RU2655265C1 - Method of destruction of paraffin, hydraulic, hydration-wax and ice deposits in development wells for support of their working regime - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to major workover and production maintenance of development wells and can be used in wells development to maintain a thermal regime in them to prevent the formation and elimination of hydrate, hydrate-paraffin and ice plugs in them. Method includes launching into the well up to the upper boundary of the plug of a local electric heater on a wireline multicore cable, the metal shell of which is connected to the body of the electric heater. One of the cores of the cable is connected to the phase of a three-phase current source, and a metal covering is connected to its zero contact. Further, the electric heater is lowered until it reaches the plug, then it is turned on and the plug material is melted, while the lower part of its electrode contacts with a borehole electrically conductive fluid. After melting the plugs, a logging multicore cable is fixed, each of its wires is connected to the corresponding phase of a three-phase current source. It’s turned on, transferring the cable along its entire length into the mode of the heating device, and a full warm-up of the annular and tubular space of the well is performed.

EFFECT: expanding functional capabilities, it is possible to automatically control the temperature of the electric heater due to the use of current regulators and temperature sensors.

3 cl, 4 dwg

Description

The invention relates to the field of overhaul and repair of oil wells and can be used to maintain a thermal operating mode in order to eliminate and prevent the formation of hydrated and hydrate-paraffin and ice plugs.

The prior art method for the destruction of paraffin, hydrate and ice plugs in production wells equipped with sucker rod units [RU 2199650 C2, IPC ЕВВ 37/00, publ. 02/27/2003], which includes the descent on the wireline cable of an electric local heating device into the annulus, the creation of a channel in the tube, pumping of the working agent through the channel in the tube until it is completely eliminated. In this case, before entering the electric heating device into the annular space in its faceplate at the wellhead, a through inclined hole is formed to connect the atmospheric space with the annular space.

The disadvantage of this method is its limited ability to destroy deposits in production wells due to the absence in the proposed technical solution of technological operations for the automatic control of the operating modes of the heating device.

The closest technical solution to the claimed invention and selected as a prototype is recognized as a method of eliminating hydrate and paraffin hydrate plugs in wells [RU 2204698 C2, IPC ЕВВ 37/00, Е21В 36/04, publ. 05/20/2003], which includes the descent into the borehole to the upper boundary of the local electric heater plug on a multicore cable connected to the current source, the armor metal sheath of which is connected to the electric heater body, converting the material of the plug into the molten state by turning on the electric heater and moving it as the material melts traffic jams. In this case, an electric heater is used, the lower end of the electrode of which is in contact with the borehole electrically conductive fluid located directly above the upper part of the plug, which is used as an electrolyte.

The disadvantage of this method is the lack of a function for measuring the temperature of deposits in the zone of operation of the heating device, which reduces the quality of the regulation process and, accordingly, the manufacturability of the method.

The technical task is to expand the functionality of the method, by providing automatic control of the process of destruction of paraffin, hydrate, hydrate-paraffin and ice deposits in production wells, as well as the implementation of the cleaning process with the required frequency.

This problem is solved in that it includes a descent into the well to the upper boundary of the electric heater plug on a multicore logging cable, the armor metal shell of which is connected to the electric heater body. In the place where the electric heater is connected to the multicore cable, the three cores of the cable are connected together according to the "star" scheme. One of the cable cores on the surface is connected to the phase of a three-phase current source, and the armor metal sheath is connected to its zero contact. Next, the local electric heater is lowered until it reaches the plug, then the electric heater is turned on, the plug material is melted, and the lower end of the electric heater is in contact with the borehole electrically conductive fluid. After melting the plug, the multi-core wireline cable is lowered to the maximum cable length, fixed, each core of it is connected to the corresponding phase of the three-phase current source, it is turned on, the cable is transferred along its entire length to the linear heating device mode, and the annulus and tube space of the well are completely heated.

To ensure automatic control of the temperature of the electric heater, each phase of the three-phase current source is equipped with a current regulator, and the first thermal sensor located inside its housing and the second thermal sensor mounted on its outer surface are introduced into the electric heater. In this case, the inputs of the mentioned regulators are connected to the power outputs of the control unit, and the first and second temperature sensors are connected to its measuring inputs.

After the work, the wireline cable is fixed at the wellhead, disconnected from the physical and electrical contacts with the winch drum and left in a suspended position in the well with the possibility of periodically connecting to a three-phase current source as necessary.

Preferably, the three-phase power source and the control unit were placed on the platform of a terrain vehicle with high cross-country ability, the control unit was based on a microprocessor system, and thermistors were used as temperature sensors.

A positive technical result provided by the combination of the features of the method disclosed above is a significant expansion of its functionality for the destruction of deposits in production wells, due to the use of a three-phase current source, each phase of which is equipped with a current regulator, and temperature sensors, providing automatic temperature control of the heater depending on the temperature of the well fluid; An additional function of the control unit in this case may be the collection of statistical information on the temperature gradient of the formation fluid in the annulus during well cleaning. In addition, the invention allows to achieve an additional technical result, consisting in the ability to carry out preventive maintenance of the well at a predetermined frequency by placing a three-phase current source and a control unit on the platform of a ground vehicle.

The invention is illustrated by drawings, where in FIG. 1 shows a simplified diagram of connecting a three-phase current source to a multicore cable; in FIG. 2 - device electric heater, which is a local heating device of the open type; in FIG. 3 is a simplified block diagram of a control unit; in FIG. 4 is a diagram of the implementation of the method of destruction of deposits.

The method is carried out using a device including a three-phase current source 1 (Fig. 1), each phase of which is equipped with a current regulator 2, 3 and 4, each of which can be made on the basis of rheostats, IGBT transistors or heistors. A multicore logging cable 5 is connected to the current source (Fig. 2), protected by a metal sheath 6, connected to an electric heater 7, which is an open type local heating device, inside of which an electrode 8 is mounted, connected to a multicore cable 5 and insulated from the electric heater body 7 by an insulator 9, at the connection point 10 of the electrode of the electric heater 7 to the multicore cable 5, the three cores of the cable are connected together according to the "star" scheme. During operation, the lower end of the electrode 8 is in contact with the molten tube material. The electric heater 7 is equipped with a first temperature sensor 11 located inside its housing, and a second temperature sensor 12, mounted on its outer surface. The inputs of the current regulators 2, 3 and 4 (Fig. 1) are connected to the power outputs 13, 14 and 15 of the control unit 16, and the temperature sensors 11 and 12 are connected to its measuring inputs 17 and 18. In addition to the control unit 16, an indication unit 19 and data entry unit 20.

Preferably, the control unit 16 was made in the form of a microprocessor system including a microcontroller 21 (Fig. 3), for example, an AVR ATMega128 containing a RISC microprocessor 22 with general purpose registers and an integrated data memory connected to the FLASH program memory 23 connected to a common a bus with five universal bi-directional I / O ports 24, 25, 26, 27 and 28, two analog-to-digital converters 29 and 30, a non-volatile electrically reprogrammable memory unit 31, and a universal synchronous-asynchronous transceiver ICOM 32. In this case, the measuring inputs 17 and 18 of the control unit 16 are connected to analog-to-digital converters 29 and 30, the input-output ports 24, 25 and 26 are connected to the power outputs 13, 14 and 15 connected to the current regulators, the input port is output 27 is connected to the display unit 19, and the input / output port 28 is connected to the data input unit 20. It is advisable to perform the display unit in the form of a TFT display, and the data input unit in the form of a keypad containing at least sixteen keys.

The method using the described device is as follows.

Initially, the logging cable 5 with shorted cores according to the “star” pattern is connected to the electric heater 7 (Fig. 2), then in the faceplate 33 (Fig. 4), if necessary, an inclined hole is formed, a thread is cut in the hole for the stuffing box adapter 34, set it together with a multicore cable 5 in the sub and lower the assembly (cable 5 with electric heater 7) into the annulus of the well using a winch (not shown). At the same time, on the surface, one of the cores of cable 5 is connected to one phase of a three-phase current source 1, and the armor metal sheath is connected to its zero contact. The electric heater 7 is lowered until it reaches the plug, then it is turned on by applying a voltage of one phase (220V), while the lower end of the local heater 7 is in contact with the borehole electrically conductive fluid, the plug is melted.

After melting the plug of hydrate-paraffin deposits and reaching the required depth with the logging cable 5, the logging cable 5 is fixed at the wellhead with a lock 35 (Fig. 4). Cable 5 is connected through a current regulator 2, 3, 4 to a three-phase current source 1, as a result, a three-phase current is supplied to the entire logging cable 5, and since the cable has sufficient resistance due to its length (about 1400 meters), it allows you to use a cable with heating along its entire length as a linear heating device with a thermal power of about 100-110 kW. Heating along the entire length, the logging cable 5 raises the temperature in the annulus and tube space to the required temperature at which solid hydrate-paraffin deposits become liquid and are released to the surface when exposed to a displacing fluid.

After work, cable 5 is disconnected from the three-phase current source, an additional stuffing box is tightened and cable 5 is disconnected from the winch drum. The remainder of the cable 5 remaining on the surface is folded and closed with a moisture-proof material, near the wellhead in a specially equipped place.

To carry out preventive heating of the well, a three-phase current source 1 is delivered to the wellhead site, as a TP-63 power step-up transformer, and a control unit 16 placed on the platform of a high-cross-country vehicle 36, for example, a UAZ vehicle, can be used. Then, a multi-core logging cable 5 is connected to a three-phase current source 1 according to the described scheme, which is connected to a standard connector (380 V) at the cluster substation 37. Next, the temperature sensors 11 and 12 are connected to the measurement inputs 17 and 18 of the control unit 16, and its power outputs 13 , 14 and 15 are connected to the current regulators 2, 3 and 4 connected to the corresponding phases of the three-phase current source 1, the neutral wire is connected to the armor metal sheath 6 of the multi-core cable 5. Then, using the data input unit 20, the pair is corrected Three modes of regulation of the source of three-phase current 1 and a common electromagnetic starter (not shown) supply a voltage of 380 V.

After the preventive heating of the annular space of the well has begun, the microcontroller 21 of the control unit 16 measures the temperature of the electric heater and the surrounding formation fluid using temperature sensors 11 and 12. At the same time, in accordance with the control program recorded in the FLASH memory 23, the microcontroller 21 issues a sequence of control PWM signals to input-output ports 24, 25 and 26, thereby regulating the amount of current supplied to cable 5. After cable 5 reaches operating temperature, deposition of ehodyat the plastic state and being dissolved in heated stream rising in the tubing of reservoir fluid pipes come to the surface. At this stage, the underground pumping equipment of the serviced well operates in the mode of pumping formation fluid and lifting it to the surface.

During operation of the device, the temperature measurements made by the microcontroller 21 are stored in its non-volatile memory 31. In the future, they can be transferred using a universal synchronous-asynchronous transceiver 32 to a personal computer for further processing in order to establish rational time intervals for conducting well cleaning.

After the destruction of the newly formed deposits is completed, the three-phase current source 1 is disconnected from the multi-core logging cable 5, and the temperature sensors 11 and 12 are disconnected from the measuring inputs of the control unit 17 and 18, then the cable is canned as described above until its next use.

Thus, the method described above allows you to effectively carry out the process of eliminating hydrate-paraffin deposits at the required depth (up to 1400 m) and maintain optimal preventive thermal conditions in the well until its scheduled repair without the use of additional complex ground equipment at the mouth site. Moreover, a sufficient condition for the implementation of the method is the use of a three-phase current source and control unit, and placing them on a mobile platform of a land vehicle allows servicing several tens of wells, which significantly reduces the cost of the work to prevent them, and by creating the necessary fund of wells, having the ability at any time to be included in the preventive mode, eliminates the additional cost of lowering the cable to the working depth well, which increases productivity and allows maintenance to be carried out in a preventive mode for a larger number of wells than is possible with known technologies.

Claims (3)

1. The method of destruction of paraffin, hydrate, hydrate-paraffin and ice deposits in production wells to maintain their operating mode, including the descent into the well to the upper boundary of the plug of the local electric heater on a multi-wire logging cable, the armor metal shell of which is connected to the metal body of the electric heater, characterized in that in the place of connecting the electric heater to the multicore cable, three cable conductors are connected together according to the “star” scheme, and one of the cable conductors on the surface and connected to the three-phase power source phase and the metal shell Book connected to its zero contact; the electric heater is lowered until it reaches the plug, then it is turned on and the plug material is melted, while the lower part of the open type electric heater electrode is in contact with the borehole electrically conductive fluid; after melting the plug and lowering to the maximum depth of the multicore logging cable, it is fixed, each core of it is connected to the corresponding phase of a three-phase current source, it is turned on, the cable is transferred along its entire length to the heating device mode, and the annulus and pipe space of the well are completely heated; each phase of the three-phase current source is equipped with a current regulator, and a first temperature sensor located inside its housing and a second temperature sensor mounted on its outer surface are introduced into the local electric heater, while the inputs of the mentioned regulators are connected to the power outputs of the control unit, and the first and second temperature sensors are connected to its measuring inputs, after which the wireline cable is fixed at the wellhead, disconnected from the physical and electrical contacts with the winch drum and left suspended dix downhole to periodically connect to a source of three-phase current as needed. 2. A method for destroying paraffin, hydrate, hydrate-paraffin and ice deposits in production wells to maintain their operating mode according to claim 1, characterized in that the three-phase current source and control unit are placed on a platform of a terrain vehicle with high cross-country ability. 3. The method of destruction of paraffin, hydrate, hydrate-paraffin and ice deposits in production wells to maintain their operating mode according to claim 1, characterized in that the control unit is based on a microprocessor system.

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