US3924677A - Device for use in the completion of an oil or gas well - Google Patents
Device for use in the completion of an oil or gas well Download PDFInfo
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- US3924677A US3924677A US501622A US50162274A US3924677A US 3924677 A US3924677 A US 3924677A US 501622 A US501622 A US 501622A US 50162274 A US50162274 A US 50162274A US 3924677 A US3924677 A US 3924677A
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- improvement
- conduit member
- casing
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- plug
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- E—FIXED CONSTRUCTIONS
- E21—EARTH DRILLING; MINING
- E21B—EARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
- E21B43/00—Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
- E21B43/11—Perforators; Permeators
Definitions
- a water soluable plug initially blocks the bore of the conduit member, and the appa- [56] References cued ratus includes removable means on each end of the UNITED STATES PATENTS plug for preventing premature contact of water with 2,707,997 5/1955 Zandmer et al. 166/100 the plug, 2,708,000 5/1955 Zandmer 166/100 2,855,049 10/1958 Zandmer 166/100 16 Claims, 1 Drawing figure ylllllllllllll liflllg US. Patent Dec. 9, 1975 3,924,677
- the present invention concerns a device used in the completion of an oil or gas well, in particular a device which is destined to form a passage between the oilor gas-bearing strata and the interior of the wellc'asing.
- said device for oil well completion are as follows: they must be easily adaptable to the differences in depth and spacing of oil or gas strata, i.e. the said devices must be easily and quickly mountable at the required positions in the casing wall'at the drill' must permit any parts which extend into the casing to be quickly removed in order to leave the'casin'g entirely free for the passage of production tools.
- a connecting tool having a connector sleeve, mounted in, and transversely slidable relative to the casing wall by means of a spring mechanism held inactive al in k which adapted to be destroyed byachemical to release said 'mechanism to effect the connection between the casing and theoilbearing strata.
- the bore hole mustbe made considerably larger than the diametef of the casing in order to.
- the invention concerns a device used in the completion of an oil or gas well to provide a passage between the oilor gas-bearing strata and the interior of the well casing.
- the device comprises a member mounted in the casing wall, but held immovable therein during the loweringof the casing into the well and being adapted for sliding transversely outwardly therefrom to contact said strata.
- the member is hollow, is initially closed at its inner end, and is held in means screwed into a mounting sleeve which is attached by welding around the hole in the casing wall.
- the member includes a stopper nutcontaining a mixture of salt and epoxy resin, the mixture being protected during the circulation and cementing processes carried out to complete the well. Upon breaking of the inner end of said memher, the mixture will dissolve to provide a free passage between the casing and said strata through said memher.
- A' well casing 1 of known construction is provided with a hole 2 in its wall. This hole is made by means of a torch at the drilling site, the location of the hole and its spacing along the casing from other such holes being determined by means of conventional electronic log ging' equipment which determines the levels of the potential production strata.
- the mounting sleeve 3 for the device is welded in a manner so as to extend outwardly for not more than one-half inch.
- the sleeve 3 is provided with an internal screw thread which is counter-sunk at the outer edge.
- a bearing nut 4 to house the transveresely-sliding member 5 in its axial bore, is'screwed into mounting sleeve 3 from the outside.
- This bearing nut has a tapered outward flange 4a which sits in the counter-sunk part of sleeve 3.
- the bearing nut 4 has an axial conical depression 412 in its outer end and an axial internally threaded bore 4c at its inner end into which a check nut 6 is screwed.
- a peripheral groove 4d is made in the outer surface of bearing'nut 4 in the vicinity of the bottom of bore 40 for a purpose to be described hereinafter.
- the check nut 6 has an enlarges bore 6a surrounding its axial bore at its outer end, i..; the end facing theclosed toward the inside.
- a salt stopper nut 8 is screwed into the open outer end of member with the interposition of a substantially conical cup 9 held by its inner rim 9a between the member 5 and the stopper nut 8.
- This stopper nut has an outer conical flange 8a which sits in, and is guarded by, the cup 9 and which is provided in its central bore with a filter 8b of salt held together by epoxy resin and protected by means of grease inserted into the member 5.
- an outer peripheral groove is provided in which a retaining ring 10 is disposed.
- the ring prevents the member 5 from falling out of the casing in case the member 5 is too short to reach the strata and also holds in position an elastic friction sleeve 11 slipped onto the inner end of memberS.
- Internal grooves 42 and 6b are provided in bearing nut 4 and check nut 6, respectively to house O-rings 12 for preventing leakage and protecting check balls 7 against mud and cement, as will become clear hereinafter.
- a known flexiflow fill up collar, equipped with a shear plate, and a known rubber seal-off plate on top of the collar is added above the casing before the latter is lowered into the bore hole. Since, normally, the casing is empty or only partly filled during this lowering operation, the external pressure will hold the member 5 in place and prevent it from sliding outwardly prior to the circulation operation, which, conventionally is effected as soon as the casing is in place. At this stage the shear plate will have built up enough pressure to push the sliding member 5 outwardly, overcoming the resistance of sleeve 11.
- cementation of the annulus is performed, as known per se. During this operation the cup 9 protects the salt stopper nut 8. Following cementation. a cementing ball, as used in the known cement retainer and having the ability to float on the cement and to sink in the mud, is inserted on top of the cement, the size of the said ball being chosen so that it can pass by the parts of the device which protrude into the interior of the casing. Thereafter the displacement operation is carried out, at the end of which said ball will hit the known rubber seal-off plate, whereby an over displacement is prevented while sufficient pressure is built up to hold the sliding member 5 in its extended position. However, should this pressure be reduced for any reason, the check balls 7 will prevent the return of mem her 5 since they are forced by the slanted wall of bore against the wall of member 5 to hold it in place by friction.
- the improvement as claimed in claim 1 including restraining means to prevent the premature outward sliding of said conduit member.
- said restraining means comprising a plastic sleeve disposed around the outer surface of the inner end of said conduit member.
Abstract
Apparatus for providing a passage between an earth stratum and the interior of a well casing comprising a movable hollow conduit member mounted in the casing wall initially held retracted and immovable, while the casing is lowered, and subsequently, after the casing is set, extended outwardly from the casing wall to contact the stratum. A water soluable plug initially blocks the bore of the conduit member, and the apparatus includes removable means on each end of the plug for preventing premature contact of water with the plug.
Description
United States Patent 1191 1111 3,924,677
Prenner et al. 5] Dec. 9, 1975 DEVICE FOR USE IN THE COMPLETION 3,120,268 2/1964 Caldwell 166/100 OF AN OIL OR GAS WELL 3,312,280 4/1967 Koplin 166/100 3,322,199 5/1967 VanNote, Jr. 166/296 Inventors: Amnon nn r; Jacob Bear; David 3,434,537 3/1969 Zandmer 166/296 Tohar, all of Haifa, Israel; Harry Koplm Mlaml Primary Examiner.lames A. Leppink [73] Assignee: Harry Koplin, Miami, Fla.
[22] Filed: Aug. 29, 1974 i [57] ABSTRACT [21] Appl. No.: 501,622 Apparatus for providing a passage between an earth stratum and the interior of a well casing comprising a movable hollow conduit member mounted in the cas- CCll.2 ing wan initially held retracted and immovablebwhfle I the casing is lowered and subsequently, after the [58] Flow of Search 166/100 ing is set, extended outwardly from the casing wall to contact the stratum. A water soluable plug initially blocks the bore of the conduit member, and the appa- [56] References cued ratus includes removable means on each end of the UNITED STATES PATENTS plug for preventing premature contact of water with 2,707,997 5/1955 Zandmer et al. 166/100 the plug, 2,708,000 5/1955 Zandmer 166/100 2,855,049 10/1958 Zandmer 166/100 16 Claims, 1 Drawing figure ylllllllllllll liflllg US. Patent Dec. 9, 1975 3,924,677
The present invention concerns a device used in the completion of an oil or gas well, in particular a device which is destined to form a passage between the oilor gas-bearing strata and the interior of the wellc'asing.
There are known a number of methods for completing oil or gas wells, as well as devices used in'these methods. In general, the known methods comprise drilling a bore hole, lowering a casing provided with transversely mounted strata-connecting devices into the well, applying hydraulic pressure whereby-the said devices are extended to make contact with said permeable strata, and cementing the annulus by forcing cement from the interior of the casing downwardly and around its bottom into the annular space between the casing and the bore hole. After the cement has set, the part of the connecting devices which are located within the casing must be removed by drilling apparatus lowered into the casing, or by acids or other chemicals which dissolve this part without damaging either other parts of the devices or the casing itself.
The requirements of said device for oil well completion are as follows: they must be easily adaptable to the differences in depth and spacing of oil or gas strata, i.e. the said devices must be easily and quickly mountable at the required positions in the casing wall'at the drill' must permit any parts which extend into the casing to be quickly removed in order to leave the'casin'g entirely free for the passage of production tools.
claimed in US. Pat. No. 2,707,997, the connecting device used therein is supported in the casing wall by a screw thread. This necessitates, on the one hand, asufficiently thick casing wall to provide enough threads to support the device, and, on the'other hand, the tapping of a hole in the casing wall at the drill site, an operation which is complicated and expensive. Furthermore, the removal of the parts of the connecting device, which extend into the casing after the device has been released, must be carried out by drilling, which is timeconsuming and costly, or by the provision of an acid or other chemical, which may be dangerous and requires special precautionary measures. Moreover, 'in'this known device, a filler substance, which seals the connection after the device has been released, requires dissolution by acid to open the passage between the oilor gas-bearing strata and the casing. Extra equipment for acid and time for dissolving the substance must therefore be provided. I
In another known method, described and claimed in US. Pat. No. 3,312,280, a connecting tool is provided having a connector sleeve, mounted in, and transversely slidable relative to the casing wall by means of a spring mechanism held inactive al in k which adapted to be destroyed byachemical to release said 'mechanism to effect the connection between the casing and theoilbearing strata. The bore hole mustbe made considerably larger than the diametef of the casing in order to.
provide room for the connecting tool and for the cementation, which is accomplished entirely exterior of the casing. Among the drawbacks of the connecting tool are its complicated construction and the fact that which includes said tool. This is both time consuming and expensive in operation. Furthermore, since cementation has never'been carried out from the outside of the casing; suitable machinery is not readily available.
It. is an object of the present invention to provide a 1 technique for completing an oil or gas well which can be carried out quickly and effectively at the drilling site.
It is a further object of the present invention to provide a device for connecting the oilor gas-bearing strata in wells with the interior of the casing, which device is extremely simple in construction overcoming all the above-mentioned drawbacks without sacrificing the fulfilment of any of the above-mentioned requirements.
The invention concerns a device used in the completion of an oil or gas well to provide a passage between the oilor gas-bearing strata and the interior of the well casing. The device comprises a member mounted in the casing wall, but held immovable therein during the loweringof the casing into the well and being adapted for sliding transversely outwardly therefrom to contact said strata. The member is hollow, is initially closed at its inner end, and is held in means screwed into a mounting sleeve which is attached by welding around the hole in the casing wall. The member includes a stopper nutcontaining a mixture of salt and epoxy resin, the mixture being protected during the circulation and cementing processes carried out to complete the well. Upon breaking of the inner end of said memher, the mixture will dissolve to provide a free passage between the casing and said strata through said memher.
The invention is illustrated, by way of example only, in the accompanying drawings, in which:
FIG. 1 is a cross-section of part of a well casing provided with the device according to the invention, the device shown in a partially extended position.
A' well casing 1 of known construction is provided with a hole 2 in its wall. This hole is made by means of a torch at the drilling site, the location of the hole and its spacing along the casing from other such holes being determined by means of conventional electronic log ging' equipment which determines the levels of the potential production strata. Into hole 2 the mounting sleeve 3 for the device is welded in a manner so as to extend outwardly for not more than one-half inch. The sleeve 3 is provided with an internal screw thread which is counter-sunk at the outer edge. A bearing nut 4, to house the transveresely-sliding member 5 in its axial bore, is'screwed into mounting sleeve 3 from the outside. This bearing nut has a tapered outward flange 4a which sits in the counter-sunk part of sleeve 3. The bearing nut 4 has an axial conical depression 412 in its outer end and an axial internally threaded bore 4c at its inner end into which a check nut 6 is screwed. A peripheral groove 4d is made in the outer surface of bearing'nut 4 in the vicinity of the bottom of bore 40 for a purpose to be described hereinafter.
' The check nut 6 has an enlarges bore 6a surrounding its axial bore at its outer end, i..; the end facing theclosed toward the inside. A salt stopper nut 8 is screwed into the open outer end of member with the interposition of a substantially conical cup 9 held by its inner rim 9a between the member 5 and the stopper nut 8. This stopper nut has an outer conical flange 8a which sits in, and is guarded by, the cup 9 and which is provided in its central bore with a filter 8b of salt held together by epoxy resin and protected by means of grease inserted into the member 5.
Near the inner end of member 5, an outer peripheral groove is provided in which a retaining ring 10 is disposed. The ring prevents the member 5 from falling out of the casing in case the member 5 is too short to reach the strata and also holds in position an elastic friction sleeve 11 slipped onto the inner end of memberS.
The device above described will be operated in the following manner:
After the well has been bored and logged, holes 2 are made in casing 1 by a torch at the required locations and sleeves 3 are fixed in said holes by welding. The device is now assembled, all parts except sliding members 5 being the same for all conditions. The diameter of said sliding member 5 will be constant, but its length will be chosen according to casing size andthe space between the casing outer surface and the well bore. After the device has been assembled into the bearing nut 4 so that cup 9 sits in depression 4b, the said nut is screwed into sleeve 3, recesses 4f being provided in the outer face of the nut so that a spanner wrench can be applied to tighten it.
The friction sleeve 11, which is preferably made of a tube of PVC, prevents the member 5 from sliding outwardly during the lowering of the casing into the bore.
A known flexiflow fill up collar, equipped with a shear plate, and a known rubber seal-off plate on top of the collar is added above the casing before the latter is lowered into the bore hole. Since, normally, the casing is empty or only partly filled during this lowering operation, the external pressure will hold the member 5 in place and prevent it from sliding outwardly prior to the circulation operation, which, conventionally is effected as soon as the casing is in place. At this stage the shear plate will have built up enough pressure to push the sliding member 5 outwardly, overcoming the resistance of sleeve 11.
Normally, during circulation enough pressure is created to force the member 5 outwardly. The use of the known shear plate which creates a higher pressure, assures that there is enough pressure to penetrate the mud cakes which are found opposite the permeable strata.
After circulation is established and the member 5 is 9 extended, cementation of the annulus is performed, as known per se. During this operation the cup 9 protects the salt stopper nut 8. Following cementation. a cementing ball, as used in the known cement retainer and having the ability to float on the cement and to sink in the mud, is inserted on top of the cement, the size of the said ball being chosen so that it can pass by the parts of the device which protrude into the interior of the casing. Thereafter the displacement operation is carried out, at the end of which said ball will hit the known rubber seal-off plate, whereby an over displacement is prevented while sufficient pressure is built up to hold the sliding member 5 in its extended position. However, should this pressure be reduced for any reason, the check balls 7 will prevent the return of mem her 5 since they are forced by the slanted wall of bore against the wall of member 5 to hold it in place by friction.
After the cement has set, a bit is lowered into the casing to knock off the part of the device extending into the casing, an operation which is made very easy and exact because of groove 4d provided in bearing nut 4 and the fact that member- 5 is preferably made of relatively fragile material, such as cast iron, which has the additional advantage of being easily drilled with conventional drill bits, in case the break is not clean. Thus, the casing is free for the passage of production tools, such as packers, bridge plugs, etc; The casing is swabbed, as known per se, which will cause the salt plugs to dissolve to open member 5 from both sides. Where the casing is swabbed dry, and acidation or other stimulation is required, the stimulating fluid will easily penetrate the formation through the permeable salt plugs and will dissolve them.
It can be seen that the assembly of this device is. simple and its mounting into the casing wall can be effected quickly, since only the sleeve 3 needs to be welded into the casing at the site. The operation of the device is automatic, leakage of mud or liquid cement into the interior of the casing through the bores of the bearing and check nuts being prevented by the O-rings.
, We claim:
1. An apparatus for providing a passage between an earth stratum and the interior of a well casing comprising a movable hollow conduit member mounted in the casing wall initially held retracted and immovable while the casing is lowered and subsequently after the casing is set extended outwardly from the casing wall to contact said stratum, a dissolvable plug initially blocking the bore of said conduit member, the improvement wherein said plug is water soluable and said apparatus includes removable means on each end of said plug which prevent premature contact of said plug by water.
2. The improvement as claimed in claim 1 wherein said plug comprises a mixture of salt and a bonding agent.
3. The improvement as claimed in claim 2 wherein said bonding agent is an epoxy resin.
4. The improvement as claimed in claim 1 wherein said means protecting said plug comprises a layer of grease disposed on the outer end of said plug.
5. The improvement as claimed in claim 4 wherein said means further comprise an end cap on the inner end of said conduit member.
6. The improvement as claimed in claim 5 wherein said end cap is integral with said conduit member.
7. The improvement as claimed in claim 1 wherein said conduit member is movably supported in a hollow mounting unit disposed in a hole in said casing wall, a peripheral groove being provided around the outer surface of said mounting unit.
8. The improvement as claimed in claim 1 wherein I said conduit member is movably supported in a hollow mounting unit disposed in a hole in said casing wall, said mounting unit comprising a mounting sleeve in a bearing nut disposed therewithin and supporting said conduit member, said bearing nut being flush at the outside with said sleeve and extending into the casing, a bore being provided at its inner end, a check nut disposed in said bore, the conduit member being held in the axial bores of the bearing nut and check nut.
9. The improvement as claimed in claim 8 wherein a peripheral groove is provided around the outside of the check nut.
10. The improvement as claimed in claim 8 wherein internal grooves are provided in the axial bores of the bearing and check nuts and sealing rings are disposed in said grooves.
11. The improvement as claimed in claim 8 including check means to prevent movement of said conduit member toward the interior of said casing wall.
12. The improvement as claimed in claim 11 wherein the outer end of said check nut is provided with an enlarged bore surrounding its axial bore, the walls of said enlarged bore being slightly conical, said check means comprising a plurality of check balls disposed in said enlarged bore.
13. The improvement as claimed in claim 1 wherein near the inner end of said conduit member retaining means are provided for preventing the overextension of said conduit member.
14. The improvement as claimed in claim 13 wherein said retaining means comprise an outer peripheral groove in said conduit member and a retaining ring disposed in said groove.
15. The improvement as claimed in claim 1 including restraining means to prevent the premature outward sliding of said conduit member. said restraining means comprising a plastic sleeve disposed around the outer surface of the inner end of said conduit member.
16. The improvement as claimed in claim 15 further including an outer peripheral groove in said conduit member near the inner end thereof and a retaining ring disposed in said groove, a portion of said plastic sleeve overlying said restraining ring.
Claims (16)
1. An apparatus for providing a passage between an earth stratum and the interior of a well casing comprising a movable hollow conduit member mounted in the casing wall initially held retracted and immovable while the casing is lowered and subsequently after the casing is set extended outwardly from the casing wall to contact said stratum, a dissolvable plug initially blocking the bore of said conduit member, the improvement wherein said plug is water soluable and said apparatus includes removable means on each end of said plug which prevent premature contact of said plug by water.
2. The improvement as claimed in claim 1 wherein said plug comprises a mixture of salt and a bonding agent.
3. The improvement as claimed in claim 2 wherein said bonding agent is an epoxy resin.
4. The improvement as claimed in claim 1 wherein said means protecting said plug comprises a layer of grease disposed on the outer end of said plug.
5. The improvement as claimed in claim 4 wherein said means further comprise an end cap on the inner end of said conduit member.
6. The improvement as claimed in claim 5 wherein said end cap is integral with said conduit member.
7. The improvement as claimed in claim 1 wherein said conduit member is movably supported in a hollow mounting unit disposed in a hole in said casing wall, a peripheral groove being provided around the outer surface of said mounting unit.
8. The improvement as claimed in claim 1 wherein said conduit member is movably supported in a hollow mounting unit disposed in a hole in said casing wall, said mounting unit comprising a mounting sleeve in a bearing nut disposed therewithin and supporting said conduit member, said bearing nut being flush at the outside with said sleeve and extending into the casing, a bore being provided at its inner end, a check nut disposed in said bore, the conduit member being held in the axial bores of the bearing nut and check nut.
9. The improvement as claimed in claim 8 wherein a peripheral groove is provided around the outside of the check nut.
10. The improvement as claimed in claim 8 wherein internal grooves are provided in the axial bores of the bearing and check nuts and sealing rings are disposed in said grooves.
11. The improvement as claimed in claim 8 including check means to prevent movement of said conduit member toward the interior of said casing wall.
12. The improvement as claimed in claim 11 wherein the outer end of said check nut is provided with an enlarged bore surrounding its axial bore, the walls of said enlarged bore being slightly conical, said check means comprising a pluralIty of check balls disposed in said enlarged bore.
13. The improvement as claimed in claim 1 wherein near the inner end of said conduit member retaining means are provided for preventing the overextension of said conduit member.
14. The improvement as claimed in claim 13 wherein said retaining means comprise an outer peripheral groove in said conduit member and a retaining ring disposed in said groove.
15. The improvement as claimed in claim 1 including restraining means to prevent the premature outward sliding of said conduit member, said restraining means comprising a plastic sleeve disposed around the outer surface of the inner end of said conduit member.
16. The improvement as claimed in claim 15 further including an outer peripheral groove in said conduit member near the inner end thereof and a retaining ring disposed in said groove, a portion of said plastic sleeve overlying said restraining ring.
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US501622A US3924677A (en) | 1974-08-29 | 1974-08-29 | Device for use in the completion of an oil or gas well |
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US501622A US3924677A (en) | 1974-08-29 | 1974-08-29 | Device for use in the completion of an oil or gas well |
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