Patent Grant
6920925
The present invention relates to wellhead equipment, and to a wellhead tool for isolating wellhead equipment from the extreme pressures and abrasive materials used in oil and gas well stimulation.
Oil and gas wells often require remedial actions in order to enhance production of hydrocarbons from the producing zones of subterranean formations. These actions include a process called fracturing whereby fluids are pumped into the formation at high pressures in order to break up the product bearing zone. This is done to increase the flow of the product to the well bore where it is collected and retrieved. Abrasive materials, such as sand or bauxite, called propates are also pumped into the fractures created in the formation to prop the fractures open allowing an increase in product flow. These procedures are a normal part of placing a new well into production and are common in older wells as the formation near the well bore begins to dry up. These procedures may also be required in older wells that tend to collapse in the subterranean zone as product is depleted in order to maintain open flow paths to the well bore.
The surface wellhead equipment is usually rated to handle the anticipated pressures that might be produced by the well when it first enters production. However, the pressures encountered during the fracturing process are normally considerably higher than those of the producing well. For the sake of economy, it is desirable to have equipment on the well rated for the normal pressures to be encountered. In order to safely fracture the well then, a means must be provided whereby the elevated pressures are safely contained and means must also be provided to control the well pressures. It is common in the industry to accomplish these requirements by using a ‘stinger’ that is rated for the pressures to be encountered. The ‘stinger’ reaches through the wellhead and into the tubing or casing through which the fracturing process is to be communicated to the producing subterranean zone. The ‘stinger’ also commonly extends through a blow out preventer (BOP) that has been placed on the top of the wellhead to control well pressures. Therefore, the ‘stinger’, by its nature, has a reduced bore which typically restricts the flow into the well during the fracturing process. Additionally, the placement of the BOP on the wellhead requires substantial ancillary equipment due to its size and weight.
It would, therefore, be desirable to have a product which does not restrict the flow into a well during fracturing and a method of fracturing whereby fracturing may be safely performed, the wellhead equipment can be protected from excessive pressures and abrasives and the unwieldy BOP equipment can be eliminated without requiring the expense of upgrading the pressure rating of the wellhead equipment. It would also be desirable to maintain an upper profile within the wellhead that would allow the use of standard equipment for the suspension of production tubulars upon final completion of the well.
The present invention is directed to a wellhead isolation tool and to a wellhead assembly incorporating the same. The present invention in an exemplary embodiment provides for a wellhead isolation tool, also referred to as a “frac mandrel” that cooperates with a relatively low pressure wellhead to accommodate the elevated pressures encountered during the fracturing process by taking advantage of the heavier material cross-section present in the lower end of wellhead equipment and by isolating the weaker upper portions of the wellhead from high fracturing pressures. Said tool provides a full diameter access into the well bore, thus enhancing the fracturing process, and may be used with common high pressure valves to provide well pressure control. The invention further provides for retention of standard profiles within the upper portion of the wellhead allowing the use of standard tubing hangers to support production tubing within the completed well.
In an exemplary embodiment of the invention, a wellhead device is provided that is operable with a conventional high pressure valve for controlling well pressure having at least one string of tubulars. The wellhead device consists of a wellhead body member and a cooperating wellhead isolation tool.
A wellhead body member is provided with an internal through bore communicating with the upper end of a string of tubulars. The lower end of the wellhead body member may be provided with a means to threadedly engage the tubulars, be welded to the tubulars, or slipped over the tubulars and otherwise sealed. The upper end of wellhead body member may be provided with a flanged connection or otherwise furnished with an alternative means of connecting completion equipment, and is further provided with an internal through bore preparation, known in the art as a bowl, to allow suspension of production tubulars. An intermediate connection or connections, either threaded or studded flange, is provided within the wall of the wellhead body member affecting a transverse access port to the annular area between the wellhead body member and the production tubulars. A through bore preparation of the wellhead body member is provided between the transverse access port and lower end tubular accommodation that cooperates with lower end and seals of the wellhead isolation tool. The upper flanged end of the wellhead body member is provided with a plurality of radial threaded ports. Said radial ports are provided with cooperating threaded devices, commonly referred to as lock screws, for the purpose of retaining equipment within the upper bowl of the wellhead body member. The quantity of these lock screws is determined by the pressure rating of the wellhead body member in combination with other parameters.
The exemplary embodiment wellhead isolation tool, is provided with a through bore that equals the through bore of the wellhead tubulars, thus maximizing flow characteristics through the tool. The upper end of the wellhead isolation tool is provided with a flange rated to accommodate fracturing pressures and suitable for the installation of equipment pertinent to the fracturing process. The outer surface of the lower end of wellhead isolation tool cooperates with the lower bore preparation of the wellhead body member and is equipped with a pair of seals that provide isolation of the through bore of the wellhead isolation tool from the upper bore area of the wellhead body member. A radial threaded port is provided in the wall of the wellhead body member in such a location as to provide a means to test the effectiveness of the isolation seals of the wellhead isolation tool after it is installed in the wellhead body member.
In a first exemplary embodiment, the mediate portion of the wellhead isolation tool is provided with an external profile that cooperates with the upper bowl profile of the wellhead body member to establish the proper vertical positioning of the wellhead isolation tool. The outside periphery of this embodiment of the wellhead isolation tool is provided with a pair of grooves formed in the shape of a truncated “V”. The resulting lower conic surface of the lowermost “V” groove cooperates with frustroconical ends of the lock screws when the lock screws are threaded into place through their cooperating ports in the flange of the upper end of the wellhead body member to affect retention of the wellhead isolation tool within the wellhead body member. In order to provide the additional strength required to adequately retain the wellhead isolation tool within the wellhead body member, an additional flange, known in the art as a secondary tie down flange, is provided that cooperates with the upper flange of the wellhead body member by a plurality of bolts or studs installed through matching holes machined in the flanges. This additional flange is also provided with a plurality of radial threaded ports in which cooperating lock screws are installed to provide additional retention capacity of the wellhead isolation tool. The frustroconical ends of the latter lock screws cooperate with the lower conic surface of the uppermost “V” groove provided in the wellhead isolation tool to provide the additional strength required to adequately retain the wellhead isolation tool within the wellhead body member. It will be recognized that the additional flange could be furnished as an integral part of the wellhead isolation tool.
In another exemplary embodiment of the wellhead isolation tool, the mediate portion of the tool is provided with an external profile that acts independently from the upper bowl profile of the wellhead body member and with a mounting flange that is threadedly connected to the wellhead solation tool. This allows the wellhead isolation tool to be more universal in its application. The lower end configuration of the second version of the wellhead isolation tool is the same as in the first exemplary embodiment and seals within the cooperating bore of the wellhead body member. As in the first exemplary embodiment, the mounting flange may be provided as an integral part of the wellhead isolation tool.
In another exemplary embodiment of the wellhead isolation tool of the present invention, the wellhead isolation tool penetrates a tubing head and a mandrel casing hanger which is seated within a casing head. A portion of the tubing head also penetrates the mandrel casing hanger. A latch and a top nut are used to retain mandrel casing hanger in the tubing head. The wellhead isolation tool seals at its lower end against the mandrel casing hanger.
In yet a further exemplary embodiment, the wellhead isolation tool penetrates a combination tubing head/casing head and seals against a casing hanger which is seated within the tubing head/casing head combination. The casing hanger is retained within the tubing head/casing head combination by a latch and a top nut. The wellhead isolation tool seals at its lower end against the casing hanger. The top nut used with any of the aforementioned embodiments can have an expanded upper portion for the landing of additional wellhead equipment.
These and other features and advantages will be become apparent from the appended drawings and detailed description.
Referring now to the drawings and, particularly, to
The tubing head assembly 20 includes a body member referred to herein as the “tubing head” 22. The upper end 14 of casing head 13 cooperates with a lower end 24 of body member 22 whether by a flanged connection as shown or by other means. A production casing 18 is suspended within the well bore 15 by hanger 16. The upper end of production casing 18 extends into the body member and cooperates with the lower bore preparation 28 of body member 22. The juncture of production casing 18 and lower bore preparation 28 is sealed by seals 32. The seals 32 which may be standard or specially molded seals. In an exemplary embodiment, the seals are self energizing seals such as for example O-ring, T-seal or S-seal types of seals. Self-energizing seals do not need excessive mechanical forces for forming a seal.
Grooves 33 may be formed on the inner surface 35 of the body member 22 to accommodate the seals 32, as shown in
It will be recognized by those skilled in the art that the production casing 18 may also be threadedly suspended within the casing head 13 by what is known in the art as an extended neck mandrel hanger (not shown) whereby the extended neck of said mandrel hanger cooperates with the lower cylindrical bore preparation 28 of body member 22 in same manner as the upper end of production casing 18 and whose juncture with lower cylindrical bore preparation 28 of body member 22 is sealed in the same manner as previously described.
In the exemplary embodiment shown in
Now referring to
With the lock screw retracted, an exemplary embodiment wellhead isolation tool 60 is installed through cylindrical bore 92 in secondary flange 70 and into the body member 22. The exemplary embodiment wellhead isolation tool shown in
A radial flange 208 extends from an upper end of the wellhead isolation tool and provides an interface for connecting the upper assembly or fracturing tree 80 as shown in
The outer surface 210 of the well head isolation tool has an upper tapering portion 54 tapering from a larger diameter upper portion 218 to a smaller diameter lower portion 222. A lower tapering portion 220 extends below the upper tapering portion 54, tapering the outer surface of the wellhead isolation tool to a smaller diameter lower portion 222.
When the wellhead isolation tool is fitted into the body member through the secondary flange 70, the upper outer surface tapering portion 54 of the wellhead isolation tool mates with a complementary tapering inner surface portion 52 of the body member 22 as shown in
Now referring to
Now referring to
Cylindrical bores 34, 36 and 86 defined through the production casing 18, the exemplary embodiment wellhead isolation tool 60, and through an annular lip portion 87 the body member 22, respectively, are in an exemplary embodiment as shown in
Referring again to
Now referring to
Now referring to
As with the embodiment, shown in
Referring again to
While the wellhead isolation tool has been described with having an upper tapering portion 54 formed on its outer surface which mates with a complementary tapering inner surface 52 of the body member 22, an alternate exemplary embodiment of the wellhead isolation tool does not have a tapering outer surface mating with the tapering inner surface portion 52 of the body member. With the alternate exemplary embodiment wellhead isolation tool, as for example shown in
With any of the aforementioned embodiments, the diameter of the tubing head inner surface 291 (shown in
A further exemplary embodiment assembly 300 comprising a further exemplary embodiment wellhead isolation tool or frac mandrel 302, includes a lower housing assembly 10 also referred to herein as a casing head assembly, an upper assembly 80 also referred to herein as a fracturing tree, and intermediate body assembly 20 also referred to herein as a tubing head assembly, and the intermediate wellhead isolation tool 302 also referred to herein as a frac mandrel, as shown in
The mandrel casing hanger 306 has a second cylindrical outer surface 320 extending above the first cylindrical outer surface 312 having a diameter smaller than the diameter of the first cylindrical outer surface. A third cylindrical outer surface 322 extends from the second cylindrical outer surface and has a diameter slightly smaller than the outer surface diameter of the second cylindrical outer surface. External threads 324 may be formed on the outer surface of the third cylindrical surface of the mandrel casing hanger. An outer annular groove 326 is formed at the juncture between the first and second cylindrical outer surfaces of the mandrel casing hanger. Internal threads 328 are formed at the upper end of the inner surface of the casing head. An annular groove 330 is formed in the inner surface of the mandrel casing head.
The inner surface of the madrel casing hanger has three major sections. A first inner surface section 332 at the lower end which may be a tapering surface, as for example shown in
Body member 350 also known as a tubing head of the tubing head assembly 20 has a lower cylindrical portion 352 having an outer surface which in the exemplary embodiment threadedly cooperates with inner surface 354 of the third inner surface section of the mandrel casing hanger. A protrusion 356 is defined in an upper end of the lower cylindrical section of the body member 350 for mating with the counterbore 343 formed at the upper end of the third inner surface of the mandrel casing hanger. The body member 350 has an upper flange 360 and ports 362. The inner surface of the body member is a generally cylindrical and includes a first section 363 extending to the lower end of the body member. In the exemplary embodiment shown in
The wellhead isolation tool has a first external flange 370 for mating with the flange 360 of the body member of the tubing head assembly. A second flange 372 is formed at the upper end of the wellhead isolation tool for mating with the upper assembly 80. A generally cylindrical section extends below the first flange 370 of the wellhead isolation tool. The generally cylindrical section has a first lower section 374 having an outer surface diameter equal or slightly smaller than the inner surface diameter of the first inner surface section of the body member of the tubing head assembly. A second section 376 of the wellhead isolation tool cylindrical section extending above the first lower section 374 has an outer surface diameter slightly smaller than the inner surface diameter of the second section 365 of the body member 350 and greater than the outer surface diameter of the first lower section 374. Consequently, an annular shoulder 371 is defined between the two outer surface sections of the wellhead isolation tool cylindrical section. The well head isolation tool is fitted within the cylindrical opening of the body member of the tubing head assembly such that the flange 370 of the wellhead isolation tool mates with the flange 360 of the body member 350. When that occurs, the annular shoulder 371 defined between the two outer surface sections of the cylindrical section of the wellhead isolation tool mates with the portion of the first section inner surface 363 of the body member 350.
Prior to installing the mandrel casing hanger into the casing head, a spring loaded latch ring 380 is fitted in the outer groove 326 of the mandrel casing hanger. The spring loaded latch ring has a generally upside down “T” shape in cross section comprising a vertical portion 382 and a first horizontal portion 384 for sliding into the outer annular groove 326 formed on the mandrel casing hanger. A second horizontal portion 386 extends from the other side of the vertical portion opposite the first horizontal portion.
The spring loaded latch ring is mounted on the mandrel casing hanger such that its first horizontal portion 384 is fitted into the external groove 326 formed in the mandrel casing hanger. The spring loaded latch ring biases against the outer surface of the mandrel casing hanger. When fitted into the external annular groove 326 formed in the mandrel casing hanger, the outer most surface of the second horizontal portion 386 of the latch ring has a diameter no greater than the diameter of the first outer surface section 312 of the mandrel casing hanger. In this regard, the mandrel casing hanger with the spring loaded latch ring can be slipped into the casing head so that the tapering outer surface 310 of the mandrel casing hanger can sit on the tapering inner surface portion 308 of the casing head.
In the exemplary embodiment, once the mandrel casing hanger is seated onto the casing head, the body member 350 of the tubing head assembly is fitted within the casing head such that the lower section of the outer surface of the body member threads on the third section inner surface of the mandrel casing hanger such that the protrusion 356 formed on the outer surface of the body member is mated within the counterbore 343 formed on the upper end of the third section inner surface of the mandrel casing hanger. The wellhead isolation tool is then fitted with its cylindrical section within the body member 350 such that the flange 370 of the wellhead isolation tool mates with the flange 360 of the body member. When this occurs, the annular shoulder 371 formed on the cylindrical section of the wellhead isolation tool mates with the first section 363 of the inner surface of the body member 350. Similarly, the lower outer surface section of the cylindrical section of the wellhead isolation tool mates with the inner surface second section 334 of the mandrel casing hanger. Seals 388 are provided in grooves formed 390 on the outer surface of the lower section of the cylindrical section of the wellhead isolation tool to mate with the second section inner surface of the mandrel casing hanger. In the alternative, the seals may be positioned in grooves formed on the second section inner surface of the mandrel casing hanger. In the exemplary embodiment, the seals are self-energizing seals, as for example, O-ring, T-seal or S-seal type seals.
A top nut 392 is fitted between the mandrel casing hanger upper end portion and the upper end of the casing head. More specifically, the top nut has a generally cylindrical inner surface section having a first diameter portion 394 above which extends a second portion 396 having a diameter greater than the diameter of the first portion. The outer surface 398 of the top nut has four sections. A first section 400 extending from the lower end of the top nut having a first diameter. A second section 402 extending above the first section having a second diameter greater than the first diameter. A third section 404 extending from the second section having a third diameter greater than the second diameter. And a fourth section 406 extending from the third section having a fourth diameter greater than the third diameter and greater than the inner surface diameter of the upper end of the mandrel casing hanger. Threads 408 are formed on the outer surface of the second section 402 of the top nut for threading onto the internal threads 328 formed on the inner surface of the upper end of the mandrel casing head. The top nut first and second outer surface sections are aligned with the first inner surface section of the top nut. In this regard, a leg 410 is defined extending at the lower end of the top nut.
The top nut is threaded on the inner surface of the casing head. As the top nut moves down on the casing head, the leg 410 of the top nut engages the vertical portion 382 of the spring loaded latch ring, moving the spring loaded latch ring radially outwards against the latch ring spring force such that the second horizontal portion 386 of the latch ring slides into the groove 330 formed on the inner surface of the casing head while the first horizontal portion remains within the groove 326 formed on the outer surface of the mandrel casing head. In this regard, the spring loaded latch ring along with the top nut retain the mandrel casing hanger within the casing head.
A seal 412 is formed on the third outer surface section of the top nut for sealing against the casing head. In the alternative the seal may be formed on the casing head for sealing against the third section of the top nut. A seal 414 is also formed on the second section inner surface of the top nut for sealing against the outer surface of the mandrel casing hanger. In the alternative, the seal may be formed on the outer surface of the casing hanger for sealing against the second section of the inner surface of the top nut.
To check the seal between the outer surface of the lower section of the cylindrical section of the wellhead isolation tool and the inner surface of the mandrel casing hanger, a port 416 is defined radially through the flange 370 of the wellhead isolation tool. The port provides access to a passage 415 having a first portion 417 radially extending through the flange 370, a second portion 418 extending axially along the cylindrical section of the wellhead isolation tool, and a third portion 419 extending radially outward to a location between the seals 388 formed between the lower section of the wellhead isolation tool and the mandrel casing hanger. Pressure, such as air pressure, may be applied to port 416 to test the integrity of the seals 388. After testing the port 416 is plugged with a pipe plug 413.
With any of the aforementioned exemplary embodiment wellhead isolation tools, a passage such as the passage 415 shown in
The upper assembly is secured on the wellhead isolation tool using methods well known in the art such as bolts and nuts. Similarly, an exemplary embodiment wellhead isolation tool is mounted on the tubing head assembly using bolts 409 and nuts 411.
In another exemplary embodiment assembly of the present invention shown in
With this exemplary embodiment, a mandrel casing hanger 452 is mated and locked against the body member 420 using a spring loaded latch ring 432 in combination with a top nut 434 in the same manner as described in relation to the exemplary embodiment shown in
Once the wellhead isolation tool 422 is seated on the body member 420, a segmented lock ring 440 is mated with the wickers 430 formed on the outer surface of the body member. Complementary wickers 431 are formed on the inner surface of the segmented lock ring and intermesh with the wickers 430 on the outer surface of the body member. In an alternate embodiment, the segmented lock ring may be threaded to a thread formed on the outer surface of the body member. An annular nut 442 is then threaded on the threads 428 formed on the outer surface of the intermediate flange 424 of the wellhead isolation tool. The annular flange has a portion 444 that extends over and surrounds the segmented lock ring. Fasteners 446 are threaded through the annular nut and apply pressure against the segmented locking ring 440 locking the portion of the annular nut relative to the segmented lock ring.
An internal thread 448 is formed on the lower inner surface of the annular nut 442. A lock nut 450 is threaded onto the internal thread 448 of the annular nut and is sandwiched between the body member 420 and the annular nut 442. In the exemplary embodiment shown in
Seals 460 are formed between a lower portion of the wellhead isolation tool 422 and an inner surface of the hanger 452. This is accomplished by fitting seals 460 in grooves 462 formed on the outer surface of the wellhead isolation tool 422 for sealing against the inner surface of hanger 452. Alternatively the seals may be fitted in grooves formed on the inner surface of the hanger 452 for sealing against the outer surface of the wellhead isolation tool. To check the seal between the outer surface of the wellhead isolation tool 422 and the inner surface of the hanger 452, a port 465 is defined through the flange 426 of the wellhead isolation tool and down along the well head isolation tool to a location between the seals 460 formed between the wellhead isolation tool and the hanger 452.
The inner surface of the mandrel casing hanger has three major sections. A first inner surface section 332 at the lower end which may be a tapering surface, as for example shown in
With any of the aforementioned embodiment, one or more seals may be used to provide the appropriate sealing. Moreover, any of the aforementioned embodiment wellhead isolation tools and assemblies provide advantages in that they isolate the wellhead or tubing head body from pressures of refraction in process while at the same time allowing the use of a valve instead of a BOP when forming the upper assembly 80. In addition, by providing a seal at the bottom portion of the wellhead isolation tool, each of the wellhead isolation exemplary embodiment tools of the present invention isolate the higher pressures to the lower sections of the tubing head or tubing head/casing head combination which tend to be heavier sections and can better withstand the pressure loads. Furthermore, they allow for multiple fracturing processes and allow the wellhead isolation tool to be used in multiple wells without having to use a BOP between fracturing processes from wellhead to wellhead. Consequently, multiple BOPs are not required when fracturing multiple wells.
The wellhead isolation tools of the present invention as well as the wellhead assemblies used in combination with the wellhead tools of the present invention including, among other things, the tubing heads and casing heads may be formed from steel, steel alloys and/or stainless steel. These parts may be formed by various well known methods such as casting, forging and/or machining.
While the present invention will be described in connection with the depicted exemplary embodiments, it will be understood that such description is not intended to limit the invention only to those embodiments, since changes and modifications may be made therein which are within the full intended scope of this invention as hereinafter claimed.
This application claims priority and is based upon Provisional Application No. 60/357,939, filed on Feb. 19, 2002, the contents of which are fully incorporated herein by reference.
| Number | Name | Date | Kind |
|---|---|---|---|
| 3166125 | Hubby | Jan 1965 | A |
| 4241786 | Bullen | Dec 1980 | A |
| 4867243 | Garner et al. | Sep 1989 | A |
| 4991650 | McLeod | Feb 1991 | A |
| 4993489 | McLeod | Feb 1991 | A |
| 5060723 | Sutherland et al. | Oct 1991 | A |
| 5103900 | McLeod et al. | Apr 1992 | A |
| 5143158 | Watkins et al. | Sep 1992 | A |
| 5236037 | Watkins | Aug 1993 | A |
| 5285852 | McLeod | Feb 1994 | A |
| 5289882 | Moore | Mar 1994 | A |
| 5372202 | Dallas | Dec 1994 | A |
| 5490565 | Baker | Feb 1996 | A |
| 5540282 | Dallas | Jul 1996 | A |
| 5605194 | Smith | Feb 1997 | A |
| 5819851 | Dallas | Oct 1998 | A |
| 5927403 | Dallas | Jul 1999 | A |
| 5975211 | Harris | Nov 1999 | A |
| 6039120 | Wilkins et al. | Mar 2000 | A |
| 6092596 | Van Bilderbeek | Jul 2000 | A |
| 6179053 | Dallas | Jan 2001 | B1 |
| 6196323 | Moksvold | Mar 2001 | B1 |
| 6199914 | Duhn | Mar 2001 | B1 |
| 6220363 | Dallas | Apr 2001 | B1 |
| 6260624 | Pallini, Jr. et al. | Jul 2001 | B1 |
| 6289993 | Dallas | Sep 2001 | B1 |
| 6360822 | Robertson | Mar 2002 | B1 |
| 6364024 | Dallas | Apr 2002 | B1 |
| 6516861 | Allen | Feb 2003 | B2 |
| 6688386 | Cornelssen et al. | Feb 2004 | B2 |
| 6712147 | Dallas | Mar 2004 | B2 |
| 20020062964 | Allen | May 2002 | A1 |
| 20020100592 | Garrett et al. | Aug 2002 | A1 |
| 20020117298 | Wong et al. | Aug 2002 | A1 |
| 20020125005 | Eslinger et al. | Sep 2002 | A1 |
| 20020185276 | Muller et al. | Dec 2002 | A1 |
| 20020195248 | Ingram et al. | Dec 2002 | A1 |
| 20030000693 | Couren et al. | Jan 2003 | A1 |
| 20030019628 | Ravensbergen et al. | Jan 2003 | A1 |
| 20030024709 | Cuppen | Feb 2003 | A1 |
| Number | Date | Country | |
|---|---|---|---|
| 20030221823 A1 | Dec 2003 | US |
| Number | Date | Country | |
|---|---|---|---|
| 60357939 | Feb 2002 | US |
