RU2536596C1 - Power supply and bottomhole information transmission unit - Google Patents

Abstract

FIELD: physics, geophysics.

SUBSTANCE: invention relates to geophysical studies during drilling of oil and gas wells using telemetering systems with wireless electromagnetic data link. The power supply and bottomhole information transmission unit contains the turbine, electrical generator, electrical separator in assembly with the drilling string, module of sensors for measuring of bottomhole information and electronic unit. Meanwhile the electronic unit contains the bidirectional triode thyristor unit, bidirectional triode thyristor control unit, impulse signal current sensor, voltage sensor of the power winding of the electrical generator and temperature sensor, meanwhile the electronic unit is installed in tight compartment of the electrical generator housing, which in addition functions as a heat sink. Besides bidirectional triode thyristors are installed on the electrical generator housing itself, and the electronic unit is designed with a possibility of automatic stabilization of the current of transmission impulse signal and its restriction at exceeding the preset temperature of the bidirectional triode thyristor unit.

EFFECT: improvement of reliable transmission of impulse signals via electromagnetic data link and maximum possible depth of drilling.

4 cl, 1 dwg

Description

The invention relates to geophysical surveys in the process of drilling oil and gas wells using telemetry systems with a wireless electromagnetic communication channel.

A known invention related to the field of well drilling, which can be used to measure downhole parameters of a well during drilling (RU 2278256, publ. 06/20/2006). A downhole telemetry system with an electromagnetic communication channel, containing ground receiving and processing equipment, an electrical column separator and its alternator and downhole equipment installed below, with measuring sensors and an electronic transmitting unit. The electronic transmitting unit of the downhole equipment is connected to the generator from above through an electrical connector under the power cable. The autonomous power supply module and measuring modules of the downhole equipment are connected to the generator by means of low-current wires through the lower electrical connector.

Closest to the technical nature of the claimed device is a downhole telemetry system (RU 2190097, publ. 09/27/2002), mounted on drill pipes, which contains a turbogenerator, an electric column separator (ERK), an electronic module and measuring sensors. Sensors are located on the upper sub and on the insulator of the ERK inside it, while magnetically sensitive sensors are placed inside the ERK in the region of its insulator. The electronic module is connected directly to the turbogenerator, the base of the housing of which seals the electronic module. The electric wires connecting the electronic module to the rest of the system through the connector of the electronic module and then the turbogenerator’s hermetic inputs are connected to the output of the latter, and through the connectors on the turbogenerator’s body, the counterparts of which are located on the upper sub of the ERC, the electronic module and the turbogenerator are connected to the sensors located on Erk case, and lower Erk sub. The connection with the lower sub of the ERC is made in the form of a conductive non-magnetic grid, covering the insulator of the ERC and isolated from the upper sub, or evenly spaced along the generatrix of the insulator of the ERC of the wires.

However, the well-known downhole telemetry systems are characterized by a limited range of data transmission and the inability to work at great depths, as well as in sidetracking modes and when drilling in the casing, when there are modes that are close to short circuit.

The objective of the present invention is to increase the range of reliable transmission of pulsed signals through an electromagnetic communication channel and the maximum possible drilling depth, increase the reliability of the power supply device and transmit bottomhole information and expand functionality, including working in sidetracking modes and in the casing, i.e. . in conditions close to short circuit.

The solution to this problem is achieved by the fact that the device for power supply and transmission of downhole information, including a turbine, an electric generator, an electric separator in a design with a drill pipe string in which the equipment is mounted, a module for measuring downhole information, in particular, an inclinometer module and / or a gamma module well-logging, an electronic unit, while the electronic unit contains a triac block, a triac control unit, a pulse current sensor, an electric power winding voltage sensor eskogo generator, a temperature sensor, the electronic control unit is mounted in a sealed compartment housing an electric generator, and triacs mounted directly on the generator housing. The module for measuring downhole information comprises a block of measuring sensors, a calculation unit and a power supply. The electric generator has two isolated windings: the first (instrument) winding is used to power the electronic units of the claimed device, the second (power) winding is used to form a pulse signal transmitted to the surface. The module for measuring downhole information (for example, the inclinometer module) transmits information to the electronic unit in the form of data packets with a specified repetition interval via an agreed interface. The electronic unit receives data, encodes and transmits it to the surface by switching the voltage of the power winding of the electric generator by the block of triacs. The block of triacs is implemented according to the bridge circuit so that the inputs of the triac bridge are connected to the outputs of the power winding of the electric generator and the voltage sensor, the first output of the bridge is connected through the current sensor of the pulse signal to the body of the electric generator and, accordingly, to the upper part of the drill pipe string, and the second output through an insulated wire of a cable group located in a connecting rod passing through an electrical splitter is connected to the bottom of the drill pipe string. The location of the triac unit and the triac control unit in the sealed compartment of the electric generator housing allows you to use the electric generator housing as a radiator to dissipate (heat sink) the heat generated during the operation of the triacs, which makes it possible to increase the maximum power of the pulse signal generated by the triac block. In this case, the electronic unit is configured to automatically stabilize the current of the pulse signal, based on the maximum current value set when setting the electronic unit, and the electronic unit is configured to limit it when the set temperature of the triac block is exceeded by automatically correcting the maximum current value of the pulse current signal in the direction of decreasing when exceeding a predetermined temperature threshold of the block of triacs up to blocking the operation of the bl ka Triac on reaching its maximum temperature. The stabilization of the pulse signal current will maximize the signal transmission power for the current degree of heating of the triac unit without the risk of failure of the triac due to overheating of the p-n junctions of their crystals, which is especially important for large drilling depths. Secondly, this will allow the device to be used in almost short circuit modes, which occurs during sidetracking and when drilling in a casing string.

In Fig.1 shows a device for power supply and transmission of downhole information, a General view.

The proposed device contains the upper part of the drill pipe string 1, turbine 2, electric generator 3, electronic module 8, which includes a current sensor 4 of a pulse signal, a voltage sensor 5 of the power winding of the electric generator 3, a temperature sensor 6, a block of triacs 7, a control unit for triacs 9, the case of the electric generator / radiator 10, the cable group 11, the connecting rod 12, the electrical splitter 13, the protective casing 14, the module for measuring downhole information 15, the lower part of the drill pipe string 16.

The device operates as follows.

The drilling fluid drives the turbine 2 of the electric generator 3, providing power to the electronic components of the device and the pulse signal current transmission. The sensor module for measuring downhole information 15 (for example, the inclinometer module) performs measurements and calculations, and transmits the results as a data packet via the agreed interface to the electronic unit 8, namely to the control unit of the triacs 9 located in the sealed compartment of the housing 10 of the electric generator 3 The triac control unit 9 encodes the received data and controls the switching of the triac unit 7, which generates transmission signals in the form of electric current pulses emitted by a dipole, composed m insulated electric separator 13, bottom 16 and upper portions of the drill string 1 in the thickness of the reservoir for receiving a terrestrial signal receiver.

The block of triacs 7 is implemented according to the bridge circuit, and the inputs of the triac bridge are connected to the outputs of the power winding of the electric generator 3 and to the voltage sensor 5 of the power winding of the electric generator 3, the first output of the bridge is connected through the current sensor 4 to the body of the electric generator 3 and, accordingly, with the upper part of the drill pipe string 1, and the second bridge exit through the insulated wire of the cable group 11 located in the connecting rod 12 installed in the electrical splitter 13, is connected to the lower part Stu drill string 16.

The current of the transmission pulsed signal is generated in the near-tube space by a dipole formed between the upper 1 and lower 16 parts of the drill pipe string, insulated by an electrical separator 13, and reaches the Earth's surface, where it is captured and decrypted by ground-based receiving equipment (not shown in the drawing). To increase the drilling depth, it is necessary to ensure the maximum possible transmission distance of the dipole current pulses, which is determined by the transmitted signal power, calculated as the product of the effective values of the transmission current and the voltage of the power winding of the electric generator.

The maximum transmit power is limited by the maximum allowable power dissipation at the triacs at the pn junction temperature of the crystal at the current time.

According to the results of measuring the temperature of the triacs using a temperature sensor 6, the current value of the pulse signal and the voltage of the power winding of the generator, measured by the current sensor 4 of the pulse signal and voltage sensor 5, the actual and allowable power of the transmission pulse signal is calculated. The actual radiation power is brought to the permissible heating temperature for the triac bodies at a given temperature by adjusting the transmission current using the triac control unit 9.

The installation of triacs directly on the casing 10 of the electric generator 3, which has a significant contact area with the drilling fluid washing the casing of the generator from the outside, and, as a result, the low thermal resistance “casing-medium”, can significantly increase the heat removal from the triacs, and therefore increase the permissible power generated pulse signal transmission.

In known devices, triacs are located on small-sized radiators, between the radiators of the triac unit and the protective casing there is a structurally unremovable air gap that creates additional thermal resistance. The gap is formed due to the fact that the inclinometer module is installed with a sliding fit into the protective casing, and the radiator of the triac unit must have a substantially smaller diameter than the inner diameter of the protective casing and a length limited by the total length of the module. Thus, by increasing the heat transfer of the triacs in the claimed device, it is possible to increase the maximum power of the transmission pulse signal in comparison with the known devices. In addition, in the inventive device, compared with known devices, the reliability is increased, which is provided by adjusting the power of the generated transmission pulse signal depending on the temperature of the triacs. For this, a current sensor 4 of the pulse signal, a voltage sensor 5 of the power winding of the electric generator 3 and a temperature sensor 6 of the triac unit 7 are introduced into the device. This allows you to adjust the transmit power to the level of triacs permissible at a given temperature by adjusting the transfer current, which prevents the triac from overheating and exit them out of order.

The proposed device provides:

- an increase in the power of the pulsed transmission signal by increasing the heat transfer of the triacs installed directly on the body of the electric generator, which increases the range of reliable data transmission and, accordingly, the maximum possible drilling depth;

- the current of the pulse signal transmitted to the surface, when the device is operating, when the temperature of the triacs does not exceed a predetermined threshold value, it is not just limited, as is realized in known devices, but stabilized at the level of a given setting, which under normal conditions allows you to extract the maximum transmit power, and in extreme conditions, for example, in the event of a short circuit, provides triac protection against breakdown;

- in the inventive device, it is possible to use inclinometer modules of various manufacturers that meet only the requirements of consistency in interface and power, since all encoding and data transfer functions are implemented in an electronic module, structurally located in an electric generator;

- heating the block of triacs in the inventive device does not lead to heating of the measuring sensors of the sensor module measuring downhole information and, therefore, does not entail a deterioration in the operational characteristics of the latter;

- the claimed device allows you to use it in the mode of sidetracking, when drilling in the casing in an almost short circuit, due to the fact that the maximum current of the transmission pulse signal is automatically stabilized at the level of the setpoint, and if the triac threshold temperature is exceeded, it is limited to in accordance with the temperature correction of the setting of the transmission current in the direction of decreasing the latter.

Claims (4)

1. A device for supplying and transmitting downhole information, including a turbine, an electric generator, an electrical isolator in a design with a drill pipe string, a module for measuring downhole information, an electronic unit, characterized in that the electronic unit containing a triac block, a triac control unit, a current sensor a pulse signal, a voltage sensor of the power winding of the electric generator and a temperature sensor, is installed in the sealed compartment of the electric generator housing, which is an additional performs the function of the radiator, wherein the triacs mounted directly on the housing of the electric generator and the electronic unit is adapted to automatically stabilize the current transmission pulse signal and its limitations when exceeding a predetermined temperature triacs unit. 2. The device according to claim 1, characterized in that the block of triacs is made in the form of a triac bridge, while the inputs of the bridge are connected to the outputs of the power winding of the electric generator and a voltage sensor, the first output of the bridge is connected through the current sensor of the pulse signal to the upper part of the drill pipe string and the second outlet is connected to the bottom of the drill pipe string. 3. The device according to claim 1, characterized in that the inclinometer module and / or the gamma-ray logging module are mainly used as a module for measuring downhole information. 4. The device according to claim 1 or 3, characterized in that the sensor module for measuring downhole information contains a block of measuring sensors, a calculation unit and a power supply.

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