NO325395B1 - Disconnectable and switchable water coupling device and method - Google Patents

Description

BACKGROUND OF THE INVENTION

Field of the invention

The invention relates to electrical downhole connections for use in wet environments. More specifically, the invention relates to sealed downhole switches which are self-cleaning when making contact to avoid contamination of the connection.

Prior art

Connecting/disconnecting power/signal lines down boreholes has always been a problem for the industry. Because the downhole environment is extremely aggressive towards electrical connections (salt water, fresh water, acids, etc.), it is more precisely traditionally considered that a reliable "wet connection" could not be established. Previously known equipment has attempted to create wet couplings that can be used in downhole environments, but these have only achieved limited reliability. Such connections according to prior art are quite small and require an excessive degree of precision when the connection is to be carried out, e.g. 1500 m below the surface. Although these connections are reasonably capable of creating a good electrical connection at the surface of the earth in modern borehole installations, they therefore fail when it comes to solving the need to create a connection connection between an uphole string and a downhole string far below the surface. Such connections are required in connection with several tools used that require power and instructions.

EP patent 0860907 shows a coupling for use in a well environment, where electrical conductors must be connected through the coupling. The connection points are cleaned of well fluid by suitable sealing rings as the connection parts are brought together. The connection consists of several connection points in a row.

US patent 4,921,438 shows a coupling for a well environment, where the male part of a conductor coupling is pressed into an area of dielectric grease when the coupling is brought together.

SUMMARY OF THE INVENTION

The above-mentioned and other disadvantages and shortcomings of previously known technology have been overcome or removed by connection/disconnection designs in wet environments according to the invention.

In all designs according to the invention, the need for plugging in small connecting pieces is avoided. The plugging in of the pipeline itself is all that is necessary to form the connection connection. This constitutes a considerable advantage within the field in view of the increasing use of electrically powered downhole tools. This wet coupling/uncoupling ensures reliability for such equipment due to an increased probability that the coupling will work and a reduction in the care required to make the coupling connection.

Most of the designs listed here use an insulator that protects a conductor installed with the downhole equipment. This insulator can be rubber, plastic material, metal or lubricating grease, etc. whose task at the time of connection is mainly to maintain the conductor in a very clean state. Some of the designs further include a wash with hydraulic fluid to ensure that the conductor is not contaminated when the insulator is pierced or otherwise removed by the string or the connecting piece that is inserted. In general, the conductor on the insertion tool will also be protected by one or more insulators of the type mentioned above.

Other designs do not use conductor insulators on the downhole string, but rely on a cleaning effect from the downhole string at the insertion to thereby remove any foreign bodies or oxidation that may have accumulated on the downhole conductors.

In each of the embodiments discussed here, the insertion process will cause certain events to occur which will lead to safe and reliable interconnections.

In addition to the ability to form wet contact, some of the designs indicated here also allow wet disconnection and reconnection, which is advantageous for situations that require such activity. In a certain embodiment, a certain section of the uphole string is left connected to the downhole string. This leaves the connection that has taken place during insertion undisturbed. Instead, a piece of the hole section is left, which itself constitutes a new insulated conductor (or non-insulated) for the subsequent insertion procedure. In the event that the holed section of the string needs to be pulled up, a new connection can take place at a later time and in the same way as the original conductor assembly. In order to be able to leave a section down the borehole, a breaker section must also be used to break the connection with the upper string. This switch section must then break the connection in a sealed environment to prevent short-circuiting when re-connecting with the borehole string.

BRIEF DESCRIPTION OF THE DRAWINGS

Reference must now be made to the drawings where corresponding elements are given the same reference numbers in the various figures, and on which:

fig. 1 is an elevation sketch showing the basic principle of the invention,

fig. 2 is an enlarged sketch of a specific embodiment of the circled portion A in fig. 1,

fig. 3 is an enlarged sketch of an alternative specific embodiment of the circled part A,

fig. 4A and 4B respectively show the upper and lower parts of a corresponding coupling device corresponding to the circled part A in fig. 1, and then in an unconnected position,

fig. 5A and 5B show the upper and lower parts of the embodiment in fig. 4A and 4B in the connected state,

fig. 6A and 6B show another alternative embodiment for the circled portion A in fig. 1 in disconnected and connected state respectively,

fig. 7 shows another alternative embodiment for the circled part A in fig. 1,

fig. 8A and 8B show another alternative embodiment of the circled part A in fig. 1 in the disconnected and connected state, respectively,

fig. 9A and 9B show an embodiment of the circled area B in fig. 1,

fig. 10A-C show different positions for an alternative embodiment of the circled part B in fig. 1,

fig. 11-13 is a longitudinal sectional sketch of the tool according to an embodiment of the invention to visualize the disconnection state,

fig. 14-17 together show an elongated longitudinal section through another coupling tool according to the invention,

fig. 18 shows a cross-section through the part of the object of the invention shown in fig. 11, and which is taken along the section line 15-15, and

fig. 19 shows a cross-section through the part of the object of the invention shown in fig. 12, and taken along the cut line 16-16.

DETAILED DESCRIPTION OF SEVERAL PREFERRED EMBODIMENTS

Reference must now be made to fig. 1, where a schematic presentation provides an understanding of the invention in its broadest aspect without details with regard to specific

mechanisms in working models. It will be understood that many different embodiments are possible, and which are capable of being used to produce the above stated desired results. Each of the figures following fig. 1 illustrates smaller parts of fig. 1 to indicate for experts in the field a certain method for connection or disconnection within the circled areas A and B in fig. 1. It should also be recognized that although in many cases within this description reference is made to "electrical" or "electricity", this terminology is only used to indicate examples and the reader should understand that also other connection types, such as fiber optic conductors and optical fibers can be used.

The broad concept of invention begins with the production of a coupling device which will be able to be installed in a borehole in different ways and connected to different devices. Fig. 1 schematically shows a connection device in a borehole. In fig. 1, a lower (first) section of a borehole has been completed (or from the manufacturer's point of view can be completed with) a tool string 12 with one or more electrically driven or regulated tools which may have sensors, etc. This lower section 12 is of many for various reasons, which will be known to those skilled in the art, isolated from an upper (second) section of the pipe string 14. For this reason, it is necessary to establish an electrical connection between the upper section 14 and the lower section 12. As indicated above, such connections have been difficult to carry out from prior art due to the unfavorable downhole surroundings. According to the present invention, equipment for such a connection has therefore been produced by excluding downhole fluids from the conductors in section 12 (or cleaning them) and ensuring that contaminants are not applied to them during the connection. The lower part 12 includes assigned conductor wires (or fibers) 16 (one or more) which are connected at the manufacturing site to conductor ends (connectors) 18. The connectors 18 are generally embedded in the pipeline and will include an overlying seal to prevent contamination. The lower part 12 is driven down the borehole or positioned downhole in some other way in this condition and will remain in a sealed condition for the coupling pieces 18 until an upper section 14 is driven down the hole to form a connection with the coupling pieces 18. Exactly how the coupling pieces are connected will be discussed below.

It will be recognized that from the sketch shown in fig. 1 that another distinct part is shown between the lower section 12 and the upper section 14. This is the switching section 20 (third section). The switching section 20 can optionally be used to restore the original connection for the equipment. It should be recognized from a consideration of fig. 1 that the special features that are present on the lower section 12 are also present on the switching section 20. It will then be understood that the upper section 14 only needs to include features that will be sufficient to be able to be joined with the lower section 12 without the need for the switching section 20.1 a preferred embodiment, however, is the switching section 20 included. The section 20 includes features that constitute a replacement for the second connecting piece in order to be able to perform a connecting connection with the first connecting piece. This section allows the original interconnection to remain intact if the upper section 14 is pulled away for any reason. This will prevent contamination of the coupling pieces 18. By way of further explanation, it can be stated that as soon as the coupling pieces 18 are freed from the insulation that protects them (in this embodiment) by the effect of sticking into the hole section, it will be left unprotected from the elements . With the upper section connected, no ambient fluid can come into contact with the connectors. If, however, the upper section is pulled away, then the coupling pieces could be exposed to attack from the borehole fluids. Reconnecting these connectors is unlikely to be successful. For this reason, the switching section 20 is used. To now continue the discussion of section 20, it should be stated that this section includes a disconnection for the wiring wires in the upper section 14 so that the cancellation of the electrical continuity caused by the extraction of the section 14 does not make it possible for a "live" connection to contact downhole fluids. This is important to prevent damage to electrical downhole tools or damage to the equipment when reconnecting. The disconnection area is schematically shown by the circled area B in fig. 1.

Switching section 20 has been created exclusively to create the possibilities that exist with stacked equipment. More specifically, since the switching section 20 is connected at the manufacturing site to the upper section 14 via a severable or otherwise separable connection with the upper section 14.1 in the event that the upper section 14 has to be removed from the borehole, it will leave behind a switching section 20 which comprises new sealed connecting pieces 18' and wires 24 which are in connection with the original insertion on the conductors 26. A subsequent upper section can then be inserted into the switching section with the same reliability as with the original connecting connection, so that the scheme with switching section can be used once in progress as many times as disconnection and reconnection is necessary. Switch sections simply keep stacking up as strings are pulled out and reconnected.

Reference will now be made to specific mechanisms, as the circled area A will first be discussed in connection with several designs to create a pure electrical connection with reliability and high security. In these figures, only the coupling mechanism itself is visible. It should be understood that such a mechanism constitutes one of section 14 or section 20, as the case may be. After the discussion of area A, the circled area B will be discussed. Area B applies to designs for breaking the connection with lead wires 22 in section 14 when this section is pulled away.

Reference must now be made to fig. 2, where a cover 30, which is shown here of plastic material, but which can be of rubber or metal, is positioned in a sealed condition on the upper side of the connecting piece 18. Although this entire part of the lower section 12 is exposed to borehole fluid, the coupling piece 18 be protected. A coupling mechanism shown in place after insertion, but before activation, comprises a bore 34, which is preferably filled with hydraulic fluid 30 (or the like). A wedge 38 is provided in the bore 34 and is driven like a piston preferably by pressure from a nearby or remote source and which is brought into contact with an electrical connector 40 connected by lead wires 44 from the upper section. This electrical coupling piece 40 comprises an inclined surface 46 and a hole punch 48. The inclined surface 46 is complementary to the wedge 38 and the coupling piece 40 is driven by this against the sealing material 42. Continued pressure against the coupling piece 40 leads to perforation of the seal 42. After perforation of the seal 42 , fluid 36 will escape from the borehole 34, as well as flow into the area between the seal 42 and the seal 30. This inflow effect displaces the borehole fluids and creates a clean dielectric environment in which the connection in question can be carried out. Further pressing of the connector 40 causes the punch 48 to penetrate the seal 30 and make electrical contact with the connector 18. It should be noted that the fluid 36 is preferably a dielectric fluid or a dielectric grease. Lubricating grease is preferred because of its viscosity and thus its tendency to remain around the coupling joint.

Reference must now be made to fig. 3, where an alternative coupling mechanism is shown. It will be recognized that this mechanism is very similar to the embodiment shown in fig. 2 and only adds seals 50 which are preferably constituted by seals of the chevron type. For the sake of overview, the other parts of this embodiment, although they are slightly different in certain respects, will be given the same reference number as in fig. 2. The embodiment in fig. 3 provides additional, possibly redundant, assurance of continuous cleanliness of the connection area. Seals 50 will not allow fluid to pass through the work in one or the other direction, while seal 50' will make it possible for fluid to pass only in the "out" direction in relation to the area enclosed by the seals 50 , 50'. The movement of the cleaning fluid 36, which in this embodiment preferably consists of hydraulic fluid, will then sweep all remains of well fluids out of the connection area and create a clean connection area.

Reference must now be made to fig. 4A, 4B and 5A, 5B where another alternative embodiment of the invention is shown. Due to the relatively complex structure of this embodiment, it is shown in both non-connected and connected form, and then respectively in Figures 4A, 4B and 5A, 5B.

Reference should first be made to fig. 4A and 4B, where the lower section 12 will constitute a reference. This embodiment works by bringing the upper section, or switching section, if present, in relation to the lower section 12' against spring-biased rings which cover the coupling pieces. In this embodiment, the lower section 12 comprises a spring biased against the area 62 which biases the ring 64 to a position where it covers the coupling piece 18. The section 12' preferably also comprises two o-rings 66, which form a seal against the ring 64, and a sweeper 68 Section 14' or 20' if present, comprises a spring 70 which rests against a spring stopper 72 and biases the ring 74 to a position where it covers the coupling piece 76. The ring 74 forms a seal over the coupling piece 76 by means of o-rings 78 which are mounted on the ring 74. The coupling piece 76 is preferably spring-loaded by means of springs 80 in such a way that it is biased against the coupling piece 18 in this position.

An attentive reader skilled in the art will recognize that there is an area 82 that is likely to be contaminated, and this volume may prove problematic for the coupling connection, even considering the sweeper 68. To eliminate this possibility, the inventors have herein created a closed hydraulic fluid reservoir 84 which can be opened via a tearable disk 86 to the volume 82. A piston 88 is provided which is operably connected to the reservoir 84 and positioned so that the "early sliding" for this embodiment, as discussed above, brings the piston 88 to movement into the reservoir 84 to increase the pressure therein until the tear-off disk 86 fails and hydraulic fluid is driven into the volume 82. This hydraulic fluid will remove all wellbore fluids in the volume 82 and make this area clean.

In operation, the piston 88 will land on the ring 64 and expel the hydraulic fluid, as discussed. Before the piston 88 is fully pressed into the bore for the reservoir

84, the shoulder 90 begins to drive the ring 64 downward by overcoming the bias from the spring 60. The ring 74 then contacts the shoulder 92 on section 12' and is driven uphole by overcoming the force of the spring 72 by downward movement of it upper section or possibly the switching section.

The coupling piece 76 is uncovered at the time it has reached the sweeper 68 and is swept clean to remove any oxidation that may have developed over time. Continued downhole movement of the uphole section aligns the coupling pieces 18 and 76 and the coupling is then complete.

Fig. 5A and 5B show this embodiment in a connected state to facilitate the understanding of the invention.

Reference must now be made to fig. 6A and 6B, where yet another alternative mechanism for the circled area A in FIG. 1 is visualized. The lower section i

this drawing shows an alternative configuration of section 12 and is thus indicated by 12". The connecting pieces also differ in appearance and are therefore designated by 18". The upper section 14" (it is understood that the upper section in this figure can also be the switching section) comprises a fluid-filled chamber 100 with an outlet port 102 sealed by means of a one-way valve 103 and a tearable disk 104. The chamber 100 is sealed by its other end by means of a gasket 106.1 a preferred arrangement, several o-ring gaskets are also applied and are indicated at 108. Focusing on the portion of the upper section 14" forming the chamber 100, it will

it is noted that two sweepers 110 are applied. A single swipe would possibly be sufficient, but for extra safety, two swipes are preferred for better cleaning. Contact pieces 112 are arranged in this area and these are protected by fluid 114 in the chamber 100.

In use, the nose 116 of section 12" is driven into the gasket 106 to eventually cut through this gasket, and as the o-rings 108 will prevent fluid 114 from escaping around the nose 116, the fluid will instead be pressurized. After as the pressure in the chamber 100 increases, this will cause the disc 104 to rupture and fluid 114 will be transferred through the valve 103 to the pipeline I.D. Since the valve 103 will not allow fluid to pass in the other direction, the coupling area in the chamber 100 will remain clean . Continued movement of the nose 116 into the chamber 100 brings the pieces 18" into sliding contact with the sweepers 110, so that these connecting pieces 18" are cleaned of any oxides that have formed thereon. The pieces 18" are then brought into line with the pieces 112 , and the connection can then be carried out, as shown in fig. 6B.

Fig. 7 shows another alternative embodiment concerning the encircled area A. In this embodiment, the upper section forms a connecting piece 120 consisting of a metal that can be melted at a low temperature (obviously, the melting temperature must be well above the well temperature at the submerged depth) . The metal coupling piece 120 is brought into position next to the coupling piece 18 and brings a coil 122 in close proximity to it, where this proximity is sufficient to melt down the coupling piece 120. As in previous embodiments, seals 134,132 are arranged and a reservoir 128 comprises fluid 130 which is driven of a plunger 126 to flood the contact area. In this embodiment, a current supplied from the surface or a downhole generated current is caused to melt the connector 120, which then flows into electrical contact with the connector 18.

In another alternative embodiment for the circled area A, and which is indicated in fig. 8A and 8B, the lower section 12 comprises two connecting pieces 18. The upper section in the drawings, which again may be somewhat equivalent to section 14 or section 20 in fig. 1, as a switch section is arranged after extraction, a nose 130 comprises a plurality of gaskets 132, preferably of the chevron type. Attached to the nose 130 by means of a release mechanism, preferably a shear pin 134, there is a coupling wedge 136 which accommodates a permeable coupling piece 138 in fluid 140 under seal 142. Upon downward movement of the upper section in the drawing (14 or 20), a spring 144 driven against a ring 146 to move it downhole until it contacts the ledge 148 of the counter wedge 150. Further downward movement causes the counter wedge 150 to move downhole behind the coupling wedge 136 to thereby cause the coupling pieces 138 to penetrate the cover 142 to contact the connectors 18 to close the circuit.

As discussed above, in that case the upper section 14 must be removed from the hole,

the connections are broken in such a way that a short circuit is avoided. To illustrate this, the relevant area is marked with B in fig. 1. It is important to note that the mere stretching of conductors to form fractures after they are exposed to drilling well fluids invites short circuits. In this case, the inventors have then produced the following two designs of switching sections. However, it should be understood that other mechanisms can also be arranged to create such a switching section, which is clearly within the scope of the invention.

Reference must now be made to fig. 9A and 9B, where the first embodiment of the switching section is shown in the connection position and the contact break position. The switching piece comprises a connecting piece 162 arranged on top of an insulator 160 in a recess 172 in section 12. The recess 172 is sealed by means of a cover 168 which can be of several different materials, which must, however, be of such a nature that they either deflect or enable a sealed sliding of the contact pins 166 through it. In terms of deflection, the pins 166 do not need to slide through the cover 166 (where the non-sliding arrangement is shown here).

As will be readily apparent from the drawings, the contact pins 166 form the basis for the connecting pieces 164, the pins extending to the outside of the cover 168 and to connection with a plate 170. The switching section is fully connected at the manufacturing site and is made as shown in fig. 9A. When a disconnection is desired, a pulling force on the tool will bring the switch to the state shown in fig. 9B, where the electrical connection is broken and the ends of the downhole wires are protected inside the recess 172 and by means of the cover 168. It will be clear to those skilled in the art that if the upper portion 174 of the drawings is to be completely removed, the switching section will have to be separated in a point on the upper side of the cover 168. Alternatively, the portion 174 could simply be a ring that remains down in the borehole.

Reference should now be made to Figs 10A, 10B and 10C, where a second switching embodiment is shown. This switching section is intended to work in much the same way as the embodiment in fig. 9A and 9B, and only what distinguishes these embodiments will be discussed here. The contact rod 180 is connected to a borehole piece of the pipe and carries a drive pin 182 and contact pins 184. The drive pin 182 comprises a wedge 186 with a sufficient angle of inclination to activate the slider 190 over the slide track 188. Actuation of the slider 190 displaces this (to the right in the drawing) to align the gate openings 192 with contact receptacles 194, in which contact pieces 196 are arranged and connected by lead wires 198. Once alignment is achieved, as described, the pins 184 can make electrical contact with the contact pieces 196 (the pieces 196 are isolated from the metallic tools using an insulation 200).

The length of the pins 182 and 184 is important for the work function according to the invention. When disconnecting, it is required that the slider 190 is closed (under bias from a spring 204) before the pins 184 are pulled free from the membrane 202. By requiring this, the seal formed by the membrane 202 will be breached, as the pins 184 are driven through this , do not allow contamination into the receptacles 194. It is obviously intended that the slider 190 should form sealing contact with the surrounding area. This embodiment is preferably assembled at the manufacturing site, but can also be used in the work field, as the ability the pin 182 has to activate the slider 190 will lie within a time frame where the pins 184 will be protectively located in the membrane 202.

In yet another embodiment of the invention, conductors are aligned and interconnected. Initially, reference should be made to fig. 11-13, where a more schematic sketch of the object of the invention is indicated. This sketch does not contain all parts of the invention and is thus only intended to show the locations and orientation of the connecting pieces. The tool 10 is divided into an upper half (which includes fig. 11 and 12) and a lower half which includes fig. 13. When these halves are separated, as shown in fig. 11-13, lower packing adapters 212 (there are twelve of these in the embodiment shown, although more or less may be used) will be visible in the lower half (Fig. 13), while complementary upper packing adapters 214 (the same number as the number of lower compaction adapters 212). The upper packing adapters 214 preferably comprise a pair of o-rings 270 for fluid-tight sealing of the lower packing adapters. The upper packing adapters 214 are connected to the uphole surroundings through channels 218, while at the other end of the connection in the lower packing adapters 12 are connected to the downhole surroundings through a channel 20. The channels 218 and 220 preferably contain fiber optic conductors. The connecting ends of the conductors are cleaned by preferably a hydraulic fluid which can be applied in many different ways, which includes utilization of the surroundings, but preferably does not include threads between the device profile and the end connections.

Although the upper and lower portions of the tool are fed into the hole together (aligned on the ground surface), an alignment profile 222 is provided on the tool to align the lower and upper halves in the event they become separated. As shown directly in fig. 12 and 13, the profile 224 constitutes a raised area of predetermined orientation on the anchoring sub 226. The profile 224 mates with a complementary profile 228 on the lower half (Fig. 13). These orientation profiles ensure that the lower packing adapters 212 will be aligned with and can be reliably brought together with the upper packing adapters 214.

Reference must now be made to the internal components of this embodiment of the invention, with reference being made to figures 14-16, and counting from the hole end of the tool, it is shown that a threaded section 230 is arranged for attaching the tool to a working string (not shown) . This threaded section 230 is cut on a body 232 which extends downhole to a suitable threaded connection with an anchoring sub 234 by means of the thread 236. The body 232 carries near its hollow end a disk-weaving spring-loaded holding cap 238 which is threaded on the outside of the body 232 by means of the thread 240. The cap 238 is further preferably anchored by means of a cap screw 242. The cap 238 functions in such a way that it retains preferably several disc springs (belleville discs) 244. The springs 244 absorb movements in the longitudinal direction of the upper and lower packing adapters. Furthermore, the washers keep the upper and lower packing adapters in positive shoulder contact inside, which is important for pumping down replaceable optical fiber installations and other installations. The disc springs 244 are held in position at the downhole end using the holding sub 246. This sub 246 is ring-shaped and threaded to the disc spring's adjustment sub 248 using the thread 250.

Downhole for the attachment sub 248 and radially outside the body 232 there is an upper coupling piece 252. This upper coupling piece 252 accommodates upper gasket adapters 214 at its lower end, as well as a line coupling assembly 254, which preferably comprises a pair of ring fittings and a lock nut (not shown individually). The coupling piece 252 is held in position on the body 232 by means of a shear screw 256 and a shoulder screw 258. These latter screws are best shown in fig. 18. Several bores 260 are made in the upper connecting piece to receive the channel 218. The lower connecting piece 262 (fig. 15 and 19) is arranged downhole for the upper connecting piece 252 and accommodates the lower gasket adapter 212, bore 264 for the channel 220 as well as a control line connector 260, which includes a pair of ring fittings and a lock nut (not shown separately). It should be noted that fig. 15 shows a cross-section through the tool, showing upper and lower seal adapters, as previously explained herein. It should also be noted that the upper seal adapter 214 includes two sets of o-rings 268 and 270. The rings 268 seal the upper seal adapter 214 against the upper coupling piece 252, while the rings 270 seal the lower seal adapter 212 inside the upper seal adapter 214 when brought into such intervention. The lower adapter 212 can then be for ordinary conductors or fiber optic conductors. Fig. 19 shows three of four (212a) of this type in normal form and one (212b) in fiber optic form.

Bridge between Figures 15 and 16 forms a sleeve 272 which covers the components of a filling and filling device according to the invention (the components of which will be discussed below). The sleeve 272 is connected to a packing housing 274 which includes locking lugs 276. The packing housing is also threaded 278 for a locking ring 280 for the body. This locking ring 280 is stopped in the direction of rotation by a roller pin 236. The gasket housing 274 is sealed against the anchoring sub 234 by means of a gasket stack 281.

Radially on the outside of the gasket housing 274 (Figs. 16 and 17) there is a casing 282 and a regulation line sub 284. The casing 282 comprises several gaskets 286, several screws 288 and an insert-receiving profile 290.

Radially within the sleeve 272 (Fig. 16) is a tap-in/tap-out assembly, which is mentioned above. This assembly comprises, starting from the hole end, a shear ring holder 292 which is connected to the anchoring sub 234 by means of a shear ring 294. The shear ring holder 292 is also connected to a support ring 298 through a set of screws 296 and threads 300. The support ring 298 supports a lowering sleeve 302 and is in contact with the body's locking housing 306. The body's locking ring housing 306 is connected to the body's locking ring 304 in the usual way and includes a set screw 308 to block rotational movement. The body locking ring housing is also threaded to a lower ice socket 302 by means of thread 310. The body locking ring housing 306 cannot move up or down due to the shear screw 312, which is engaged with the anchor sub 234. The body locking ring housing 306 is connected to a latch 314 by means of a dividing ring 316, which is a ring with holding profiles 318 to hold the body's retaining ring housing 306 against the latch 314 until a predetermined tensile load is applied to it and breaks the dividing ring 316.

In operation and after downhole, a pressure line 243 (Fig. 16) will pressurize a piston area 318 which is sealed with gaskets 86. After reaching a predetermined pressure, the shear screw 288 will be cut off and allow the casing 282 to move downward in the hole and so that the recess 290 is placed over the locking lugs 276 and allows these to be moved radially outwards for disconnection from the anchoring sub 234. When the anchoring sub 234 is disconnected from the lugs 276 it will be free to move. The body's locking ring 280 is arranged to prevent the housing 282 from moving back into the hole and readjusting the projections 276. After initial setting, the housing part of the tool is permanently displaced and the projections 276 are permanently disconnected from the anchoring sub 234. After this disconnection, the upper part of the tool (fig. 11 and 12) the lower part (fig. 13) is separated using the snap-in/snap-out assembly for the purpose of developing an appropriate sectioning for the present well, as the tool can be snapped in and out as many times as necessary until sufficient weight is transferred and the anchoring sub 234 supports the latch 314.1 this latter condition, the finishing feature is cancelled.

As soon as the cutting is correct, a lowering weight that exceeds the shear strength of the shear ring 294 and the shear screw 312 will be applied. After cutting off, the anchoring sub 234 is moved downhole through the locking ring 304 and held in this position until extraction is necessary or desired.

To extract the tool, a tensile load is placed on the anchoring sub and that is transferred to the body's locking ring 304, the dividing ring 316 and the latch 314. When a predetermined tensile force is exceeded, the dividing will fail and the anchoring sub leg 34 can be moved and holed. The unsupported detent 314 allows the detent to deflect into the recess 320 so that the finishing sub is brought into operational condition. Continued tensile loading will release the upper part of the tool from its lower part for extraction. The process described can be repeated with a new or rebuilt upper part.

Claims (1)

1. Conductive connection device for downhole environments and which comprises: a first section (12) which can be connected to equipment intended to be placed further downhole than said first section, when said device is installed in a borehole, at least one first conductor (16) assigned to said first section (12), a first coupling piece in functional communication with said at least one first conductor (16), where said first conductors (16) are maintained in a clean state or to be cleaned during operation of the coupling device, a second section (14) to is connected to equipment that is intended to be placed further downhole than said second section (14) when said second section (14) is installed in a borehole, and at least one second conductor (22) assigned to said second section (14), characterized by the wood third section functionally connected to said second section, at least one third manager who is connected to said third section, said at least one third manager who is functionally connected to said at least one other manager, a third connecting piece in functional connection with said at least one third conductor, said conductor is maintained in a clean state or to be able to be cleaned during operation of the connecting device, said third connecting piece being arranged to be connected to said first connecting piece during operation of said connecting device, where said third section can be separated from said second section (14) after said coupling device has been put into operation, a fourth coupling piece in functional communication with said at least one third coupling piece, where said fourth coupling piece is maintained in a clean state or to be cleaned during operation of a subsequent drive of the coupling device. 2. Conductive coupling device as stated in claim 1, characterized in that said third section further comprises a conductor break to prevent conductive contact of said at least one first connecting piece with borehole fluids through said one at least third connecting piece when separating said third section from said second section. 3. Conductive coupling device as stated in claim 2, characterized in that said conductor break comprises at least two contacts which are maintained in a clean environment, where said contacts are arranged to be separated by separation of said second section. 4. Conductive coupling device as stated in claim 3, characterized in that said clean environment is maintained by means of a deflectable cover (30) to which one of said at least two contacts is connected, said deflectable cover (30) being deflected to maintain connection between said two contacts while said third section is attached to said second section. 5. Conductive coupling device as stated in claim 2, characterized in that said conductor break comprises: at least one contact pin, and at least one contact receiver. 6. Conductive coupling device as specified in claim 5, characterized in that said breach further comprises a slider that seals said at least one receiver when said at least one pin is not engaged with said at least one receiver. 7. Conductive coupling device as stated in claim 6, characterized in that said break further comprises an activation pin to activate said slider. 8. Conductive coupling device as specified in claim 1, characterized in that said first connecting piece and said third connecting piece each comprise: at least one connecting link, at least one fluid-impermeable covering (30) on said at least one connecting link. 9. Conductive coupling device as specified in claim 8, characterized in that said coupling device further comprises at least one intermediate coupling which creates a coupling between said first coupling piece's coupling link and said third coupling piece's coupling link. 10. Conductive coupling device as stated in claim 9, characterized in that said intermediate coupling is a conductive piercing body which pierces said at least one fluid-impermeable covering (30) on each said at least one contact joint during operation of said coupling device. 11 Conductive coupling device as stated in claim 1, characterized in that said connecting device is configured to supply dielectric material (36) to the vicinity of an intermediate connection between said first connecting piece and said third connecting piece. 12. Conductive coupling device as stated in claim 10, characterized in that said cover (30) is made of rubber. 13. Conductive coupling device as stated in claim 10, characterized in that said cover (30) is made of metal. 14. Conductive coupling device specified in claim 11, characterized in that said dielectric material (36) is oil. 15. Conductive coupling device as stated in claim 11, characterized in that said dielectric material (36) is lubricating grease. 16. Conductive coupling device as stated in claim 1, characterized in that said first coupling piece and said third coupling piece are exposed to ambient conditions and are swept clean during operation of the coupling device. 17. Conductive coupling device as stated in claim 16, characterized in that said device is configured to transfer dielectric material (36)e to the vicinity of an intermediate connection in said connection device. 18. Conductive coupling device as stated in claim 17, characterized in that said dielectric material (36) is oil. 19. Conductive coupling device as specified in claim 17, characterized in that said dielectric material (36) is lubricating grease. 20. Conductive coupling device as specified in claim 17, characterized in that said dielectric material (36) is emitted from a reservoir in said device. 21. Conductive coupling device as stated in claim 16, characterized in that said first connecting piece and said third connecting piece are swept clean of each other. 22. Conductive coupling device as stated in claim 16, characterized in that said first coupling piece and said third coupling piece are swept clean by means of a sweeper. 23. Conductive coupling device as stated in claim 20, characterized in that said reservoir comprises a shut-off valve. 24. Conductive coupling device as stated in claim 1, characterized in that said first connecting piece consists of a connecting link and said third connecting piece comprises a fusible conductive element. 25. Conductive coupling device as stated in claim 24, characterized in that said element can be melted by means of a coil (122). 26. Conductive coupling device as stated in claim 25, characterized in that said coil (122) is supplied with power from within said device. 27. Conductive coupling device as stated in claim 25, characterized in that said coil (122) is supplied with power from a source outside said device. 28. Conductive coupling device as stated in claim 1, characterized in that said device is configured to produce a dielectric material (36) for an intermediate connection area for said first connection piece and said third connection piece. 29. Conductive coupling device as stated in claim 28, characterized in that said dielectric material (36) is oil. 30. Conductive coupling device as specified in claim 28, characterized in that said dielectric material (36) is lubricating grease. 31. Method for creating a conductive connection in downhole environments while enabling disconnection and reconnection, the method comprising: installing a first section (12) arranged to be connected to equipment located further down the borehole than an intended location of said first section , wherein said first section (12) has at least one associated conductor as well as a coupling piece functionally connected to said at least one coupling piece, installation of a second section (14) arranged to be connected to equipment located further up the borehole than an intended location for said second section, where said second section (14) has at least one assigned conductor, characterized in that said second section (14) further comprises a third section with at least one assigned conductor as well as a third connecting piece which is functionally connected to one end of said at least one conductor, as well as a fourth connecting piece functionally connected to the other end of said at least one cow pling piece and engagement of said third section with said first section. 32. Method for creating a conductive connection as stated in claim 31, and which further comprises: decoupling said second section (14) from said third section, and installing a separate second section (14) for engagement with said third section in the same position as associated with said first section. 33. Method for creating a conductive connection as stated in claim 31, where said intervention includes flushing a connection area for connection between said first connection piece and said second connection piece with a dielectric fluid. 34. Method for creating a conductive connection as stated in claim 31, and where said intervention comprises flushing a connection area for connection between said first connection piece and said third connection piece with a dielectric fluid.