven valves which use fluid pressures to control actuation of the main valve, and thus are independent of external power sources and can be used in essentially any location. One such flow-driven valve system is disclosed in U.S. Pat. No. 5,967,176 to Blann, et al. The system controls high and low pressures by utilizing the pressure drop across an orifice plate that is installed in the main line, usually attached directly to the inlet or outlet flange of the main valve. The pressure control is independent of the main valve position, and is a direct function of system flow. The pressure control device monitors the pressure drop or flow across the orifice plate. Control pressure is varied based upon the movement of a pilot valve member with respect to a fixed pilot valve member, which in turn controls the main control valve.
However, this system has many shortcomings. The diameter of the orifice plate may need to be customized for different high/low flow applications. For example, a smaller orifice diameter may be required if flows are not sufficient to develop the required pressure drop across the system orifice. Likewise, the system orifice may need to be increased if pressure drops are too large because a smaller orifice can limit the flow capacity of the system. The orifice plate also decreases the capacity of the main valve. This is particularly a concern when high flow is necessary, such as a high flow of water to fight a fire or the like. The added orifice plate limits the capacity of the main valve for fire flow situations. Moreover, it is difficult to retrofit existing valves with this system as the flange spacing must be modified to accommodate the orifice plate, typically requiring removal of the main valve from the line.
Accordingly, there is a continuing need for an improved flow-driven valve system for automatically controlling downstream pressure between selected set points. The present invention fulfills these needs and provides other related advantages.
The present invention resides in a system and method for hydraulically managing fluid pressure between selected set points. As will be more fully described herein, the system is flow-driven and responds to changing flow demand downstream from a main valve, so as to manage and control the fluid pressure downstream from the main valve between predetermined set points.
The system generally comprises a main valve having a main valve body defining a fluid inlet and a fluid outlet. A main valve seat is disposed between the fluid inlet and the fluid outlet. A main valve member is movable between an open position away from the main valve seat, and a closed position engaging the main valve seat. The main valve is configured to hydraulically open to increase fluid flow therethrough, and hydraulically close to reduce fluid flow therethrough. A main valve diaphragm is coupled to the main valve member. The main valve diaphragm and the main valve body, or a cover thereof, define a control chamber having a control port in fluid communication with a pilot control system.
The pilot control system is operably coupled to the main valve and has at least one fluid conduit for passing fluid through a fixed orifice and into a first chamber of a control pilot valve apparatus, and for passing fluid through a variable orifice assembly defining a variable orifice and into a second chamber of the control pilot valve apparatus.
The variable orifice assembly comprises a housing associated with the valve, and defines a fluid inlet and outlet. A stem is connected to the valve member and slidably disposed within the housing. Movement of the stem within the housing creates a variable fluid orifice between the fluid inlet and the fluid outlet of the housing.
The variable orifice assembly stem may include a fluid inlet in fluid communication with the fluid inlet of the housing, and a fluid outlet variably in fluid communication with the fluid outlet of the housing as the stem is moved. In another embodiment, a sleeve is disposed between the housing and the stem. The sleeve has an aperture in fluid communication with the housing fluid outlet. The stem is adapted to variably permit fluid to pass from the housing fluid inlet to the sleeve aperture, and the housing fluid outlet. Preferably, the sleeve is adjustably positioned within the housing to vary the fluid flow from the housing fluid inlet to the housing fluid outlet.
At least one fluid conduit includes a first inlet disposed upstream of the main valve seat and in fluid communication with the fixed orifice and the variable orifice assembly. A second inlet is disposed downstream of the main valve seat, the second inlet being in fluid communication with the first chamber of the control pilot valve apparatus.
A pressure regulator apparatus may be disposed between the fluid conduit inlet and the fluid inlet of the variable orifice assembly to customize and regulate the pressure entering into the variable orifice assembly. The pressure regulator comprises a housing having a fluid inlet and a fluid outlet. A selectively adjustable fluid passageway is disposed between the fluid inlet and fluid outlet.
The control pilot valve apparatus generally comprises a housing having a first flexible diaphragm disposed therein and defining a first variable chamber above the first flexible diaphragm. The first variable chamber has a fluid inlet and a fluid outlet. A movable yoke is attached to the first flexible diaphragm. A second flexible diaphragm is disposed within the housing in spaced relation to the first flexible diaphragm, and defines a second variable chamber below the second flexible diaphragm. The second variable chamber has a fluid inlet. A stem is attached to the second flexible diaphragm and slidably disposed relative to the yoke. The yoke and stem cooperatively form a variable fluid passageway between the inlet and the outlet of the first variable chamber.
Typically, the stem includes an aperture variably alignable with a yoke aperture such that as the yoke and stem move relative to one another, they cooperatively define the variable fluid passageway.
The movement of the stem is limited to a selected range defining a lower pressure set point. Typically, such means includes an adjustable spring assembly for adjusting the movement of the stem to the selected range defining the lower pressure set point. Similarly, the movement of the yoke is limited to a selected range so as to define an upper pressure set point. Typically, such means includes an adjustable spring assembly for adjusting the movement of the yoke to the selected range defining the upper pressure set point.
The pilot control system hydraulically opens or closes the main valve in response to a pressure differential between the first and second chambers of the control pilot valve apparatus, so as to manage fluid pressure downstream of the main valve between the selected upper and lower set points.
A method of controlling fluid flow through a main valve to maintain downstream pressure between pre-determined set points in accordance with the present invention comprises the steps of generating a fluid stream having a pressure proportional to an inlet pressure of the main valve. A first portion of the fluid stream is passed through a fixed orifice and into the first chamber of the control pilot valve apparatus above the flexible diaphragm thereof. A second portion of the fluid stream is passed through the variable orifice assembly and into the second chamber of the control pilot valve apparatus below the flexible diaphragm. A pressure differential between the first and second chambers of the control pilot valve apparatus is detected, resulting in the hydraulic opening or closing of the main valve by transmitting a fluid stream into the control chamber of the main valve. The fluid passageway of the variable orifice is automatically altered in response to the opening and closing of the main valve.
The second portion of the fluid stream may be passed through the pressure regulator passageway before passing the second portion of the fluid stream through the variable orifice. The pressure regulator passageway may be adjusted in order to modify a pressure regulation profile.
A lower pressure set point is set by selectively limiting a range of travel of the flexible diaphragm of the control pilot valve apparatus. An upper pressure set point is set by selectively limiting a range of travel of a second, or upper, flexible diaphragm of the control pilot valve apparatus which is disposed above the first chamber.
A second fluid stream is generated which has a pressure proportional to an outlet of the main valve. This second fluid stream is placed in fluid communication with the first chamber of the control pilot valve apparatus.
Other features and advantages of the present invention will become apparent from the following more detailed description, taken in conjunction with the accompanying drawings, which illustrate, by way of example, the principles of the invention.
The accompanying drawings illustrate the invention. In such drawings:
As shown in the accompanying drawings, for purposes of illustration, the present invention is directed to an adjustable hydraulically operated pressure management control valve system 10. As will be more fully described herein, the system 10 of the present invention is primarily intended for use in the waterworks industry where there is a desire to reduce the amount of water loss in the system due to leaks. The invention can reduce the amount of water loss in a system by reducing the system pressure as the flow or system demand decreases. A common example would be a residential water system where water demand is high during the day and low at night. If the pressure is lower during low usage, then a lower pressure will result in lower water losses throughout the system.
As will be more fully described herein, the system 10 of the present invention comprises a main valve assembly 100 operably coupled to a pilot control system 20. The pilot control system 20 includes a variable orifice assembly 200, a control pilot valve apparatus 300, and an optional pressure regulator apparatus 400. Various conduits 22-42 fluidly couple these components and provide pressurized fluid streams, as will be more fully described herein. The pilot control system 20 hydraulically opens the main valve assembly 100 during high demand conditions, and closes the main valve assembly 100 during low demand conditions, resulting in a reduction of the amount of water loss in a waterworks system downstream of the main valve assembly 100.
With reference now to
As will be more fully explained herein, the pilot control system 20 increases fluid flow into the control chamber 120 during low flow or low demand situations, causing the main valve member 110 to move downwardly towards engagement with the main valve seat 108. Conversely, during high flow or high demand situations, less fluid is directed into the fluid control chamber 120, resulting in a lower pressure and enabling the main valve member 110 to move away from the main valve seat 108 into an open position so as to permit more fluid to flow through the main valve 100.
With reference again to
With reference now to
A stem 212 is movably disposed within the housing 202, and coupled to the stem 112 of the main valve member 110. In this manner, as the main valve member 110 moves up and down, the stem 212 of the variable orifice assembly 200 also moves up and down. The housing 202 and the stem 212 cooperatively define a variable orifice 214. For example, typically the stem 212 is at least partially hollow and includes an aperture or slit therein. As illustrated in
With reference now to
In this case, however, the stem is not hollow. Instead, the housing 202′ is adapted so as to receive a sleeve 203′ between the inner wall of the housing 202′ and the stem 212′. As illustrated in
It will be readily appreciated by those skilled in the art that the slot 205′ can be created so as to create a pressure regulation profile by increasing or decreasing the fluid flow therethrough. Similarly, the exterior configuration of the stem section 207′ can be modified to correlate to increased or decreased fluid flow. However, these techniques do not allow adjustment after the assembly 200′ has been manufactured and assembled.
Thus, with reference to
The travel of the sleeve 203′ may be limited, for example, by the use of a set screw 213′ which is disposed above a shoulder 215′ of the sleeve 203′. Also, this serves as a precautionary feature so as to not permit the user to inadvertently unthread the sleeve 203′ to the point where the variable orifice assembly 200′ does not function. It will be appreciated that the adjusting position of the sleeve aperture 205′ can be used to change or customize the pressure curve profile between the low and high flow set points of the system.
With reference again to
More particularly, with reference to
The control pilot valve apparatus 300 includes a low pressure adjustment screw 312 threadedly connected to an end member 314 and having a stop nut 316 threadedly attached thereto. The end of the screw 312 engages a guide 318, supporting a spring 320. The spring is contained within a piston 322 such that the spring 320 exerts a force on the piston 322.
A stem 324 is connected to the piston 322, such as by use of a nut 326 and a threaded end of the stem 324 extending into the body of the piston 322. The stem 324 also extends through the diaphragm 306 and a washer 328 disposed on a top surface of the diaphragm 306. An upper nut 330 may be threaded onto the stem 324, or a shoulder formed in the stem. The lower and upper nuts 326 and 330 sandwich and couple the piston 322, the diaphragm 306, the stem 324, and the washer 328 to one another. Thus, if any of these components are moved, such as due to the force of the spring 320 or the fluid pressure in chamber 304, the connected members also move. An upper portion of the stem 324 is hollow, and includes an aperture or slot 332 therein.
A high pressure adjustment screw 334 threadedly extends through an upper member 336 of the body and includes a stop nut 338. The end of the high pressure adjustment screw 334 is in contact with an upper spring guide 340 which acts upon an upper spring 342. The spring 342 extends between the upper guide 340 and a washer 344 coupled to an upper, and typically smaller, diaphragm 346. The upper diaphragm 346 is disposed above the upper or first chamber 310, and a chamber 348 having atmospheric pressure.
A yoke 350 has a threaded end 352 with a nut 354 which couples the yoke 350 to the upper diaphragm 346 and washer 344. The yoke 350 includes a passageway or opening 356. The yoke passageway 356 and the stem slot 332 are alignable with one another so as to permit fluid to flow through an inlet 358 of the control pilot valve apparatus and into the first chamber 310, and out an outlet 360. The stem 324 and the yoke 350 are slidably nested or otherwise arranged so that they independently move, yet cooperatively define a variable fluid passageway between the inlet 358 and outlet 360. It will be appreciated that depending upon the position of the stem 324 and the yoke 350, the stem slot 332 and yoke aperture 356 are either completely aligned with one another, partially aligned with one another so as to restrict flow therethrough, or completely non-aligned so as to prevent fluid flow into and through the first upper chamber 310 of the control pilot valve apparatus 300.
Typically, a coupling member or stem guide 362 has an orifice or passageway therethrough 364 to permit fluid flow between an upper portion of the first chamber 310 adjacent to the inlet and outlet 358 and 360, and a lower portion of the upper or first chamber 310 immediately above the lower diaphragm 306. Thus, fluid pressure in the upper or first chamber 310 can act upon both the lower diaphragm 306 and the upper diaphragm 346 of the control pilot valve apparatus 300.
With reference again to
The fluid stream in conduit 34 is split between conduits 36 and 38. The fluid stream in conduit 38 passes through a fixed orifice device 50, and is fluidly coupled to the outlet 360 of the control pilot valve apparatus 300. The fluid stream in conduit 36 is passed through inlet 302, and into the lower, or second chamber 304. As the variable orifice 214 is presented at its maximum flow, the amount of fluid stream, and thus fluid pressure, entering into the chamber 304 is relatively large, causing the lower diaphragm 306 to move upwardly, as illustrated in
As the lower diaphragm 306 moves upwardly, the aperture or slot 332 in the stem 324 is moved upwardly so as to become increasingly aligned with the corresponding aperture or slot 356 of the yoke 350. Thus, the fluid in conduit 30 is able to pass through the inlet 358, and through the aligned apertures or slots 332 and 356 of the stem 324 and yoke 350, and into the upper or first chamber 310. The fluid is also able to exit outlet 360 of the control pilot valve apparatus, and into conduit 40. Due to the relatively free flow of the fluid, as described above, a relatively lesser amount of fluid and fluid pressure is introduced into the control chamber 120 of the main valve 100, permitting the main valve member 110 to be moved upwardly towards the main valve cover 118. It will be noted that in this situation, the pressure at P2 is greater than the pressure at P3 at the other side of fixed orifice device 50. This is due to a relatively high flow of fluid through variable orifice 214 and into the lower chamber 304 of the control pilot valve apparatus 300. Moreover, there is a pressure differential between the lower chamber 304 and the upper chamber 310, causing the diaphragm 306 to move upwardly, aligning slots 332 and 356, resulting in the hydraulic opening of the main valve member 110. Such would be the case, for example, when a large flow is required downstream from the main valve assembly 100.
As explained above, the design of the present invention controls high and low pressures by interacting with the variable orifice 214 or the variable orifice assembly 200 operably coupled to the main valve assembly 100. The variable orifice 214 opening increases or decreases with the main valve member 110 stroke upwardly or downwardly. The variable orifice 214 interacts with the fixed orifice 50 in the control pilot system 20. As system demand increases, the main valve 100 opens to respond to the increased system demand. As the main valve 100 opens, the flow area through the variable orifice 214 increases, which in turn increases the pressure drop, or pressure differential, across the fixed orifice device 50. The pressure drop, or differential, across this fixed orifice 50 is used to control the transition of system downstream pressure between the low and high pressure set points of the control pilot valve apparatus 300.
In the illustrated design, the low pressure set point is set and adjusted by turning screw 312, which serves to compress or decompress spring 320, thus limiting the range of motion or travel of the lower diaphragm 306 and stem 324. The upper or high pressure adjustment is made by selectively turning screw 334, thus compressing or decompressing spring 342, and thus affecting the range of travel of the upper diaphragm 346 and the yoke 350. Such adjustments set the low and high pressure set points of the system 10.
The variable orifice 214 can be customized to control the rate of change between the low and high pressure settings. If the flow area through the variable orifice 214 is profiled to increase quickly (relative to main valve member 110 stroke), the transition between low and high pressure set points will likewise change quickly. For example, for a variable orifice 214 where the flow area through the variable orifice quickly changes, the transition between the low pressure set point and the high pressure set point would occur fairly quickly between the low and high flow conditions resulting in a relatively steep curve between the low and high set points. For instance, for a given valve size, such as an eight-inch valve, pressure change could occur within a two hundred gallon-per-minute flow span, or a relatively steep curve. However, if the flow area through the variable orifice 214 is profiled to increase slowly, relative to main valve member 110 stroke, then the transition between the low and high pressure set points will likewise change slowly. For example, a variable orifice 214 where the flow area through the variable orifice slowly changes, then the same low-high pressure transition would occur fairly slowly between the low and high flow conditions. In this case, the change might occur within a five hundred gallon-per-minute flow span, or a relatively shallow curve. Changing the variable flow area geometry of the variable orifice 214 can be used to change or customize the pressure curve profile between the low and high flow set points.
With reference now to
The set point or adjustment is made by a screw 426 being turned clockwise or counterclockwise, which applies a force to spring guide 428, causing the spring 420 to be compressed or relaxed. This impacts the position of diaphragm 418, and yoke 422. This also establishes a range of travel for the diaphragm 418, if any, so as to produce a relatively constant flow or pressure through outlet 410, represented by P1 in
With reference now to
Referring now to
As the pressure in the first chamber 310 begins to increase, upper diaphragm 346 will be forced to move upwardly, pulling yoke 350 upwardly with it, and constricting the passageway through slots or apertures 332 and 356. In fact, when diaphragm 346 is moved to its upper most position, the yoke 350 may be sufficiently raised so that its aperture or slot 356 is no longer aligned whatsoever with the slot or aperture 332 of the stem 324, such that fluid is not allowed to pass therethrough. Such is illustrated in
As described above, adjustment screw 334 is rotated so as to relax or compress spring 342, increasing or decreasing the range of potential motion and travel of the diaphragm 346 and the yoke 350. In this manner, the high pressure set point can be adjusted and set to a predetermined level.
With reference now to
With continuing reference to
With reference now to
With reference now to
This results in a lower fluid flow and pressure at P2, and lower chamber 304 of the control pilot valve apparatus 300. The lower pressure in chamber 304 naturally biases the lower diaphragm 306 downwardly, as can be seen in
The passage area through the variable orifice 214 changes with the change in the main valve member 110 position. Main valve number 110 position changes in response to system flow demand conditions, opening as demand increases and closing as demand decreases. Restricted flow through the variable orifice 214 causes a low pressure drop, or pressure differential, through the fixed orifice 50, which causes restricted flow through the control pilot valve apparatus 300. This action causes the main valve 100 to throttle closed towards a lower pressure set point. The lower pressure set point is established by adjusting set screw 312, which compresses or relaxes spring 320, directly affecting the range of travel and motion of lower diaphragm 306.
However, when system flow demand increases, the main valve 100 responds by opening, which increases flow area through the variable orifice 214, as described above. Increased flow through the variable orifice 214 increases the pressure drop, or differential, across fixed orifice 50. This action causes the main valve 100 to throttle open towards the higher set point.
Due to the varying flow of fluid through the variable orifice 214, the pressure acting on the lower diaphragm 306 also varies. When the pressure on the top of the lower diaphragm, in chamber 310, is equal to or slightly higher than the pressure under the lower diaphragm, in chamber 304, then hydraulic forces bias the travel of the slotted stem 324 in a direction that reduces the flow area through the slot 332. This action, as described above, causes the main valve 100 to throttle towards the low pressure, or low flow, set point.
However, as pressure under the lower diaphragm in chamber 304 increases relative to pressure above the lower diaphragm 306 in chamber 310, then hydraulic forces bias the travel of the slotted stem 324 in a direction that increases the flow area through the slot 332. This action causes the main valve 100 to throttle towards the high pressure, or high flow, set point. As described above, when the pressure in the upper chamber 310 is sufficiently great, the upper diaphragm 346 moves upwardly to its selected high pressure set point, moving the yoke upwardly, and restricting the flow through the slot 332 and yoke passageway 356, increasing the pressure in the control chamber 120, and either preventing the main valve member 110 from moving upwardly any further, or forcing the main valve member 110 downwardly towards a more closed position. In all flow conditions (low and high) the stem 324 and yoke 350 are independently moved and do not interfere with one another's travel. The exposed slot area, or variable passageway, through the control pilot valve apparatus 300 varies with changing system conditions causing flow to modulate. This arrangement allows the main valve 100 to modulate between the pre-selected high and low pressure set points established at the control pilot valve apparatus 300, as described above. More particularly, it is the selection of the springs 320 and 342 acting on the lower and upper diaphragms 306 and 346 which create the high and low pressure set points. The low pressure set point is determined by the applied force of the lower spring 320. Decreasing the spring force of the lower spring 320 lowers the downstream pressure. Increasing the spring force of the upper spring 342 raises the downstream pressure. The upper spring 342 is used to set the system pressure for normal or high flow conditions, while the lower spring 320 is used to set the system pressure conditions for low flow conditions.
Although several embodiments have been described in some detail for purposes of illustration, various modifications may be made without departing from the scope and spirit of the invention. Accordingly, the invention is not to be limited, except as by the appended claims.
Number | Date | Country | |
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60911604 | Apr 2007 | US |
Number | Date | Country | |
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Parent | 11927474 | Oct 2007 | US |
Child | 13240070 | US |