This technology relates generally to sealing the through-bore of a plug valve suited for high pressure oil and gas production systems.
Generally, a valve forms a flow passage and has a selectively operable closure to open or close the flow passage in order to control a flow of fluid through the valve. The sealing integrity of high pressure valves must withstand not only high operating fluid pressures, which could be 5,000 pounds per square inch and higher, but also must do so while controlling the flow of corrosive and/or abrasive fluids that are notorious for eroding the valve internal components in the oil and gas industry. While 5,000 psi is listed herein, it should be understood that valves of this type are often subjected to working pressures of 10,000 psi, 15,000 psi, or more. The 5,000 psi number should only be considered a “floor”, below which conditions would not be considered “high pressure” in the hydraulic fracturing and oil and gas industries.
Illustrative embodiments herein are directed to a plug valve although the contemplated embodiments are not so limited. In a plug valve the flow passage typically includes a valve body in fluid communication with two or more openings, typically an inlet opening and an outlet opening, forming a flow passage through the valve body. A valve plug and insert segments, one type of a valve closure that is described herein, are disposed in a valve body bore between the inlet and outlet openings where sealing occurs between the plug, the insert, and the bore.
The valve plug defines a through-opening and is selectively rotatable to an open position where the through-opening is aligned with the flow passage to permit a flow of fluid through the valve (from the inlet to the outlet), or to a closed position where the through-opening is misaligned with the flow passage to prevent the flow of fluid through the valve. Fluid travelling through the valve is often a fracturing fluid or “frac” fluid. Such fluid is water-based, but includes additives that assist in the fracturing of a downhole formation. These additives may include acids, such as hydrochloric acid. They may also include corrosion or scale inhibitors. Finally, frac fluid often includes suspended “proppants”—often sand or silica—which is used to “prop” open fissures in downhole formations. Such proppants enable additives to reach deeper into formations in oil and gas operations.
Operating a valve at high pressure conditions with acidic fluid containing abrasive proppant material can cause erosion of the location where the seal in the insert contacts the bore, often resulting in leakage in a week. Repairing the valve body, such as by a weld build-up and machining operation, is a cumbersome and disruptive repair in the oilfield.
For this reason, it is advantageous to transfer the wear from the valve body to smaller, replaceable parts like the aforementioned inserts. By transferring the seating location of the seal from the insert to the valve body, the wear associated with the seal is moved from the valve body to the seal. While challenges exist in forming such a seal groove, the following description is of one such seal groove formed in a valve body to improve the hierarchy of wear in a valve body.
The present invention is directed to a valve comprising a valve body, at least two elongate inserts and a rotatable plug. The valve body has a valve chamber formed therein. The valve chamber also has a pair of opposed ports formed therein, each port communicating with a fluid conduit. The inserts cooperate to form a cage positioned within the valve chamber. Each insert has a convex surface that is interrupted by a fluid conduit that extends through the cage. The convex surface is bounded by edges formed at or near the longitudinal extremities of the insert. The rotatable plug is penetrated by a fluid conduit and positioned within the cage. A recess is disposed within the valve body about each of the opposed ports.
Inserts 106a, 106b in these illustrative embodiments are segments of an open hollow cone. Although two inserts 106a, 106b are depicted, the contemplated embodiments are not so limited because alternatively there can be more than two. In embodiments with more than two inserts 106a-b, there may be inserts without flow passages. The inserts with flow passages through them may be identically shaped and sized. As shown, each insert 106a, 106b has an outer conical surface 108a, 108b forming a matching taper to engage against the bore 104 in a close mating relationship. Each insert 106a-b is formed from a body having an inner surface and a spaced outer surface. The outer surface should have a shape complementary to that of the valve chamber. Preferably, the inner surface is concave, and the outer surface is convex.
A plug 110 has an outer diameter surface 112 sized to fill the space between the inserts 106a-b, mating with an inner diameter surface 114a, 114b of the respective inserts 106. As shown the plug 110 is partially cylindrical, and at least a portion of its outer surface is congruent with a portion of the curved side of a cylinder. The plug 110 has a journal 118 that is rotatable by a handle 120. A packing 122 seals against the journal 118 to contain the pressurized fluid inside the valve 100 while permitting an external force to rotate the journal 118 and, in turn, the plug 110. Alternatively the journal 118 can be rotated by a powered actuator. The plug no also has a second journal 126 that rotates within the body 102 and is sealed by packing 128.
Inserts 106a-b cooperate with and surround the plug 110. There may be two inserts 106a-b, as shown, or more inserts, where only two of the inserts 106a-b form a flow opening 129 (
The inserts 106a-b and rotatable plug 110 may be made from a durable metallic material. This may be the same or a different alloy than used in the valve body 102. Inserts 106a-b and the plug no being smaller and more simply formed than the valve body 102, are easier to treat. Inserts 106a-b and plug no can therefore be heat treated, treated with chemicals, or made with wear-resistant alloys in order to improve the life of the valve 100.
To enclose the plug no and support the journal 126, a retaining nut 121 may be threaded to the valve body 102. The retaining nut 121 seals to the valve body bore 104 by seal 146. The seal 146 may be situated in a groove formed either within the retaining nut 121 or in the valve body 102. Although a radial seal is depicted, in alternative embodiments an axial seal or a crush seal and the like can be used instead of or in addition to the radial seal 146.
The body 102 also defines a fluid flow path 116 intersecting the bore 104. The fluid flow path 116 has a longitudinal axis normal to the rotational axis of the plug is element and the axis of symmetry (if any) of the valve chamber 104. Each insert 106a-b may form an insert flow opening 129, and the inserts 106a-b are mounted in the valve 100 so that the insert openings 129 are aligned with the fluid flow path 116 and openings 130a-b formed in the valve body 102. The openings 130a-b may be an inlet or an outlet depending on the direction of fluid flow through the valve 100. The plug no forms a through-opening 132 permitting a user to selectively align the opening 132 with the openings 129 and 130a-b.
While the bore 104 and inserts 106a-b shown are a tapered cylinder (or, in other words, a conical frustum), the bore may instead be a right cylinder. Additionally, the inserts 106a-b may have a flat external surface to conform to a bore with a rectangular or square cross-sectional shape.
The body 102 is preferably formed of a high-strength metal material, such as steel. Forged steel provides the durability and strength necessary to operate in high-pressure conditions over 5000 psi. The plug valve 100 may be rated to as much as 10,000 psi, 15,000 psi, or more.
The openings 130a-b are each surrounded by a seal 140 seated in a groove 142. The groove is formed in the bore 104 of the valve body 102 at a uniform distance from the closest point on the boundary of its associated opening 130a-b. In this configuration, the seal 140 seats on three sides against the groove 142 and on a fourth side against a surface of the corresponding insert 106a-b. Wear due to interaction between the seal 140 and the surfaces it contacts is primarily on the insert 106a-b, rather than on the valve body 102. Previous designs, such as that found in U.S. Pat. No. 2,813,695 issued to Stogner, placed a seal in the insert, and caused the wear to be most prevalent on the valve body.
With reference now to
Likewise, the groove 142 is formed on the internal surface of the bore 104. The groove 142 is formed in the valve body 102 at a uniform distance from the closest point on the boundary of its associated opening 130a-b. As shown, the groove 142 is shaped as a circle projected onto the inner surface of a conical frustum. The cross-section of the groove 142 is substantially rectangular, with a bottom surface of the groove being parallel to the internally-disposed surface of the bore 104. The sides of the groove 142 are perpendicular thereto. Alternatively, the sides of the groove 142 may be parallel to the fluid flow path 116. The groove 142 may have a uniform depth.
Positioned in this way, the seal 140 (
Machining such a non-Euclidean groove 142 on the surface of a unitary valve body 102 requires precise and small tools, and is much more difficult than machining a similar shape on an insert 106a-b, as in prior art valves. However, any difficulty in machining is made up for in the transfer of the wear from the valve body 102 to a replaceable insert 106a-b.
Seals 140 are shaped differently than the inserts 106a-b. Seals 140 are generally elastomeric rings which may be seated in grooves such as groove 142. Inserts 106a-b, as described above, are metallic pieces which allow the plug to rotate within one or more of the inserts, while complementing the internal bore 104 of the valve body 102.
With reference now to
With reference to
A small pressure-relief port 204 allows high pressure fluid trapped within the through passage 132 of the plug 110 (
With reference to
With reference now to
The inserts 106a-b are disposed about the plug 110. The seals 140 are shown opposite the sealing surface 202 as grooves 142 are not shown in
The valve 100 comprises two ports 302. As shown, the ports 302 are integrally formed with the valve body 102. An adaptor 300 may be provided proximate the valve 100 for threaded attachment to pipes or other components.
With reference to
The valve body 308 may have a top port 320 for connection to handles, journals, and other internal components of the valve 100′. As shown in
Referring again to
Axial seals 346 are formed between the insert tubes 344 and the valve body 308 at the inlet port 304 and exit port 306. As shown, the seal 346 is seated in the valve body 308 at the inlet port 304. The seal 346 is seated in the insert tube 344 of the flange 311 at the exit port 306. This arrangement is shown for illustrative purposes only and is not limiting on the invention. Representative seals 346 may be o-rings.
Valve 100′ is similar to valve 100 (
In the arrangement of
With reference to
With reference to
Flanges 310, 311 are examples, and other embodiments are contemplated. For example, the surface 350 of flange 310 may be made larger such that it comprises a larger portion of the internal bore 309 wall in valve body 308. The internal bore 309 may be complementary to a rectangular prism such that square inserts are disposed between the plug and a flange having a flat surface 350.
In either the embodiment of
Number | Date | Country | |
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62486273 | Apr 2017 | US | |
62346915 | Jun 2016 | US | |
62318542 | Apr 2016 | US | |
62315343 | Mar 2016 | US | |
62234483 | Sep 2015 | US |
Number | Date | Country | |
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Parent | 15280642 | Sep 2016 | US |
Child | 15955128 | US |