EA016999B1 - Device for producing an electrohydraulic effect on a well bottom-hole zone - Google Patents

Abstract

Use of the invention: recovery and increase of the oil, gas and water wells output, repair of the casing, and high-resolution seismic prospecting. Technical result: reduction of energy losses in the logging cable and providing the device efficiency with the logging cable longer than 5-6 km. Essence of the invention: the proposed device includes the surface power supply connected by means of a logging cable to the borehole electric-discharge device consisting of a charging unit, capacitor energy storage, a switching unit and an electrode system which are the individual modules, herewith the charging unit comprises an oil-filled case with a low-voltage input on one end and a high-voltage output on the other end, the step-up transformer, the high-voltage rectifier and the protective choke are installed inside the case, herewith one end of the secondary winding of the step-up transformer is connected through the high-voltage rectifier and the protective choke to the high-voltage output, and second end of the secondary winding of the step-up transformer is connected to the case, the discharge resistor and the measuring CR-circuit are switched in parallel between the high-voltage output and the case, the time constant of the measuring CR-circuit is chosen smaller than the time constant of the capacitor storage discharge, the surface power supply represents a DC source and the charging unit includes additionally a capacitive filter, a bridge inverter based on transistors and an inverter control circuit, herewith, the capacitive filter, one of the diagonals of the bridge inverter and the input of the inverter control circuit are connected in parallel to the low-voltage input, and the resonance capacitor, the current sensor and the primary winding of the step-up transformer are switched to the other diagonal of the bridge inverter, the output of the inverter control circuit is connected to the control electrodes of the transistors.

Description

FIELD OF THE INVENTION

The invention relates to the oil and gas industry, in particular to high-voltage electro-hydraulic devices designed to restore and increase the flow rate of oil, gas and water wells, eliminate leaks in casing strings, as well as high-resolution seismic surveys.

State of the art

A device for electro-hydraulic treatment of the formation and increase its oil recovery (see US patent No. 4345650, NKl. 166-249, MKl. E21 B43 / 256, 1982), containing a tubular metal housing with a cable adapter at one end and a rotary discharge head at the other end and located in the tubular housing, a step-up transformer, a high-voltage rectifier, a capacitor bank and a controllable switch, while the charge and discharge control means are connected to the capacitor bank and a ground power source through a geoph phe- cable, the secondary winding of the transformer is connected to the rectifier circuit, the rectifier output is connected to a potential terminal of the capacitor bank, the potential output capacitor bank is connected via a controllable switch to the anode of the discharge head.

The capacitor bank includes a large number of parallel-connected capacitors, each with a working voltage of 3 kV and a capacity of 100 μF, total capacitors up to 1000 pcs. The switch is a standard ignitron. Ignitron ignition is carried out from a separate injection capacitor bank with an operating voltage of 30 kV. The step-up transformer consists of a W-shaped core and primary and secondary windings. The discharge head consists of two electrodes with an adjustable gap. The discharge head is equipped with a rotary mechanism and a reflector for the concentration and direction of acoustic energy towards the producing well. All of the above constituent elements of the device are located in the same compartment of the tubular body and are separated from each other by metal partitions.

The disadvantages of the analog device:

low operating voltage of 3 kV capacitor bank, which complicates the conditions for the formation of an electric discharge in the borehole fluid and reduces the amplitude of the shock wave and the force of impact on the bottomhole formation zone;

high power consumption of the device up to 450 kJ and low electrical and electro-acoustic efficiency;

the presence of an additional injection battery of 30 kV to facilitate the breakdown of well fluid at the initial stage;

the inability to use the device in horizontal oil wells due to the unstable (floating) position of the mercury cathode in the ignitron;

the difficulty of controlling the ignitron due to the need to lay the ignition bus through a capacitor bank;

poor maintainability of the device and the controllability of its stored and output energies, since the transformer, rectifier, capacitor and switching blocks are located in the same oil-filled tubular casing and, in addition, numerous partitions inside the casing make it difficult to connect these blocks to each other and repair them.

The closest in technical essence to the claimed device - the prototype is a device for influencing the bottomhole zone of the well (see EAPO patent for invention No. 010901 dated 10.26.2006, IPC Е21В 43/25, publ. 30.12.2008, authors Kartelev A.Ya. et al.). This device contains a ground-based power source and a borehole apparatus connected by means of a geophysical cable, consisting of a charging unit, a capacitor energy storage device, a switch and an electrode system, while the charging unit, a capacitor energy storage device, a switch and an electrode system are made as separate modules, the modules are connected each other electrically and mechanically by screwing up, each of the modules is enclosed in an autonomous metal case and is equipped with insulated current leads and two-level waterproofing from the external environment: external in the form of sealing elements at least at one end of the module housings and internal in the form of sealing elements at the output insulators and current outputs of the modules.

The charging unit in this device contains an oil-filled metal case with a low-voltage input and a high-voltage output at opposite ends and a step-up transformer, a high-voltage rectifier, a protective choke, a discharge resistor and a measuring CB-circuit located inside the case, while the primary winding of the step-up transformer is connected to the low-voltage input, the secondary winding of the step-up transformer is connected to a high-voltage bridge rectifier assembled according to a bridge circuit or circuit with by multiplying the voltage, one of the rectifier leads is connected through the protective inductor to the high-voltage output, and the second rectifier output is connected to the housing, the discharge resistor and the measuring CB-circuit are connected in parallel between the high-voltage output and the housing, the time constant of the measuring circuit is chosen less than the discharge time constant of the capacitive storage. The housing of the charging unit is made in the form of a steel pipe with a diameter of 102 mm and a length of 1 m. The operating voltage of the charger

- 1 016999 block 30 kV.

The power supply of the charging unit is carried out from a ground source of power and control connected to an industrial network of 220 V, 50 Hz and generating an alternating voltage with a frequency of 1 kHz and an amplitude of up to 800-900 V. at the output of the ground source - input of the geophysical cable

The disadvantages of the prototype device are:

significant weight and size indicators of the charging unit (length of about 1 m, weight 25 kg), which affects the performance of the entire borehole electro-hydraulic apparatus;

large (at least up to 56%) active and reactive power losses on the geophysical cable when the apparatus is supplied with alternating voltage, which is especially evident when the length of the geophysical cable is more than 5 km, as a result of which the power and voltage at the input of the charging unit decrease and, accordingly, its output voltage decreases.

For this reason, with a long geophysical cable, the capacitor modules are not recharged and the switch of the borehole electro-hydraulic apparatus does not work. In fact, the following happens: the ground-based power and control panel is operating at full power, but the downhole apparatus does not reach the mode of repeated discharges of electro-hydraulic shocks. As a result, the bottom-hole zone of an oil well is not cleared of asphalt-tar and paraffin deposits.

SUMMARY OF THE INVENTION

The main task solved by this invention is to ensure the operability of the apparatus with geophysical cable lengths of more than 5-6 km. An additional objective is to reduce the weight and dimensions of the charging unit of the downhole apparatus.

The main technical result of the invention is the reduction of energy losses on the geophysical cable and ensuring the operability of the apparatus with the length of the geophysical cable more than 5-6 km.

The specified technical result is achieved by the fact that in the known device for influencing the bottom-hole zone of the well, comprising a ground-based power source and a downhole electric discharge apparatus connected via a geophysical cable, including a charging unit, a capacitor energy storage device, a switch and an electrode system made in the form of separate modules, this charging unit contains an oil-filled metal housing, at one end of which is installed a low-voltage input, and at the other end - high-voltage st output, a step-up transformer, a high-voltage rectifier, a discharge resistor, a protective inductor and a measuring SK.circuit are placed inside the case, while one end of the secondary winding of the step-up transformer is connected through a high-voltage rectifier and a protective inductor with a high-voltage output, and the second end of the secondary winding of a step-up transformer connected to the housing, the discharge resistor and the measuring SK.-chain are connected in parallel between the high-voltage output and the housing, the time constant of the measuring SK.-ts the kidney is selected less than the discharge time constant of the capacitive storage, the new one is that the ground power source is a direct current source, a capacitive filter, a bridge inverter with transistors and an inverter control circuit are additionally introduced into the charging unit, while the capacitive filter is one of the diagonals of the bridge inverter and the input of the inverter control circuit is connected in parallel to the low-voltage input, the second diagonal of the bridge inverter is connected through the resonant capacitor and the current sensor to the primary ohm winding of the step-up transformer, and the output of the inverter control circuit is connected to the control electrodes of the transistors.

Replacing a ground power source with an alternating output voltage with a power source with a constant output voltage (current) eliminates the influence of the reactive component of the electrical impedance of the geophysical cable on the output power of the ground power source and, as a result, reduces its power consumption and output (in the prototype, the output power of the ground the power source is 3 kW, the proposed device has enough power of 1.5 kW);

reduce by at least 13% the energy loss in the conductors of the geophysical cable and, accordingly, ensure the operability of the borehole electric discharge apparatus with geophysical cable lengths or operating depths exceeding 5-6 km;

eliminate electromagnetic interference to the third control core of the geophysical cable, through which a control pulse is transmitted to the earth’s surface at each discharge of the device, carrying information about the parameters of the discharge current of the device (state of the device and the level of the shock wave affecting the oil reservoir).

The input to the charging unit of a capacitive filter, a bridge inverter on transistors and an inverter control circuit and the organization of their connections and interactions as in the claims provides a current-free switching of power transistors in a bridge inverter, which allows to reduce switching losses and electrical overload of radio elements, to organize a safe operation mode of power transistors ( the weakest link of devices of this kind);

low level of electrical noise generated during operation of power transistors of a bridge inverter, which can significantly improve the mutual electromagnetic compatibility of individual nodes of the charging unit;

- 2 016999 pulse-frequency control mode, which increases the stability of the bridge inverter and the control circuit to interference arising from high-current (up to 30 kA) discharges of the condenser energy storage of the downhole apparatus.

List of figures of drawings and other materials

In FIG. 1 shows a block diagram of the proposed device.

In FIG. 2 shows the electrical circuit of the charging unit of the proposed device.

In FIG. Figure 3 shows the dependence of the power transmitted through the geophysical cable from the ground-based power and control source to the charging unit and the capacitor storage energy of the downhole apparatus, with the conditional output power of the ground-based power and control panel 1 kW and various frequencies of the supply voltage (from constant to variable frequency 5 kHz) .

Information confirming the possibility of carrying out the invention

The proposed device for electro-hydraulic treatment of the reservoir contains (see Fig. 1) a ground source of power and control 1, a load-bearing geophysical cable 2 and a borehole electro-hydraulic device 3.

The borehole electro-hydraulic device 3 is a multi-module design consisting of one charging unit 4, from one to five, depending on the modification and purpose of the device, capacitor modules 5, switch 6, and electrode system 7. In accordance with the declared features of the power supply, the device is given the name ERA -5 ° C.

Each unit module of the device is enclosed in a self-contained metal case with connecting threads at the ends and is equipped with insulated current leads and two-level waterproofing from the external environment: external in the form of sealing elements at least at one end of the module housings and internal in the form of sealing elements at the output insulators and current outputs of modules.

The diameter of all the module blocks of the borehole electro-hydraulic apparatus is 102 mm. The lengths of the device modules are different: the charging unit 4 and the capacitor module 5 are 1.0 and 1.2 m long, respectively, the switch 6 and the electrode system 7 are 0.37 and 0.4 m long. The weight of the capacitor module does not exceed 30 kg module - 25 kg, switch - 7.5 kg, electrode system - 9 kg.

The unit modules of the device are connected to each other electrically and mechanically by screwing.

As a ground source of power and control 1, it is advisable to use a commercially available secondary power source of the Cepeku series for the production of the Israeli company Latya-B-ΛΜΒΌΛ CEY600-2.6 (see the magazine Syr Lekk, No. 2 (85), 2004 ) This power supply has a power of 1500 W and provides an adjustable output DC voltage from 0 to 600 V and a load current from 0 to 2.6 A. The LAMBOA CEY600-2.6 source can operate from a single-phase AC network with voltage from 85 to 265 At a frequency of 50 / 60Hz, which is important when operating in the field. It is also characterized by a high power factor of 0.99 at full load, provided by the active power factor correction circuit.

Configurable overvoltage protection and current limiting with a sharp knee-shaped characteristic ensure high reliability of the device. The settings of the protection settings can be pre-set and presented on the display located on the front panel of the source.

Additional important functions of the secondary power supply of the Sepekuk series are the safe inclusion and storing of the settings that were set last. Function bac! 8ey1pd The method saves the settings for the output voltage and current, remote or local mode, settings for overvoltage and undervoltage protection, current limits, data transfer rate and power-on mode without using a battery. The front panel also has power on / off controls and a choice of remote and local controls. Through the K.8-232 / K.8-485 interface, source control from a personal computer can be organized.

Such high functionality, reliability and compactness of the LAMBOA CEY600-2.6 power supply make it possible to build on its basis a complete ground-based power and control panel for a borehole electro-hydraulic apparatus.

Geophysical cable 2 standard three-core with ohmic resistance lived 24-25 Ohm / km.

The charging unit 4 in this apparatus contains (see Fig. 2) an oil-filled metal housing 8 with a low-voltage input 9 at one end and a high-voltage output 10 at the other end. The housing 8 of the charging unit is made in the form of a steel pipe with an outer diameter of 102 mm and a length of approximately 0.7 m. The low-voltage input 9 is a standard three-socket or three-pin cable head, to which the cable lug of the geophysical cable 2 is connected. The high-voltage terminal 10 is a metal pin, located along the axis of the housing 8 and isolated from it using the output high-voltage insulator 11.

- 3 016999

Inside the housing 8 of the charging unit there is a step-up transformer 12, a high-voltage rectifier 13, a protective inductor 14, a discharge resistor 15 and a measuring CB chain from a capacitor 16 and two resistors 17 and 18, a capacitive filter 19, a bridge inverter 20 with transistors, a control circuit 21 of the inverter and a resonant capacitor 22, while the capacitive filter 19, one of the diagonals of the bridge inverter 20 and the input of the control circuit 21 of the inverter are connected in parallel to the low-voltage input 9, the second diagonal of the bridge inverter 20 is connected through a cut the onance capacitor 22 to the primary winding of the step-up transformer 12, the output of the control circuit 21 of the inverter is connected to the control electrodes of the transistors of the bridge inverter 20, the secondary winding of the step-up transformer 12 is connected to one diagonal of the bridge high-voltage rectifier 13, the second diagonal of the bridge rectifier 13 is connected to the high-voltage terminal 10 and the case 8 through a protective inductor 14, between the high-voltage terminal 10 and the housing 8, a discharge resistor 15 and a measuring CB chain from a conde are connected in parallel Satoru 16 and two resistors 17 and 18, the time constant of the measuring SV-chain chosen less constant storage capacitor discharge time.

Capacitor modules 5 are identical in design and stored energy. Each capacitor module contains a group of series-connected or parallel-connected and oil-impregnated capacitor sections located in a metal casing, the metal casing being the cathode. Capacitor modules have output high-voltage insulators, current outputs and connecting threads (one internal, the other external) at both ends. Due to this, it becomes possible to connect capacitor modules into a chain line, as well as charge capacitor modules from one end of the module and discharge to the load from the other end of the module. The operating voltage of each capacitor module is 30-35 kV, the energy consumption is 1 kJ, the inductance is not more than 120 nH.

The charging unit 4 and the capacitor modules 5 are evacuated and filled with condenser oil. High-voltage insulators in the charging unit 4 and the capacitor modules 5 are installed with seals relative to the current leads and the housing. Inside the charging 4 and condenser modules 5, temperature compensators are installed to expand the condenser oil at elevated temperatures, which are usually observed in the well. The temperature resistance of the charging unit and capacitor modules is 100 ° C.

Switch 6 is an uncontrolled gas-filled (nitrogen or hydrogen) discharger with a fixed operating voltage, also located in a metal case and equipped on both sides with current leads, high-voltage insulators and seals.

The electrode system 7 has a central anode rod, a fairing insulator, and a cathode with a flat surface mounted with a gap relative to the anode and connected to a metal casing, in which up to twelve longitudinal slots are made to communicate the internal volume of the system with the borehole fluid and a high-velocity fluid discharge during electric discharge. The fairing insulator is installed with seals relative to the metal casing and the central anode to prevent breakthrough of the borehole fluid, which is under high reservoir pressure of 200-300 atm, in the direction of the switch 6. The cathode has a threaded shank, which allows you to adjust the gap between the cathode by screwing / unscrewing the anode and cathode of the electrode system and its electro-acoustic efficiency.

The assembly of the borehole electro-hydraulic apparatus and all intermodular electrical and mechanical connections are carried out in two simple operations: installing ring rubber seals on the ends of the modules and sequentially screwing the modules together.

The proposed device operates as follows.

When you turn on the ground source 1 power supply series Sepekuk at its output starts to gradually increase the DC voltage. A direct current occurs in the geophysical cable 2, which charges the input (filtering) capacitor 19 of the charging unit 4 to a threshold value determined by the control circuit 21 of the charging unit. The voltage drop across the geophysical cable is easily compensated by an increase in the output voltage of the ground power source. When the voltage reaches the threshold value at the input (filtering) capacitor 19, the control circuit 21 generates control signals to the power transistors of the bridge inverter 20 with a frequency and duration according to the parameters of the resonant circuit formed by the resonant capacitor 22 and the dissipation inductance (primary winding) of the step-up transformer 12 included in the diagonal of the bridge inverter 20. The control circuit 21 operates in self-oscillating mode as long as the voltage at the input capacitor 19 is greater than the thresholds st. The alternating voltage obtained in the bridge inverter 20, similar in shape to a sinusoidal and frequency of tens of kilohertz, is applied to the primary winding of the step-up transformer 12, increased in it and fed from the secondary winding of the step-up transformer 12 to a high-voltage rectifier 12, assembled according to a bridge or multiplication circuit voltage, where it is straightened and multiplied, respectively, 2 or 4 times. From the rectifier 12, a high and rectified voltage is supplied to the high-voltage output 10 of the charging unit, and from it to the capacitor modules 5 of the borehole electro-hydraulic apparatus.

- 4 016999

The authors performed a circuit simulation of the operation of the new charging unit for a capacitive load With _n = 0.01 μF (1000 times smaller than the capacitance of the capacitor modules of the ERA-5ES apparatus to reduce simulation time). The results of circuit simulation of a new charging unit with a geophysical cable 5 km long showed the following:

switching to a borehole electro-hydraulic apparatus with a constant voltage leads to a reduction in losses on the geophysical cable and a 13% increase in the power transmitted to the charging block and capacitor modules of the ERA-5ES apparatus (the electric power at the input of the charging block increases when changing from a supply frequency of 1 = 1 kHz to 1 = 0 from 440 to 560 W with the conditional output power of the ground power and control panel 1 kW, see Fig. 4);

the new charging unit provides a capacitor charge of C _n = 0.01 μF to a voltage of 30 kV for 5 ms. Accordingly, the capacitor modules of the ERA-5ES apparatus with a total capacity of C = 10 μF will be charged (provided that they have a linear charge of O = 1T = IC) to a voltage of 30 kV in a time of no more than 5 s.

At the same time, the power of the secondary power source of 1.5 kW will be sufficient for charging the capacitor modules of the ERA-5ES apparatus (in the prototype, the output power of the ground power source is 3 kW).

Thus, the results of calculations and analysis of the modern elemental base have shown the promise and the real possibility of developing a power and charge system for the ERA-5ES downhole electro-hydraulic apparatus, consisting of a ground-based power and control panel based on a direct current source and an in-depth charging unit with an integrated high-frequency voltage converter. This will ensure a reduction in energy losses on the geophysical cable and the operability of the ERA-5ES apparatus with geophysical cable lengths of more than 5-6 km. In addition, the conditions for recording and processing the control pulse of the device carrying information about the parameters of the discharge current of the device (about the state of the device and the level of the shock wave affecting the oil reservoir) will improve.

Claims (1)

CLAIM A device for electro-hydraulic impact on the bottom-hole zone of a well, comprising a ground source of power and control connected by a geophysical cable and a downhole electric discharge apparatus including a charging unit, a capacitor storage of energy, a switch and an electrode system made in the form of separate modules, wherein the charging unit contains an oil-filled metal case, on one end of which a low-voltage input is installed, and on the other end - a high-voltage output, inside the case a step-up transformer, a high-voltage rectifier, a discharge resistor, a protective choke and a measuring CP circuit, with one end of the secondary winding of the step-up transformer connected through a high-voltage rectifier and a protective choke with a high-voltage output, and the second end of the secondary winding of a step-up transformer connected to the housing, a discharge resistor and a measuring CP chains are connected in parallel between the high voltage terminal and the housing, the time constant of the measuring CP chain is chosen less than the constant of the discharge time of the capacitive storage, characterized in that the ground-based power supply is a direct current source, a capacitive filter, a bridge inverter with transistors and an inverter control circuit are additionally introduced into the charging unit, while a capacitive filter, one of the diagonals of the bridge inverter and the input of the control circuit the inverter is connected in parallel to the low-voltage input, the second diagonal of the bridge inverter is connected through the resonant capacitor to the primary winding of the step-up transformer, and the output d inverter control circuit is connected to the control electrodes of the transistors.