RU2040691C1 - System for transmission of electric power and information in column of joined pipes - Google Patents

Abstract

FIELD: systems for transmission of electric power and information. SUBSTANCE: system for transmission of electric power and information in column of joined pipes has electric conductors located along pipe body and members of contactless communication on pin and box. These members are made in form of transformer windings located in annular recesses of joined pipes. Annular recesses are made, either on end face of box and on stop surface of pin, or in conical thread surfaces of pin and box, or on the end face of pin and box plane opposite to pin, or in external cylindrical surfaces of pin and box, or in internal surfaces of nipple and box. Transformer windings may be located inside their own opened magnetic circuits. In this case, pipes may be made of nonmagnetic material. Transformer windings may be wound round their own closed circular magnetic circuits installed in annular recesses. In this case, pipes may be made of nonmagnetic electric conducting material. EFFECT: higher efficiency. 12 cl, 25 dwg

Description

 The invention relates to drilling wells, and in particular to devices for non-contact transfer of energy from a source located in one pipe from a pipe string to a consumer located in another pipe of this string, for similar transmission of information and for transmitting information and energy simultaneously.

 A known system of energy and information transfer for drilling equipment (1), containing electrical conductors located along the body of the pipes and contact elements of electrical contact on the nipple and coupling.

 This system has all the disadvantages of a device using contact electrical communication.

 Also known is an electrical information transmission system for boreholes (2), containing electrical conductors located along the body of the pipes, and contactless elements, a magnetic field source and a Hall sensor located on the nipple and lock coupling of the joined pipes.

 The disadvantages of this system are the complexity of the design and its low reliability.

 In FIG. 1 shows a pipe string with an electric transmission system in which transformer windings are placed in annular recesses at the end of the coupling and on the thrust plane of the nipple; in FIG. 2, section AA in FIG. 1; in FIG. 3 embodiment of an electrical transmission system, in which the transformer winding of the system is located directly in the annular grooves of the nipple and clutch; in FIG. 4 is an embodiment of an electrical transmission system in which the transformer winding of the system is located inside its own open magnetic circuit installed in the annular grooves of the nipple and clutch; in FIG. 5 is an embodiment of an electrical transmission system in which a transformer winding is wound around its own closed annular magnetic circuit and is installed in the annular grooves of the nipple and clutch; in FIG. 6, 7, embodiments of the transmission system (Figs. 3, 5), in which the outer parts of the stop of the nipple and the coupling (or only the nipple or the coupling) are made protruding; in FIG. 8 is one variation of the embodiment of FIG. 3, where the protruding part of the emphasis provides reliable closure of the magnetic circuit (in the variants of Figs. 8 and 7, a cover 30 is used that protects the windings from mechanical damage); in FIG. 9 is a variation of an embodiment of a transmission system (as shown in FIG. 5) in the case of non-conductive pipes; in FIG. 10 a closed ring magnetic circuit around which a transformer winding is wound; in FIG. 11 a pipe string with an electric transmission system, in which the transformer windings are placed in annular grooves made in the tapered threaded surfaces of the nipple and coupling; in FIG. 12, 13 placement options of transformer windings (according to Fig. 11), while the windings are placed inside their own magnetic cores; in FIG. 14 is an embodiment of an own magnetic circuit of a transformer winding located in an annular groove of a nipple (according to FIGS. 12, 13); in FIG. 15-17 pipe string with an electric transmission system in which transformer windings are placed in annular grooves at the end of the nipple and the opposite plane of the coupling; in FIG. 18-20 pipe string with a transmission system in which transformer windings are placed in annular grooves made in the outer cylindrical surfaces of the nipple and coupling; in FIG. 21-23 a pipe string with a transmission system in which transformer windings are placed in annular grooves made in the inner cylindrical surfaces of the nipple and coupling; in FIG. 24, 25 embodiments of the electrical conductors of the information and energy transmission system.

 The proposed system works as follows.

 The nipple 1 of one of the pipes 2 of the column is connected to the coupling 3 of the second pipe 4 by a threaded connection 5 (Fig. 1). Transformer windings 6 of the system are placed in the annular grooves 7 of the nipple 1 and the coupling 3. The electrical conductors 8 of the system are located along the pipe body, for example in grooves 9, fixed and insulated by compound 10.

 In one embodiment, the transformer windings 6 can be placed directly in the grooves 7 of the nipple 1 and the coupling 3, while the transformer windings are fixed and isolated in the grooves 7 by the compound 11. The terminals 12 of the transformer windings for connection with electrical conductors 8 can pass, for example, through holes 13 ( Fig. 3-10).

 In another embodiment, transformer windings 6 are placed inside their own open magnetic circuit 14 (Fig. 4). Here, as in the previous embodiment, the windings are fixed and insulated in the magnetic circuit 14 and in the grooves 7 by the compound 11, and their conclusions can pass through the holes 13.

 In another embodiment, transformer windings 6 are wound around their own closed annular magnetic core 15, which can be made solid, wound from tape or made of ferrite. Further, the windings made in this way are installed in the annular grooves 7 of the nipple 1 and the coupling 3, are fixed and isolated in the groove by the compound 11 (Fig. 5-10).

 In FIG. 6 shows one of the varieties of this structural embodiment of the transformer windings. To ensure reliable electrical connection of the squirrel-cage loop formed by the electrically conductive nipple 1 and the coupling 3, the outer parts 16 of the stop of the nipple and the coupling are made protruding.

 In FIG. 9 shows a variant of the design of transformer windings.

 In the case when the pipes 2 and 4 or one of them is non-conductive, the winding 6 with its own closed ring magnetic core 15, located in the groove 7 made in the non-conductive pipe, should be placed inside the additional input annular open conductive core 17, the open ends of which protrude above the mating surfaces.

 Transformer windings 6 of the information and energy transmission system can be placed in annular grooves 7 made in tapered threaded joints 5 of the nipple 1 and the coupling 3 (Fig. 11-14).

 In FIG. 11 shows the indicated option for the case when the transformer windings 6 are located directly in the annular groove 7 of the nipple 1 and the coupling 3. In order to make the placement of the windings 6 in the coupling 3 technologically convenient, it is possible to manufacture a prefabricated coupling 3 consisting of a main part and a nozzle 18 .

 In FIG. 11 and 14 show a variant for the case when transformer windings 6 are placed inside their own open magnetic circuits 19 and 20, similar to magnetic circuits 14 in FIG. 4. If the coupling 3 is made prefabricated, then the outer magnetic circuit 19 can be made continuous annular. The inner magnetic circuit 20 in the case of the execution of the nipple 1 solid (non-assembled) should be composite. For example, as shown in FIG. 14, composed of two halves. In FIG. 12 shows an embodiment of using windings placed on their own closed magnetic circuits 15, similar to those shown in FIG. 10. Here, to ensure the possibility of installing the magnet wire, the nipple, like the coupling, must contain a nozzle 21.

 Transformer windings 6 of the information and energy transmission system can also be placed in annular grooves 7 at the end of the nipple 1 and the opposite plane of the sleeve 3 (Fig. 15-17). When this winding 6 can be located in the grooves 7 directly (Fig. 15) or in their own open magnetic circuits 14 (Fig. 16).

 If in the lock of joined pipes the end face of the nipple and the opposite plane of the sleeve are used as stops (there is a gap at the end of the sleeve), then transformer windings 6 located in the grooves 7 can be located on their own closed ring magnetic circuits 15, similar to those shown in FIG. 10. Moreover, to reliably obtain a short-circuited electrically conductive ring, the internal parts of the stop of the nipple and the coupling should be protruding (Fig. 17).

 When the intrinsic electrical conductivity of the pipe is insufficient, the winding 6 of the magnetic circuit 15 should be placed inside an additionally inserted annular open conductive core 17, the open ends of which protrude above the mating surfaces (Fig. 9). Moreover, if an electrically conductive and one non-conductive pipe are joined, then only one winding corresponding to the annular groove of the non-conductive pipe should be placed inside the open conductive core. The second winding is placed inside the annular groove of the conductive pipe without an additional core.

 In addition to the considered options, transformer windings 6 of the electrical transmission system can be placed in the annular grooves 7, made in the outer cylindrical surfaces 21 of the nipple 1 and the coupling 3 (Fig. 18-20). The sections of the outer cylindrical surface 21 of the joined pipes 2 and 4, located behind the annular grooves 7 from the joint 22 of the pipes, are additionally connected by an external magnetic circuit 23. In FIG. 18 shows an embodiment in which the outer diameter of the outer magnetic circuit 23 is larger than the outer diameter of the abutting pipes. In FIG. 19 shows an option when the outer diameter of the outer magnetic circuit 23 is equal to the outer diameter of the joined pipes. A third case is possible, the outer diameter of the outer magnetic circuit is smaller than the outer diameter of the joined pipes. In FIG. 20 shows the case of the transmission system when the transformer windings 6 are wound around their own closed annular magnetic circuits 15 and this assembly is placed in the grooves 7 in the outer cylindrical surfaces 21 of the nipple 1 and the coupling 3. Here, the outer element 23 must necessarily be made of electrically conductive material.

 An option is proposed in which the transformer windings 6 of the electrical transmission system are placed in annular grooves 7 made in the inner cylindrical surfaces 24 of the nipple 1 and the coupling 3 (Fig. 21-23). The sections of the inner cylindrical surface 24 of the joined pipes 2 and 4, located behind the annular grooves 7 from the joint of the pipes, are connected by an additional input magnetic circuit 25 located inside the pipes. In FIG. 21 shows an embodiment in which the inner diameter of the additionally inserted magnetic circuit 25 is smaller than the inner diameter of the pipes to be joined. In FIG. 22 shows a variant when the inner diameter of the additionally introduced magnetic core is equal to the inner diameter of the joined pipes. In FIG. 23 shows an embodiment of a transmission system similar to that of FIG. 20. There is also an additional element magnetic circuit 25) must be made of electrically conductive material.

 The electrical conductors of the transmission system can also be made in the form of metal tracks 26, mounted in a flexible tape 27 (Fig. 24, 25). In this case, the flexible tape 27 is isolated from the surface 28 of the pipe 4, and is also insulated by the coating 29 from the internal cavity of the pipe or from the external environment (in the case of the location of the tape on the external surface of the pipe).

 To consider the principle of operation of the proposed system, for definiteness, let us say that a power supply unit, a command generation unit and an information processing unit are located in the pipe 2, and a block of sensitive elements is located in the pipe 4.

 Power (energy) in the form of an alternating current voltage with a frequency f through the electrical conductors 8 enters the transformer winding 6, fixed in the nipple 1 (Fig. 1). In the second transformer winding 6, mounted in the sleeve 3, there is an alternating current voltage, which, through the electrical conductors 8 located on the pipe 4, is supplied to power the sensor unit.

 If pipes 2 and 4 are made of magnetic material, then two windings 6 form a transformer with a ferromagnetic core. If the joined pipes are made of non-magnetic material, then two windings 6 form a transformer without a magnetic circuit (air).

 Own open magnetic circuits 14 form, together with the windings 6, a transformer with a ferromagnetic core (Fig. 4) regardless of the fact that abutting pipes are made of magnetic or non-magnetic material.

 Own closed ring magnetic circuits 15 form, together with the windings 6 and the electrical conductive nipple 1 and the coupling 3, a transformer with a common snapped screw (housing) (Fig. 5).

 Information from the block of sensitive elements to the information processing block in the form of an AC signal or in the form of a pulse signal travels a path similar to the supply voltage, but in the opposite direction.

 Information from the block generating commands to the block of sensitive elements in the form of a pulse signal travels a path similar to the supply voltage.

For the simultaneous transmission of information of the supply voltage and information, the frequency f _{2 of} the information signal generated in the form of an alternating current signal must be different from the frequency f _{1 of the} supply voltage, or the information signal must be generated in the form of pulses.

 The number of turns in the transformer windings 6 of the mating pipes 2 and 4 may be the same or different. In the case of a different number of turns, the transformer formed by the windings 6 can be step-up or step-down for the supply voltage, step-up or step-down for the information signal. In the case of simultaneous transmission of information and energy, the transformer windings 6 in the mating pipes can be made sectional, which allows using these windings to realize a step-up transformer for both the supply voltage and the output information of the sensitive elements.

 The proposed transmission system can be used both for two pipes of the column, and for several series-connected pipes of the column.

Claims (12)

 1. SYSTEM OF TRANSMISSION OF ELECTRIC ENERGY AND INFORMATION IN THE COLUMN OF BATTERING PIPES, containing electrical conductors located along the body of the pipes, and contactless elements located on the nipple and lock coupling of the joined pipes, characterized in that the contactless and the contactless communication elements are made the secondary windings of which are placed in annular grooves located respectively on the nipple and coupling of the joined pipes.  2. The system according to claim 1, characterized in that at least one of the windings of the transformer is placed inside its own open magnetic circuit, while the body of the joined pipes can be made of non-magnetic material.  3. The system according to claim 1, characterized in that the transformer windings are wound on their own closed annular magnetic circuit, while the pipe body can be made of non-magnetic material.  4. The system according to claim 3, characterized in that the annular magnetic circuit of at least one pipe is placed inside an annular open conductive core, the open ends of which protrude above the mating surface of the pipe, the pipe body is made of non-conductive material.  5. The system of claims. 1 to 4, characterized in that the annular grooves are made at the end of the coupling and on the thrust plane of the nipple.  6. The system of claims. 1 to 4, characterized in that the annular grooves are made in the conical threaded surfaces of the nipple and the coupling.  7. The system of claims. 1 to 4, characterized in that the annular grooves are made on the end of the nipple and the opposite plane of the coupling.  8. The system according to claim 1, characterized in that the annular grooves are made in the outer cylindrical surfaces of the nipple and the coupling, and the sections of the outer cylindrical surface of the pipes located behind the annular grooves from the joint are connected by an additional external magnetic circuit, the outer diameter of the external magnetic circuit can be more, equal to or less than the outer diameter of the joined pipes.  9. The system according to claim 1, characterized in that the annular grooves are made in the inner cylindrical surfaces of the nipple and the coupling, and the sections of the inner cylindrical surfaces of the abutting pipes located behind the annular grooves from the joint are connected by an additional magnetic circuit located inside the pipes, the inner diameter the magnetic circuit may be larger, smaller, or equal to the inner diameter of the joined pipes.  10. The system according to claim 3, characterized in that the annular grooves are made in the outer cylindrical surfaces of the nipple and the coupling, and the sections of the outer cylindrical surface of the pipes located behind the annular grooves from the junction are electrically connected by an additionally inserted external conductive sleeve, the outer diameter of the external sleeve may be greater, equal to or less than the outer diameter of the joined pipes.  11. The system of claim 3, characterized in that the annular grooves are made in the inner cylindrical surfaces of the nipple and the coupling, and the sections of the inner cylindrical surfaces of the abutting pipes located behind the annular grooves from the joint are electrically connected by an additional input external conductive sleeve located inside the pipes, moreover the inner diameter of the coupling may be larger, smaller, or equal to the inner diameter of the joined pipes.  12. The system according to PP.1 to 11, characterized in that the electrical conductors are placed and fixed in the grooves made along the pipe body, and the grooves can be on the outer, inner or both outer and inner cylindrical surfaces of the pipes, and the conductors and transformer windings are insulated with a compound .

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