RU2571867C1 - Submersible module (versions) and power transmission system (electric energy) (versions) - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: power transmission system includes surface block connected to the submersible module via the power supply circuit of the submersible motor to transfer low power energy for submersible module operation and for bidirectional data communication. Surface block contains power source, control device of surface block and current monitor, and submersible module contains power and data communication device, and control device of the submersible module that processes data of any one measuring device. At that the surface block contains additional power source and multiplexer, at that first input/output of the multiplexer is input/output of the surface block, to the second input/output of the multiplexer the current monitor input/output is connected, to the first input of the multiplexer the first output of control device of surface block is connected, and to the second input the output of additional power source is connected, second output of control device of surface block is connected to power source input, the power source input is connected to input of the current monitor, and current monitor output is connected to input of control device of surface block. Under the first option of the system and submersible module the later contains demultiplexer to separate the supplied to its first input/output (submersible module input/output) large power energy. The second input/output of the demultiplexer is connected to the second input/output of power and data communication device, output is connected to input of the electric energy converter, and input is connected to output of the control device of submersible module, and its second input/output is connected to input/output of electric energy converter, its output is output of submersible module. Under second option of design of system and submersible module the later contains submersible block and remote block connected by power supply and data transmission channel.

EFFECT: increased durability, reliability.

6 cl, 2 dwg

Description

The proposed technical solutions relate to the oil industry, namely, systems and devices for receiving / transmitting information and electric energy to executive devices and mechanisms for operating wells for fluid production (multiphase medium - a mixture of oil, associated water and associated gas), maintenance and research of wells .

Currently, various methods are used to drive the devices installed inside the well, the operation of which requires a large amount of energy (equipment for cleaning wells, installing packers, etc.).

Systems are widespread in which the operation of energy-intensive devices is provided by connecting them directly to ground-based devices, which requires large material and technological costs for laying an expensive cable and a high probability of cable damage when the installation is lowered into the well.

Known intelligent hydrocarbon production control system (patent No. 2440488, “Method for simultaneous and separate operation of multilayer wells and a device for its implementation”, priority 24.08.2009, LLC GEONIK, Kazan), installed at the reservoir level and containing an analysis unit and logic, controlling the actuator (solenoid valve - a device for regulating production from the lower reservoir), based on the results of the analysis of measurements of technological parameters of wells by a measuring device (measuring transducer b is the sensor). The system also includes an autonomous power supply, which ensures the functioning of all its devices and mechanisms. Organization of temporary communication with ground-based equipment to obtain well parameters, data on the operation of the autonomous system and its individual devices, to recharge the power source, it is necessary to stop all the well equipment, stopping fluid production, lower the cable into the well and connect it to the system at the installation level, which costly, leads to downtime.

A well-known hydrocarbon production control system (patent No. 2487994, priority 07/19/2011, LLC Research Institute of Technical Systems "Pilot", Ufa), in which from a ground source of remote power via an independent signal circuit transmit power to the submersible unit ( BP) containing an amplifier, a power source and a borehole monitoring unit.The power supply of the BP provides the conversion of electrical energy to remote power to provide energy for the functioning of all downhole equipment, as well as suppresses electromagnetic interference induced in the signal circuit.In the same circuit, information is received / transmitted to the borehole control unit.The signal circuit is formed by a transit insulated conductor laid between the stator package and the submersible motor housing (PED), connected, on the other hand, through a node current lead with a signal core of a submersible cable, which in the ground part is connected to a remote power source and to a transceiver unit. The power supply of the PED is carried out in another circuit independent of the signal circuit. The signal circuit can be extended to connect other equipment located below the ESP, by transit of this circuit through the borehole part of the system for organizing measurements and controlling actuators located in other areas of the borehole space. The disadvantage of this technical solution is the need to lay an additional signal core in a submersible cable, which requires the use of non-standard expensive cables and specialized nodes of hermetic cable entry into the SEM; additional labor costs for wiring a separate additional core in the SES stator, which in sum requires significant material costs.

Various systems are known (patent for invention No. 2509888 “Method for monitoring downhole parameters (options) and a control system for the oil production process”, publ. 03/20/2014; patent for utility model No. 67636 “Telemetry information transmission system”, publ. 27.10. 07; patent for utility model No. 144124 “submersible block”, published on 08/10/14; Triol TM-01-06 immersion telemetry system, TRIOL Corporation, Kharkov, UA, http: // www. trioloil.ru/index.php?id=35 and others), in which the power and reception / transmission of information to the submersible module with measuring instruments is carried out Floats on SEM supply circuit from a ground unit. The disadvantage of the systems is the limitation of the limit of transmitted capacities along the power supply circuit and, as a consequence, the impossibility of ensuring the operation of energy-intensive devices and mechanisms installed in the well.

The closest analogue of the proposed power transmission system is a telemetry information transmission system (patent for invention No. 2230187, published on June 10, 2004) containing a ground unit (BN) and an underground transmitting device (PU). BN contains a power source, a control device for receiving, processing data from the control panel and transmitting commands to the control panel and the current monitor. The latter is implemented in this case on two resistors and an electronic key, but can be performed in any other way (for example, according to patent No. 67636, publ. 27.10.07). The underground device is the closest analogue of the inventive submersible module and contains a power and data transmission device connected to the input / output of the PU, bi-directionally connected to a data collection and transmission device (control device), to the inputs of which measuring devices are connected. The power supply from the BN power source to the power supply and data transmission device and measuring devices of the control unit is supplied via the power circuit of the submersible electric motor (PEM): input / output of the BN - electric cable - PED - input / output of the control unit. On the same circuit, receive / transmit data from the PU to the BN. The power supply and data transmission device according to this patent consists of resistors, a voltage stabilizer, an electronic key, but can be implemented in any other known manner (patent No. 67636).

The system provides the operation of a device for receiving and processing data and measuring devices that are part of the control unit itself, as well as connected to it, for monitoring downhole parameters. The system does not provide the ability to connect energy-intensive equipment to the control panel. The limit of transmitted powers on the power cable of the SEM is limited. This is due to the fact that it is necessary to have a relatively high output impedance of the power source to isolate the transmitted telemetry signal in the transmitter against the background of energy transfer through the power cable. In addition, the uneven energy consumption of the power load by energy-consuming devices interferes with the power supply of the SEM and makes it impossible to transmit data.

The objective of the technical solution is to create a power transmission system (electric energy) and a submersible module, which allow data to be transmitted and ensure the operation of at least one high-power submersible device connected to the module, which will significantly increase the manufacturability and reliability of connecting such actuators, significantly reduce the cost of systems in overall by reducing the length of the cable for power transmission.

To solve the problem, there is a submersible (MP) module in two versions, the input and output of which via the PED supply circuit receives data and a supply voltage sufficient to provide control and operation of the MP and the devices connected to it (at least one measuring and at least one executive). MP contains a demultiplexer, which serves to:

- power supply for said external actuating device with subsequent conversion of the released electrical energy into mechanical, thermal and / or electrical energy, which is transmitted to the said device. Moreover, the aforementioned conversion is regulated by the MP control device (for example, depending on the state of the well according to the data of measuring devices, or according to the commands received at the MP input),

- data transmission for the control device MP (SUMP) and power for the operation of the SUMP and the mentioned measuring device.

The first option is MP. The first input / output of the demultiplexer is the input / output of the MP, through which the power supply for the operation of the MP and at least one measuring device connected to it and bi-directional data transmission, as well as the supply of energy (power), are sufficient for operation though one external actuator (УП) connected to the MP (including high-power energy). The MP contains a power supply and data transmission device (DLC), the first input / output of which is connected to the first input / output of the control device of the submersible module (SUMP), which processes data coming from the said measuring device. At the same time, the MP contains a demultiplexer for separating the energy arriving at its first input / output for the said USP and transmitting this energy through the output of the demultiplexer to the said USP. The first input / output of the demultiplexer is the input / output of the MP, the second input / output of the demultiplexer is connected to the second input / output of the control unit, the input is connected to the output of the SUMP, which controls the operation of the mentioned USP through the second input / output. In this case, the external USP consists of PE and Fur. УП.

It is preferable that in the submersible module the input of the electric energy converter (PE) is connected to the output of the demultiplexer, and the input / output of the PE having at least one output for connecting the USP mechanism (Mech. USP) is connected to the second input / output of the SUMP. In this case, PE is part of the MP.

The second option is MP. Through the input / output of the MP through the power circuit of the submersible electric motor, energy is supplied for the operation of the entire MP and the measuring devices connected to it and bi-directional data transmission, as well as the supply of energy (power), sufficient for the operation of at least one external actuator connected to the MP (in including high power energy). MP consists of a submersible block (BP) and a remote block (BV). The PSU contains a control unit, an amplifier, a demultiplexer for separating the energy arriving at its first input / output (MP input / output) that is sufficient for the operation of the mentioned USP and the transmission of this energy through the output of the demultiplexer to the input of the power transmission channel and data of the submersible unit (CPBP). The first input / output of the control unit is connected to the first input / output of the SUMP processing the data coming from at least one measuring device. The second input / output of the demultiplexer is connected to the second input / output of the control unit, the output of the demultiplexer is connected to the input of the power transmission channel and the data of the submersible unit (CPBP), and the input is connected to the output of the SUMP, the second input / output of which is connected to the first input / output of the CPBP, the second the input / output of which is the second input / output of the PSU connected to the input / output of the BV.

The BV contains a channel for transmitting power and data to the remote unit (CPBV), the first input / output of which is the input / output of the BV, and the second input / output is connected to the input / output of the control unit of the remote unit (UBVV), which processes data from at least one additional measuring device. The energy for the functioning of the mentioned USP comes from the output of the CBPV, and the UUBV through its output controls the functioning of the mentioned USP.

It is preferable that in the submersible module, the input of the electric energy converter (PE) is connected to the output of the CPBV, and the second input of the PE having at least one output for connecting the mechanism of the mentioned USP (Mech. USP) is connected to the output of the UBVV. The output of PE is the output of BV and MP. In this case, PE is part of the MP.

This arrangement of the MP allows you to position the BV (and the mechanisms connected to it) arbitrarily in relation to the PSU and the engine with the minimum possible length of the additional cable between the PSU and BV.

Preferably, the PSU has at least one additional input / output for connecting the corresponding additional BV.

It is possible to connect to the demultiplexer (directly in the first embodiment, either through to the CPBP and the CPBV in the second version) at least one additional PE controlled by SUMP (according to the first option) or UUBV (according to the second option). In addition, there may be at least one additional output in the PE for connecting the corresponding additional actuator.

To solve the problem, there are two options for the power transmission system (System), in which, to ensure the functioning of energy-intensive actuating devices, the ground unit (BN) contains a multiplexer for providing joint transmission with separation in the frequency and / or time domain of data from the BN control device (UUBN), energy of low power of a power source (IP), as well as additional energy of high power from an additional power source (DIP) of high power along the PED power supply circuit: input / output BN - electric cable - PE - input / output module immersion (MP) comprising a demultiplexer for:

- allocation of the transferred energy, conversion of the released electrical energy into mechanical, thermal and / or electrical energy and its transmission to an actuator connected to the MP. Moreover, the said conversion is regulated by the MP control device,

- allocation and data transfer for the control device MP (SUMP) and power for the operation of SUMP and at least one measuring device.

Moreover, in the BN, the first input / output of the multiplexer is the input / output of the BN. The first output of the UUBN is connected to the first input of the multiplexer, and the second to the input of the IP. The IP output is connected to the input of the current monitor (MT), the output of which is connected to the UUBN input, and the MT input / output is connected to the second input / output of the multiplexer, the DIP output is connected to the second input of it. UUBN data exchange with external devices is possible.

In the first embodiment, the MP system is made according to the first described option, in the second - according to the second MP variant.

In the proposed technical solutions UUBN, UUMP, UUBV can be implemented programmatically on various programmable devices that satisfy the dimensions of BN and MP.

The multiplexer, demultiplexer, KPBP, KPBV can be implemented in hardware (electromechanical devices) or software and hardware to reduce hardware requirements and algorithmic simplification of the software UUBN, UUMP, UUBV.

UISm and DUizm can be either integrated into the MP (in the BP and BV in the second embodiment), or be independent devices connected through the MP inputs to the SUMP (SUMP and UUBV).

As PE, well-known devices are used that can be built into the USP.

Next, the operation of each of the options for the submersible module will be described as part of the corresponding power transmission system in the preferred embodiment.

FIG. 1 is a first embodiment of a power transmission system with a first embodiment of a submersible module in one of the preferred embodiments.

FIG. 2 is a second embodiment of a power transmission system with a second embodiment of a submersible module in one of the preferred embodiments.

Presented in FIG. 1 The power transmission system in the first embodiment (hereinafter referred to as System 1) comprises a ground unit 1 (BN), in which the first input / output of multiplexer 2 is the input / output of the BN. BN also contains a control unit for ground unit 3 (UUBN), the first output of which is connected to the first input of multiplexer 2, and the second to the input of power supply 4 (IP). The IP output is connected to the input of the current monitor 5 (MT), the output of which is connected to the input of the UUBN 3, and the input / output is connected to the second input / output of the multiplexer 2, the second input of which is connected to the output of the additional power supply 6 (DIP).

The first version of the submersible module 7 (MP) of System 1 contains a demultiplexer 8, the first input / output of which is the MP input / output connected through the PED supply circuit to the input / output of the BN to supply low-power energy from the BN IP, sufficient for the MP to operate, and bidirectional data transfer. The first input / output device power and data transfer (UPD) 9 is connected to the first input / output of the control device of the submersible module (UUMP) 10, the second input / output UPD 9 is connected to the second input / output of the demultiplexer. The inputs of the UUMP receive data from the measuring devices 11 (UISm). The output of the SUMP is connected 10 to the input of the demultiplexer 8, the output of which is connected to the input of the electric energy converter 12 (PE), the output of which is the output of the MP and serves to connect the actuator 13 (USP). To the second input / output of UUMP 10 is connected to the input / output of PE 12.

The power of the dipole is sufficient for the operation of the UPP connected to the MP (in other versions, several UPPs).

Perhaps the presence of input / output UUBN 3 (second input / output BN) for communication with external devices (Fig. 1 is not shown).

There may be additional outputs PE 12 for connecting additional actuators.

Structurally, IP and DIP can be performed as a single device. IP serves to ensure the functioning of the MP, UISm, DUizm, and DIP - for the operation of all connected to the MP UP.

In addition, the USP can consist of PE and the USP mechanism (Mech. USP). Then the output of the demultiplexer and the second input / output of the SUMP are in the MP output and input / output for connecting the USP, respectively.

KPBP and KPBV can be any (for example, single-wire or with separate lines for food and data transmission).

The logic of the system is carried out by control devices located in the BN and MP. They also monitor the system, including the coordination of control devices, and well parameters through UISm. Data (including commands) can be transmitted in both directions: BN-MP, MP-BV. UUBN, for example, transmits to the MP the settings of the MP, commands, requests, data for reprogramming the UMP, which simplifies the maintenance of the MP and the system as a whole, etc.

The power transmission system in the second embodiment starts working when the necessary supply voltage is applied to all BN devices that require power.

UUBN according to the algorithm specified in it, including taking into account telemetric data from the MP, transmits data for UMP. To do this, the device UUBN through the second output, respectively transmitted data modulate in the frequency band Δf (frequency band of the transmitted data) the voltage of the power source. It is possible to modulate data in the frequency band Δf, not including f _PI . Next, the obtained alternating voltage by the frequency band (f _IP UΔf) in transit is transmitted through MT to the second input / output of the multiplexer. In the absence of data (“zero data”), the voltage of the frequency f _PI (Δf = 0) is transmitted to the multiplexer.

Thus, for the transmission of electric energy of the SP ("e") and data ("d") for the MP, form the energy flow of IP with data in the frequency band (f _IP UΔf). In the case when there is no need to supply energy to the USP, the energy flow of the SP with data is transmitted in transit through the multiplexer to the input / output of the BN.

If it is necessary to start UIP (according to the data received from the MP in accordance with the results of UIMiz data processing, or to the commands from the input / output of UUBN, etc.) UUBN through the first output sends a command to the multiplexer to generate the total energy flow from the IP energy flow with data and the energy flow DIP ("E") frequency f _DIP supplied to the second input of the multiplexer. In this case, the DIP is chosen such that f _{DIP is} different from the frequency of the energy flow of the SP with data and is different from the frequency f of the _{SEM of} rotation of the SEM by Δf (outside the data transmission band).

That is, when implementing a multiplexer for joint transmission with frequency division of the frequency band Δf _IP f _DIP , Δf do not intersect:

In the case where the multiplexer is implemented for joint transmission with time division, the frequency f _DIP and Δf _PI can intersect.

Thus, in the Multiplexer, IP energy, data for transmission to the MP and DIP energy, separated in the time and (or) frequency domain, are combined. The multiplexer is implemented on the principle of a key (filter - in the case of frequency separation), regulated by UUBN. By switching the Multiplexer through its first input, either the total stream or only the IP energy stream with data is transmitted.

Further, the total energy flux from the IP and DIP, or only the IP energy flux with data, is transferred from the input / output of the BN to the input / output of the MP via the PED power cable.

When transmitting only the energy flow of the IP with data, the latter is transmitted through the demultiplexer through the DLC to the SUMP, which recognizes the transmitted data for execution by the modulated signal, and use the small power load (low-power energy from the IP) to power all MP devices that require power, in including UISm (carried out in any known manner).

The demultiplexer is implemented according to the method of transmitting the total stream in the multiplexer and also works on the principle of a key (filter - in the case of frequency separation), regulated by SUMP. If necessary, in accordance with the data received from the BN, the SUMP switches the demultiplexer through the output to isolate the DIP energy flow. The total flux in the demultiplexer is divided into an IP energy stream with data, which is transmitted to the control unit, and a high-power energy stream DIP (high power load) for USP. A large power load, depending on the implementation of the demultiplexer, may include additional PED energy. The allocated power load is transmitted to the PE input. At the same time (possibly at the same time), the SIA through the second input / output transmits commands for controlling the PE (turning on / off the USP). On the command to turn on the USP, the incoming load is converted into PE into mechanical and (or) electric energy in accordance with the type of the USP and transfers it to the MP output, and on the off command, the USP is stopped.

Based on the data received from the UIMism, the SUMP controls the USP, and also generates data for transmission to the BN. Further, in accordance with these data, in the DLC, the current consumption from the PM is modulated and transmitted through the demultiplexer along the PED power supply circuit from the MP to the BN. Then, through the multiplexer and the MT output, the data from the MP are recorded for change in the consumed current from the power source to the UUBN for further use.

Direct and reverse data transmission (from BN to MP and from MP to BN) can be performed with either frequency or time division.

When transmitting power and / or data with a time division synchronize UUBN, UUMP.

The second option is the Power Transmission System.

Presented in FIG. 2 The power transmission system in the second embodiment (hereinafter referred to as System 2) contains BN 1, in which the first input / output of multiplexer 2 is the input / output of the BN. The BN also contains UUBN 3, the first output of which is connected to the first input of multiplexer 2, and the second to the input of IP 4. The output of the IP is connected to the input of MT 5, the output of which is connected to the input of UUBN 3, and the input / output to the second input / output multiplexer 2, to the second input of which the output of DIP 6 is connected.

The second version of the submersible module 7 (MP) of System 2 consists of a submersible block 14 (BP) and a remote block 15 (BV).

BP 14 contains a demultiplexer 8, UPD 9, UUMP 10 and a channel for transmitting power and data to a submersible block 16 (CPBP).

The first input / output of the demultiplexer 8 is the first input / output of the PSU (MP input / output as a whole) connected through the PED power supply circuit to the input / output of the BN for supplying low-power energy for the MP functioning and bidirectional data transmission. The first input / output device power and data transfer (UPD) 9 is connected to the first input / output of the control device of the submersible module (UUMP) 10, the second input / output UPD 9 is connected to the second input / output of the demultiplexer. The inputs of the UUMP receive data from the measuring devices 11 (UISm). The output of the SUMP is connected 10 to the input of the demultiplexer 8, the output of which is connected to the input of the CPBP 16. The second input / output of the SUMP is connected to the first input / output of the CPBP 16, the second input / output of which is the second input / output of the PSU 14 connected to the input / output of the BV fifteen.

BV 15 contains a channel for transmitting power and data to remote block 17 (CBCB), the first input / output of which is the input / output of the BV, the second input / output is connected to the input / output of the control device of the remote unit 18 (UUBV). The inputs UUBV 18 receives data from additional measuring devices 19 (DUizm). The first input of PE 12 is connected to the output of the CBPB 17, the second input of PE 12 to the output of the UBBV 18. The output of PE 12 is the output of the BV (and the MP as a whole) and serves to connect the UP 13.

The USP can consist of PE and the USP mechanism (Mech. USP). Then the output of the CWPV output of the UWBW in the MP are the first and second outputs for connecting the USP, respectively.

The logic of the system is carried out by control devices located in the BN, BP and BV. They also monitor the system, including the coordination of control devices and well parameters through UISm, DUizm. Data (including commands) can be transmitted in both directions: BN-BP, BP-BV, BN-BV (via BP). UUBN, for example, transmits to the MP the settings of the MP operation, commands, requests, data for reprogramming the UMP, UUBV to simplify the maintenance of the MP and the system as a whole, etc.

The conditions for starting work are the same as for option 1.

In UUBN, according to the algorithm specified in it, including taking into account telemetric data from the magnetic field, an IP energy flow is generated with data for the UUMP and / or UUBV, as described above.

If it is necessary to start UI (according to the data received from the MP in accordance with the results of data processing UISm and DUizm, or to commands from the input / output of UUBN, etc.), the total flow is formed from the energy flow of the IP with data and the energy flow of the DIP, as described above .

Further, the total energy flux from the IP and DIP, or only the IP energy flux with data, is transferred from the input / output of the BN to the input / output of the MP via the PED power cable.

When transmitting only the energy flow, the IPs with the data recognize, as described above, the transmitted data for execution, and the energy from the IPs is used to power all MP devices that require power, including UISm, DUizm.

If necessary, in accordance with the data received from the BN, the SUMP switches it through the input of the demultiplexer to isolate the DIP energy flow. The total flux in the demultiplexer is divided into a low-power energy flow of an IP with data that is transmitted to the control unit, and a high-power energy flow of a DIP (high power load) for a USP. The allocated large power load is transferred to the CPBP. In this case, the SUMP transmits commands for controlling the PE through the second input / output (turning on / off the USP). Through the communication channel (KPBP-KPBV), the commands and the load are transferred to UUBV and PE, respectively. At the turn-on command, the PE converts the incoming load into mechanical and (or) electrical energy in accordance with the type of USP and transmits it to the MP output, and at the turn-off command, the USP is stopped.

The data from the DUISm is transferred to the UUVV, where they are converted for transmission to the UUMP through the UCBP and the UCBP - through the communication channel between the base unit and the base unit. At UMP also received data from the UIMism. Based on the received data, the SUMM controls the SEML, and also generates data for transmission. Further, in accordance with these data, in the DLC, the current consumption from the PM is modulated and transmitted through the demultiplexer along the PED power supply circuit from the MP to the BN. Further, through the multiplexer and the input / output of the MT in UUBN on the change in the current consumption from the power source, data from the MP is recorded for further use.

Direct and reverse data transmission can be performed either with frequency or time division.

When transmitting power and / or data with a time division, they synchronize UUBN, UUMP, UUBV.

Despite the fact that technical solutions are shown and described with reference to their specific implementation options, specialists in the art should understand that various changes in form and content can be made without departing from the essence and scope of the invention defined by the attached claims.

For example, UUMP (according to the first option) or UUBV (according to the second option) can receive data from the UP connected to the MP. Moreover, the connection between the MP and the USP can be any (for example, single-wire or with separate lines for power and data transfer).

Thus, a feature of the Telemetry Systems proposed as inventions is that an additional high-power power source is used, the energy from which is transmitted to the executive device through the “multiplexer – demultiplexer” system, which separates (in the frequency or time domain) IP energy flows with data and energy flow DIP powerful load for actuators, which provides the claimed technical result.

In addition, in both versions of the System, the inability to start URP (including the failure of DIP, PE, or URP) does not lead to a failure of the entire system; the functioning of all control devices of the System, including data reception / transmission, is preserved.

Claims (6)

1. The submersible module (MP), through the input / output of which, through the power circuit of the submersible electric motor (PED), supply energy and bi-directional data transmission, comprising a power and data transmission device (DLC), the first input / output of which is connected to the first input / output the control device of the submersible module (UUMP), which processes data coming from at least one measuring device, characterized in that it contains a demultiplexer for separating the energy supplied to its first input / output, sufficient for functional at least one external actuating device (USP), and transmitting this energy through the output of the demultiplexer to the said USP, the first input / output of the demultiplexer being the input / output of the MP, the second input / output of the demultiplexer connected to the second input / output of the control unit, the input is connected to the output of the SUMP, which controls the operation of the said SPS. 2. The submersible module according to claim 1, characterized in that the input of the electric energy converter (PE) is connected to the output of the demultiplexer, and the input / output of the PE having at least one output for connecting the USP mechanism is connected to the second input / output of the SUMP. 3. The submersible module (MP), through the input / output of which is fed through the PED power supply circuit and bi-directional data transmission, containing the control unit, the first input / output of which is connected to the first input / output of the SUMP processing the data coming from at least one measuring device, characterized in that it contains a submersible unit (BP) and a remote unit (BV),
moreover, the PSU contains a control unit, a control amplifier, and also a demultiplexer for separating the energy arriving at its first input / output, sufficient for the operation of at least one external USP, and transferring this energy through the output of the demultiplexer to the input of the power transmission channel and data of the submersible unit (CPBP), moreover, the first input / output of the demultiplexer is the first input / output of the PSU and the input / output of the MP, the second input / output of the demultiplexer is connected to the second input / output of the control unit, and the input to the output of the SUMP, the second input / output of which is connected to the first input / you KPBP ode, the second input / output of which is the second input / output power supply connected to the input / output BV
moreover, the BV contains a channel for transmitting power and data to the remote unit (BAC), the first input / output of which is the input / output of the BV, and the second input / output is connected to the input / output of the control unit of the remote unit (UBVV),
processing data coming from at least one additional measuring device, moreover, the energy for the functioning of the mentioned USP comes from the output of the SECS, and the UUBV controls the functioning of the said USP. 4. The submersible module according to claim 3, characterized in that the first input of the PE is connected to the output of the CBPB, and the second input of the PE having at least one output for connecting the USP mechanism is connected to the output of the UBBV. 5. A power transmission system comprising a ground unit (BN) connected to a submersible module (MP) via a PED power supply circuit for transmitting energy and bidirectional data transmission, wherein the BN contains a power source (IP), a control unit for the ground unit (UUBN) and a monitor current (MT), and the MP contains a control unit, the first input / output of which is connected to the first input / output of the SUMP processing data coming from at least one measuring device, characterized in that the BN contains an additional power source (DIP) and a multiplexer, the first the multiplexer input / output is BN input / output, the MT input / output is connected to the second multiplexer input / output, the first UUBN output is connected to the first multiplexer input, the DIP output is connected to the second input, the UUBN second output is connected to the IP input, the IP output is connected to MT input, and MT output - to the UUBN input, and the MP is performed according to claim 1. 6. A power transmission system comprising a ground unit (BN) connected to a submersible module (MP) via a PED power supply circuit for transmitting low-power energy and bi-directional data transmission, wherein the BN contains a power source (IP), a control unit for the ground unit (UUBN) and a current monitor (MT), and the MP contains an EDC, the first input / output of which is connected to the first input / output of the SUMP processing data coming from at least one measuring device, characterized in that the BN contains an additional power source (DIP) and a multiplexer moreover, the first input / output of the multiplexer is BN input / output, the MT input / output is connected to the second input / output of the multiplexer, the first UUBN output is connected to the first input of the multiplexer, the DIP output is connected to the second input, the second UUBN output is connected to the IP input, output IP - to the input of the MT, and the output of the MT - to the input of the UUBN, and the MP is performed according to p. 3.

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