The present invention relates to the field of measuring and testing fluid and more particularly, displacement provers on petrochemical fluid lines.
The small-volume prover is a compact, cost-effective device that allows users to verify the accuracy of flow meters used to measure product and process materials. A significant small-volume prover in the industry is provided by Flow Management Devices, LLC, such as the invention family represented by U.S. Pat. No. 7,650,775 to Alexander Ignatian. The small-volume prover is used in oilfields worldwide, either on platforms or floating production storage and offloadings (FPSOs) working with varying crude oils, hydrocarbons, and liquid fuels. Flow meters are often proven several times a day, so any reduction in the time taken by the process increases transfer accuracy and significantly improves productivity.
In the stand-by mode the piston is downstream and stationary. The piston's inner flow-through valve is open (valve poppet stationed slightly upstream of the main piston body and coupled with valve), allowing product to (low freely through the proverbs measurement cylinder with insignificant pressure loss.
When the operator starts a proving run, the computer signals the motor to pull the piston longitudinally in cylinder into the upstream position. The piston is then uncoupled from the—drive return mechanism and valve is closed with the combination of fluid pressure force and spring force. When the piston is released, it quickly accelerates until the Piston velocity is now synchronized with the fluid velocity. The low-drag piston traveling down the smooth-bore tube is then free in follow flow of the fluid with the least possible effect on the flow stream from upstream to downstream position within cylinder.
After the piston has been released, and after beginning a short run through the cylinder, the precision optical volume switch is actuated, sending a signal to the proving computer to start the timing sequence. The piston continues downstream with the flow. Upon reaching the end volume switch, a signal is sent to the proving computer to stop the timing sequence. Just after passing the end of volume switch, the piston shaft is stopped by a mechanical stop. Product flowing through the prover pushes the perimeter of the piston further downstream, opening the flow-through valve and permitting flow to continue with little to no pulse/surge in line pressure. The speed, or lack thereof, at which h the opening and closing of the valve affects such surge.
To begin the next proving run, a signal is sent from the proving computer, activating the return mechanism and pulling the piston to the upstream position where it is released to obtain another data point.
The main features of the small-volume prover include its precision smooth bore measurement cylinder, a displacement piston that contains an integral bypass valve and high accuracy optical switches. The bypass valve includes a dual control led poppet valve resting between a drive rod and a spring. The prover includes preferably PTFE filled seals mat ensure fluid compatibility, and sealing integrity. The small-volume prover has a constant displaced volume, ensuring constant proving results with uncertainty equal to or exceeding 0.02 percent as required by the American Petroleum Institute (API).
Unidirectional captive displacement provers, such as the FlowMD Unidirectional Captive Displacement Prover provides for small volume proving and sampling of a pipeline. Displacement provers often conform to API 4.2 (American Petroleum Institute). Materials often used include stainless steel and PTFE on wetted parts. Frame mounted isolation pads may provide for lateral drive movement compliance while maintaining vertical support.
Current cylinder draws are limited based on the geometry of the cylinder and the piston assembly. The piston includes a poppet on the integral valve that is fixed on a longitudinally driven shaft. The poppet disk has been a flat, round disk with annular seal. The valve, with poppet, is held in a biased closed position by a spring. The prover valve opens when connected to a flowing fluid stream to allow fluid to continue to pass through the cylinder. On a testing stroke (prover run), the prover shaft drives the piston with open valve via the support through the cylinder towards the supply end (upstream). The piston/shall assembly is decoupled from the main drive mechanism and the piston system is tree to move along the flow direction on shaft via the force provided from the incoming fluid. This allows closure of the valve (as the poppet mates with the seal in valve) via biased spring force and fluid pressure force. At the end of the stroke, the valve opens to allow minimally interrupted flow. During the prover run, the piston assembly moves at the speed of the incoming fluid due to the flow pressure.
The shaft draws the valve and is secured to poppet support to pull piston body. During the opening and closing of the valve, inaccuracies will occur if the closing is not done in advance of the optical volume switch actuation. The practical considerations of the valve being forcibly closed by the incoming fluid pressure and spring tension, causes a delay (however miniscule) that affects flow. Similarly, when opening at the end of the stroke. To minimize the interference caused by the valve action, the valve must open and close as quickly as possible with as little disruption to the fluid dynamics as possible.
Given the nature of the stresses on the prover (designed as a pressure vessel), the components are often very well constructed and do not yield to maintenance easily. Seals wear and ultimately fail due to the (albeit minimized) constant friction and/or pressures on the seal body. These seals must be replaced on a regular basis. In order to replace the seal, prior art provers require complete disassembly of the valve. An improved valve design may include new poppet and seal structure.
Therefore, it is an object of the present invention to provide for an improved geometry in poppet shape to allow for better flow when the valve is open.
It is another object of the present invention to provide a poppet shape that speeds the opening and or closing of the valve after the downstroke and/or the upstroke, respectively.
It is yet a further object of the present invention to increase the pressure on the valve to streamline poppet valve closure at the beginning of the downstream stroke.
It is yet another object of the present invention to minimize the time to open the valve at the end of the downstream stroke.
It is an object of the present invention to provide accurate flow readings.
It is another object of the present invention to reduce noise in the system.
Furthermore, the current poppet geometry including retention rings and support frame lead to difficult maintenance and repair. It is therefore another object of the present invention to provide for an improved ring seal removable for easier maintenance of poppet and valve. A prior art prover includes a piston body includes a piston support, poppet, upstream a shaft and downstream shaft, retainer washer, seal rider, piston spring, bushing, piston seal and poppet seal, etc. An improved design can simplify the parts to accommodate ease of maintenance.
It is a further objective of the present invention to provide for an easily accessible seal.
It is a further another object of the present invention to provide for ease of maintenance of a prover valve.
These and other objects of the present invention will become apparent to those skilled in the art as the description thereof proceeds.
The present invention includes a small-volume prover for the validation and monitoring of petrochemical fluid flow. A cylinder houses an upstream shaft and a downstream shaft, and includes a valve supported between the upstream and downstream shafts. In the alternative, a single shaft may be used to support the valve. The valve includes a poppet (such as a disk) and a poppet valve seat along an interior surface of the valve. The seal along the valve ring defines a ring plane where the poppet valve seat meets the poppet. The poppet mates the poppet valve seat at an angle offset from parallel of said ring plane. The angled meeting of the poppet and ring contrasts prior parallel matting of straight edges against a straight (parallel) flange.
The poppet is preferably angled and mates with complimentarily angled seat. The poppet may be many shapes, including a contoured poppet disk. The poppet disk may be contoured in such a way that at least a portion of the contoured poppet disk extends downstream beyond the ring plane. A spring forcing the poppet disk may also extend downstream beyond the ring plane. Given the contour of the poppet disk, the disk may take up enough length along the cylinder that at least a portion of the contoured poppet disk extends upstream beyond the ring plane at the same time as the disk is also beyond the ring plane in the downstream direction.
The poppet disk may be either flat or contoured, while including an angled wing along the annular edge or circumference of the disk. The angled wing mates with the poppet valve seat and provides for poppet mating (and seal) with the seat at an angle offset from parallel of the ring plane.
The small-volume prover may include a poppet seal (such as an annular seal, cup spring seal, etc.) mounted onto the poppet valve seat. A removable retention ring may be used to fasten the poppet seal onto the poppet valve seat. The disk may be contoured and include an annular ring, whereby the poppet seal is adapted to provide mating with the annular ring of the disk. A retention ring may be fastened directly to the poppet valve seat. The retention ring may be fastened by fasteners, such as threaded bolts, screws, snap rings, etc.
The invention also includes a small-volume prover with a cylinder housing an upstream shaft and a preferably a downstream shaft. A support slidably encircles the upstream shaft and includes a spring slidably mounted on the upstream shaft. A valve is located along the shaft, said valve comprising a contoured poppet in force communication with said spring. The contoured poppet may include an interior sheet section circumscribed by an annular wing. The interior sheet may be formed, conical, flat, tapered, or otherwise. The valve may include a tapered poppet valve seat angled at an offset angle greater than zero degrees from a ring plane. The seat may be angled to complimentarily mate with the annular ring of the contoured poppet. The annular wing may include a tapered angle to match the offset angle. The annular wing may include a sealing face adapted to male with the poppet valve seat or a seal emanating or flanged on the seat. The annular wing may preferably includes a thickness greater than a length of a contact surface on the poppet valve seat. Thus, as the annular wing wears, the location of the seal at the seat may be modified while retaining a possible seal in angled mating faces.
The present invention also includes a method of maintaining the poppet seal in a small volume prover. One may remove the prover cylinder end flange to access the valve within the cylinder. The poppet valve assembly may be maintained within the prover cylinder, and need not be removed to access the valve and seal(s). Both upstream and downstream shafts may remain in place, along with spring-loaded pressure against the poppet. A retention ring may be removed from the ring to access a poppet seal from between the valve ring and the retention ring. One may thereby replace the poppet seal while the valve remains on both upstream and downstream shafts, and then retain the poppet seal by replacing the retention ring over poppet seal onto the ring.
The present invention will be described with greater specificity and clarity with reference to the following drawings, in which:
Numerous patents have issued disclosing various types of provers. In the present invention, provers such as those described and taught by U.S. Pat. Nos. 7,650,775, and 8,161,791 to Alexander Ignatian are herein incorporated by reference. The present invention also builds upon the improvements to proven set forth in U.S. Pat. Nos. 8,196,446, 8,205,479, 8,578,752, 8,677,800, 9,103,709, and 9,470,573 to Alex Ignatian herein incorporated by reference.
A small volume prover improved with optimized drive belts includes a piston designed to displace sampled material in flow tube. Improved design of piston, including a valve with contoured poppet, allows for smoother fluid flow due to the efficiency of space when the valve is open. The redesigned poppet contoured shape provides for increased volume sampled as the poppet may close more quickly, more fluid remains on upstream side, as well as providing for possibility of reduced tube size. The new poppet structure and design includes any angle greater than 0 degrees measured perpendicular to flow direction, such as to reduce the angle fluid can flow over the open valve poppet to less than 90 degrees. The valve is held in place by a spring mated with a support and the upstream side of the poppet disk. The valve includes a ring in communication with the interior surface of the cylinder to provide a seal. The ring includes a ring plane perpendicular to flow and direction of cylinder that dissects the cylinder. By contouring a poppet such that the downstream face of the poppet disk extends further downstream than the ring plane, the extra volume may be captured. Furthermore, the spring mating with an upstream face of the poppet disk may be moved (at least partially, if not fully) downstream beyond the ring plane, resulting in additional volume of fluid held in the downstream end of cylinder.
A seal retention ring may be applied to valve body, including fasteners onto structure support to provide access to seal(s). The seal retention ring may be placed on the downstream face (near interior) of ring to hold a seal on poppet seal to allow poppet to seal in ring (and close valve).
Improved dish-shaped, or contoured, poppet may provide potential benefits of decreasing mass of poppet and prover, decreasing cost of materials and manufacture, and reducing pressure loss due to improper geometry of flow profile. Contoured poppet provides improved flow profile for smoother flow and less pressure loss. Improved poppet and ring provides for easier handling design. Poppet and ring assembly includes less material volume and should be lighter to handle manually. Efficient compact piston design provides for space efficiency. With the new poppet design, more volume can be sampled or the prover may be shortened.
The improved poppet and design seal allows for the prover to flow more smoothly through the proving stroke. The valve remains open for fluid to pass through during normal operation of the flow meter. Flow passes over poppet design in valve within prover cylinder. In order to start a test run, rod drives valve upstream through fluid towards the inflow end of cylinder. As quickly as possible, shaft releases pressure on spring to allow valve to close, in part due to pressure flow against the poppet. Valve is released to flow longitudinally through cylinder to demonstrate the speed of the flow. At the end of the stroke, as valve has now moved downstream within cylinder, the valve will reopen to allow flow to continue. Disruptions upon valve closure and opening can impact readings of flow, as well as cause possible cavitation leading to unwarned noise and vibrations in the prover. At end of upstream stroke, the improved poppet design can utilize more flow pressure to close the poppet faster. The sooner closure the sooner a measure can be taken. This allows the measurement cycle to be completed over a longer period of time (greater volume). By doing so, more of the stroke can be used, such as at the end of the upstream stroke and the beginning of the downstream stroke as the valve is closed the instantaneous release of pressure from the rod and spring will close the valve as it is beginning its movement downstream. The faster the closure of the valve, the more length of the cylinder can be used tor testing.
Referring now to
Poppet valve is further coupled with support 40 via spring 82 which interfaces with disk 50 (shown in
As can be seen with more detail in the closeup cross-sectional view of
Referring now to the prior art shown in
As can be seen in
Referring now to an exploded view of poppet valve 35 of an embodiment of the present invention shown in
A cross-sectional exploded view of a portion of alternative embodiment of the poppet disk engaging a surface of an alternative ring (similar to view area of embodiment shown in
As can be seen in
As can be seen with particularity for the seal, in
As can be shown in
A further advantage of the present invention is demonstrated in the cross-sectional view of the embodiment shown in
As is shown in contrast of
Alternative embodiments of the present invention are demonstrated in
Poppet is preferably in accordance with one embodiment of the present invention a 3/16ths inch fixed stainless steel. Poppet may be manufactured into the shape or conically popped from a sheet. Manufacture of poppet can reduce the current poppet volume (e.g. by approximately 75% and/or reduction in mass of approximately 75%). During seal replacement maintenance, support can remain bolted to spring, and provides compression on spring. Retention ring may be pulled off and valve providing access to seal and poppet without removing mount support from spring. Fasteners for ring may include screws, possibly with a thread locker (glue). Seal may be comprised of reinforced Teflon PTFE or UHMW, or otherwise.
The new designed poppet may be any concave shape rather than a flat shape of the current valve disks. The slope on the edges of the poppet may provide for a smoother flow velocity to provide less cavitation, and/or to provide less noise in system.
The present application includes subject matter disclosed in and claims priority to a provisional application entitled “Improved Prover Poppet Design and Seal Retention System” filed May 11, 2017 and assigned Ser. No. 62/504,725 describing an invention made by the present inventor, herein incorporated by reference.
Number | Date | Country | |
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62504725 | May 2017 | US |