This invention is directed to an injection valve typically used in conjunction with an injection well. Injection wells are drilled for example in close proximity to hydrocarbon producing wells that have peaked in terms of their output. Fluid for example water is pumped under pressure into an injection well to maintain the pressure of the underlying formation as the well is produced. Injected water acts to force the hydrocarbons into adjacent producing wells thus increasing the yield.
U.S. Pat. No. 7,866,401 discloses an injection safety valve having a restrictor, also known as an orifice, create a pressure differential so as to move a flow tube past a flapper valve. The diameter of the restrictor is fixed.
A problem with injection valves is a phenomenon known to those of normal skill in the art as “chattering”. Chattering occurs when the injection rate is insufficient to allow the valve to fully open, whereby the flow across the fixed orifice (the standard in injection valves) is too low to compress the power spring and shift the flow tube into a position to hold the flapper into the fully open and protected position.
Chattering causes the flapper to intermittently and rapidly slam into the flapper seat causing premature failure of either the flapper and/or seat. Such failure can cause an unsafe well condition necessitating premature, immediate shut in of the well, and expensive well remediation—sometimes costing tens of millions of dollars in the instance of subsea wells.
One embodiment of the invention includes providing a tubing retrievable injection valve having a full bore internal diameter when running and retrieving the valve. A “slick-line” or “wireline” retrievable “nozzle assembly” having an orifice is carried by and affixed in the wellbore by a lock assembly. The nozzle assembly is retrievable without removing the injection valve. Consequently the diameter of the nozzle may be changed on the surface. The injection valve also has a temporary lock out feature so that the valve may be placed in the well in a lock out mode. In certain situations where the flow rate of the water may vary, an embodiment of the invention includes a nozzle assembly with a variable orifice to provide an infinitely variable downhole nozzle. The nozzle is designed to generate a pressure drop sufficient to hold the flapper valve fully open. This prevents the flapper valve from “chattering” and isolates the flapper valve from fluid flow during injection both of which are harmful to the flapper valve assembly.
Additionally, in yet further embodiment of the invention, a pair of opposite pole magnets are provided. One magnet is attached to an upper sleeve of the nozzle assembly and a second magnet is attached to a middle sleeve member which carriers a variable orifice. In the run-in position, the flapper valve is locked out and the variable orifice insert permits flow of liquid in both directions. In the set position within the well, the upper sleeve and middle sleeve are locked together and injection into the well is permitted. Once the flowrate is decreased at the surface, the variable orifice insert resets into the fully closed position while a return spring returns the flow tube to the initial position allowing the flapper to close. Once injection resumes, the differential pressure across the variable orifice insert is very high because it's held in a closed position by the strong magnets. Hence the variable orifice insert moves to a position which opens the flapper valve before any flow is established through the injection valve. In this manner, no flapper chattering is possible. As the injection flow rate is increased, the variable orifice insert will open a greater area in response to the flow rate to allow more flow to pass through the internal restriction. As the restriction is opened by flow, the magnet force is decreased allowing very low operational differential pressure during operation. The operating differential pressure must be above the opening differential pressure for the flow tube and flapper valve to stay open during injection. When the injection flowrate is decreased, the flapper will close thus protecting the valve surface from produced injection water.
The variable output nozzles are designed so that as flow occurs, the flow tube will first move in a direction to open the flapper valve and then the output area of the nozzle will increase with increased flow rates.
The nozzle assembly can either be run pre-installed in the injection valve prior to running or after the injection valve has been set, utilizing wireline/slickline operations to insert and or remove the nozzle assembly from the injection valve.
A further embodiment of the invention is directed to a wireline retrievable injection valve that includes a flapper valve at one end and an axially movable sleeve within which is mounted to a second valve. The second valve is pressure responsive and includes a variable orifice.
According to another embodiment of the invention, the valve may be designed as a flapperless injection valve thus simplifying the design and construction of the valve.
Referring to
The injection valve 10 further includes an upper flow tube having a first section 17 and a second section 14 which are secured together. Section 17 has an interior nipple profile at 16 for receiving a tool. Section 14 has an elongated sleeve portion 19 that extends to valve seat 26 when the valve is in the position shown in
Middle body member 12 has a reduced diameter portion 25 that carries an annular valve seat 26. A flapper valve 27 is pivotably connected at 28 to valve seat 26 and is resiliently biased to a closed position on valve seat 26 as is known in the art.
A coil spring 18 is positioned about elongated sleeve portion 19 and is captured between shoulder 14 of the upper flow tube and an internal shoulder 41 provided within middle valve body member 12.
In the temporary lock out running position shown in
When the valve is positioned within the well at the desired location, a suitable running tool is lowered into the well and engages the upper shifting profile 39 of shiftable flow tube 31 and the flow tube is moved upwardly, to the position shown in
The retrievable nozzle selective lock assembly (RNSLA) will now be discussed with reference to
The next step in the process is to pump a fluid such as water under pressure into the valve body. As the fluid flows through the RNSLA, a pressure drop will occur across orifice 54 which will cause the RNSLA and upper flow tube assembly 15, 14, as well as shiftable flow tube 31 to move downhole as shown in
This movement will compress spring 18. The downhole portions of both the upper flow tube and lower flow tube will be forced into contact with flapper valve 27 and as they are moved further by the pressure differential, they will open the flapper valve to the position as shown in
As long as the fluid is being pumped the injection valve will remain open. However when the pumping stops, compressed spring 18 will move the RNSLA and the upper and lower flow tubes back to the position shown in
Variable output nozzle assembly 100 includes an outer tubular cylindrical casing 101. An axially moveable cylindrical sleeve 103 having an enlarged portion 107 is positioned within casing 101 and has an end face 114 that extends outwardly of casing 101. Sleeve 103 has an interior flow passage 105 and also has a plurality of outlet ports 104 that are axially and radially spaced about its longitudinal axis. Sleeve 103 terminates in an end face 116 that includes an outlet orifice 115. A coil spring 102 is positioned between the inner surface of casing 101 and the outer surface of sleeve 103 as shown in
At lower flow rates, the pressure drops across orifice 115 will be sufficient to move the lower flow tube to a position keeping flapper valve 27 open. As the flow rate increases, sleeve 103 is moved axially to sequentially move outlet ports 104 past the end face 109 of casing 101 as shown in
The spring constants of springs 18 and 102 are chosen so that as fluid flow begins, the RNSLA will first move in a downhole direction opening the flapper valve before sleeve 103 moves in a downhole direction.
In this embodiment the variable output nozzle assembly includes a first fixed portion including a cylindrical tubular casing 124 having a solid conical core member 139 supported therein by a plurality of struts 129 as shown in
As the flow rate of fluid is increased, outer sleeve member 120 will move to the right as viewed in
The embodiments according to
The variable output nozzles of
In the position shown in
An axially movable valve assembly 250 shown in
Nozzle 215 has a converging inlet section 216, a throat portion 261 and a diverging outlet section 208. Nozzle 215 moves axially with the second valve assembly between shoulder 230 in inlet portion 204 and a shoulder 231 formed on intermediate portion 221 of the second valve assembly as shown in
Second valve assembly 250 includes an elongated sleeve 223 coupled to intermediate portion 221 for example by threads. Sleeve 223 is adapted to move downwardly to open flapper valve 224 as shown in
In operation, injection fluid is pumped through the well head into tubular string 403 in which valve 406 is located. As shown in
Fluid pressure will initially cause second valve assembly 250 to move downwardly to the position shown in
Yet a further embodiment of the invention is illustrated in
Main body portion 301 has an upper connection 325 suitable for connection to a wireline lock 411 for example. The valve includes an inlet 309 and outlet 323 for the injection fluid. A solid tear-shaped body 302 is fixed within the main body housing 301 by a plurality of struts 303. A nozzle member 304 includes a converging inlet 308 and a diverging outlet 311. A valve seat 305 is formed between the conveying and diverging portions of the nozzle and cooperates with body 302 to form a variable constricted flow passage through the valve as nozzle 304 moves axially. Nozzle 304 is moved downwardly against spring 306 in spring chamber 307 by a pressure differential. Spring 306 is captured between a shoulder 310 on the exterior surface of the nozzle and a step 312 formed on the upper end of lower body housing 322.
When fluid is pumped down to the valve, nozzle 304 will move downwardly to open up an annular fluid passageway between body 302 and nozzle 304. When fluid flow is terminated, spring 306 which is compressed as nozzle 304 is moved downwardly will shift nozzle 304 in an upward direction thus bringing surface 305 into contact with body 302 thereby closing the annular fluid passageway and preventing flow back of fluid.
The RNSCA includes an upper sleeve 501 have a standard internal fishing neck profile 510. A middle sleeve 508 is attached to upper sleeve 501 by a plurality of pins 506. A first set of magnets 502 is positional between the upper and middle sleeves. Middle sleeve 508 terminates in a tapered valve seat 516. An outer sleeve member 521 is axially movable with respect to middle sleeve 508. A pair of magnets 503 are attached to outer sleeve member 521 and move with the sleeve 521. Magnets 502 and 503 have opposite poles that attract each other. Pin 512 is secured to middle sleeve 508 and is positioned within a
J-slot 542 formed in outer sleeve 521.
A gap 504 is formed between upper sleeve 501 and outer sleeve 521. A slightly compressed spring 507 is positioned between middle sleeve 508 and outer sleeve 521 as shown in
The RNSCA includes a plurality of seals 532 and a locking tab 533. A lower sleeve 515 is attached to outer sleeve 521 by one or more pins 513. Lower sleeve 515 supports inner valve member 520 by a plurality of struts 514. A spring guide sleeve 518 surrounds middle sleeve 508.
In the resetting position of
This allows outer sleeve 521 and valve body 520 to move upwardly thereby closing the valve. The valve is now ready for operation as shown in
In this position the flapper valve 27 and the variable orifice insert are both in the fully closed position thus providing a dual barrier check valve for any fluid flowing out of the well. When injection resumes, the differential pressure developed across the insert is relatively high because it's held closed by the magnets. The variable orifice insert opens the flapper valve before any flow is established through the tool.
Consequently no flapper chattering is possible. As the flow rate is increased, the variable orifice inset will open to allow flow to pass through the variable orifice. As the orifice is opened by the flow, the magnetic force is decreased allowing very low operational differential pressure during injection operation. The operating differential pressure must be above the opening differential pressure for the flow tube and flapper system to stay open during injection. When the injection flowrate is decreased below a certain valve, the flapper will close protecting the surface from produced injection water.
The opening of the valve due to fluid flow is resisted by the spring force as it is displaced, by the spring pre load-force and by the magnetic force. These forces balance each other with the result that a low operating differential pressure is maintained which results in higher injection efficiency.
The horizontal axis is the injection flowrate and the vertical axis represents the differential pressure across the orifice.
With a fixed orifice nozzle, as the flowrate increases and the pressure differential is below 20 psi, the flapper element will chatter as shown in the shaded area until the opening differential pressure is above 20 psi.
Also the fixed orifice will take significantly higher flow to attain the required opening differential pressure. Also, the fixed orifice will require an even higher flow for re-setting the flow tube. Potentially, the re-setting differential pressure might not be achieved at all rendering the system useless.
In contrast, the variable nozzle of the present invention does not open until the flapper valve is moved to an open and protected position thereby completely eliminating chatter.
The variable orifice allows the user to re-set the valve with minimal flow and will consequently always operate above the flapper chattering zone.
Magnets 502 and 503 may be made of rare earth materials. The various sleeves and housing may be formed of austenitic stainless steels. The portion of the assembly susceptible to erosion, for example, the valve body 520 and lower sleeve 515 could be made of erosion resistant material such as tungsten carbide, ceramic material, hard faced carbon steel, hipped zirconium and stellite.
All of the embodiments may be deployed or retrieved using a wireline or slickline and are easily redressable and repairable. Furthermore, when injection flow is stopped the valve automatically will close, thereby protecting the upper completion from back flow or a blowout condition.
Although the present invention has been described with respect to specific details, it is not intended that such details should be regarded as limitations on the scope of the invention, except to the extent that they are included in the accompanying claims.
This application is a continuation of U.S. application Ser. No. 15/353,495 filed Nov. 16, 2016 which is a continuation of U.S. application Ser. No. 14/697,289 filed Apr. 27, 2015 which is a continuation-in-part of a U.S. application Ser. No. 13/863,063 filed on Apr. 15, 2013, which is a continuation-in-part of Ser. No. 13/669,059 filed on Nov. 5, 2012 which is a non-provisional of 61/639,569 filed on Apr. 27, 2012, the entire contents of the above identified patent applications are expressly incorporated herein by reference thereto in their entirety.
Number | Date | Country | |
---|---|---|---|
61639569 | Apr 2012 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 15353495 | Nov 2016 | US |
Child | 15862434 | US | |
Parent | 14697289 | Apr 2015 | US |
Child | 15353495 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13863063 | Apr 2013 | US |
Child | 14697289 | US | |
Parent | 13669059 | Nov 2012 | US |
Child | 13863063 | US |