RU2743910C1 - Method for increasing the telemetry system operating resource - Google Patents

Abstract

FIELD: oil industry.SUBSTANCE: invention relates to oil-producing industry, namely to survey or inspection of wells. Method includes delivering the supply voltage from the ground unit to the submersible unit, where, after setting the supply voltage on the switching communication elements of the measuring units, a control signal is transmitted to the switching communication elements of the measuring units and the electronic key by means of the information receiving and processing device. After that, each measuring unit is switched on with an electronic key at a predetermined time interval and an electronic interrogation of each measuring unit is carried out.EFFECT: increased working life of the submersible telemetry system, reduced effect of the supply voltage in the submersible assembly measuring units and the telemetry system simplification.3 cl, 1 dwg

Description

The claimed invention relates to the field of the oil industry, to the study or inspection of wells, is intended to increase the service life of the telemetry system, providing the reception and transmission of information data and electrical energy to the actuators and mechanisms during the operation of wells for the production of fluid.

One of the most important tasks at the current level of development of telemetry equipment in the oil industry is to improve the reliability and service life of the telemetry system, in this regard, various devices and methods are widely used to solve this problem.

A similar solution is known from the prior art, RF patent 180608U1, which describes an immersion unit that contains at least a main backup module, a main module that includes an information receiving and processing device that controls an electronic key and is designed to collect information data from measuring units. The measuring units can be used, in particular, sensors for temperature, pressure, vibration, etc.

When the supply voltage is applied to the submersible unit, all its modules are switched on and the necessary supply voltages are formed for the operation of the device for receiving and processing information. When the main module is in working mode, the device for receiving and processing information carries out an electronic interrogation of the measuring nodes and converts the current readings, which are transmitted to the ground unit using an electronic key.

If the main module fails, a signal is received from the ground unit in order for the main backup module to start functioning as the main module, which also reads data from the switched on measuring nodes.

The disadvantage of the known utility model is that for the transmission of reliable data and increasing the reliability of the submersible unit in conditions of extreme temperatures, additional main redundant modules are used, which complicates the telemetry system and reduces the technical and economic indicators of the system. The continuous functioning of the measuring units of the submersible unit, which read information data during the operation of the main and backup modules of the submersible unit, is not taken into account, which leads to additional consumption of electric power.

A similar disadvantage is also characterized by the method of switching sensor units of the telemetric data transmission system [RF Patent No. RU2694984C1, IPC E21B 47/12, 2018], in which at least one redundant submersible unit is additionally connected, which ensures the reliability of the submersible unit and continuous data transmission from measuring nodes due to the possibility of redundancy and duplication of functions. The proposed technical solution for the switching method complicates the telemetry system technically, and additional costs arise for the transmission and distribution of electrical power in the telemetry system.

The closest analogue is the patent for the invention of the telemetric information transmission system [RF patent No. RU2230187C2, MPKE21V 47/00, 2004], where the supply voltage from the ground unit, including the power supply, the device for receiving and processing information is supplied to the submersible unit. The immersion unit contains a device for receiving and processing information, which controls the electronic key and the switching elements of communication of the measuring units and collects the electronic signals of the measuring units. The device for receiving and processing information of the submersible unit generates a pulse signal, which is transmitted to the device for receiving and processing information of the ground unit.

The disadvantage of the above invention is the lack of technical solutions aimed at the reliability of the telemetry system. The constant presence of the measuring nodes under the supply voltage in the telemetry system is not taken into account, while additional consumption of electrical energy occurs, which leads to a decrease in the service life of the measuring nodes and the submersible unit, respectively, and the telemetry system as a whole.

The technical objective of the invention is to increase the service life of the telemetry system while ensuring the receipt of telemetry data, without using additional backup and redundant functions of the system elements.

The technical result from the implementation of the invention consists in increasing the working life of the submersible telemetry system and is achieved by the fact that the method reduces the effect of the supply voltage in the measuring units of the submersible unit and provides data transmission and obtaining the results of telemetry data, without complicating the telemetry system with additional, backup and redundant functions of the system elements , which also reduces the size of the device.

The solution to the problem is determined by a combination of the following essential features.

According to the method for increasing the service life of the telemetry system, the supply voltage is supplied from the ground unit to the submersible unit, where, after establishing the supply voltage on the switching communication elements of the measuring units, a control signal is supplied to the switching communication elements of the measuring units and the electronic key by means of the information receiving and processing device.

After that, with an electronic key, each measuring unit is switched on in turn with a predetermined time interval and an electronic interrogation of each measuring unit is carried out.

After interrogation, the supply voltage is removed from each measuring unit by an electronic key at a predetermined time interval.

The measuring units are switched on after each cycle of measuring the insulation resistance in the circuit for a specified time interval.

The specified time interval is calculated based on the time required for one measuring unit to turn on, perform an electronic poll and remove the supply voltage. By means of the device for receiving and processing information of the submersible unit, electronic signals of the measuring units are collected, a pulse signal is generated and transmitted to the device for receiving and processing information of the ground unit.

The essence of the proposed technical solution is explained, but not limited to, graphic material:

fig. - block diagram of the telemetry system operation.

The method of increasing the service life of the telemetry system is implemented in the telemetry information transmission system.

The telemetry information transmission system includes ground 1 and submersible units 3 interacting through a power cable 2.

Power cable 2 is designed to power electric motors with various installations, for example, the installation of an electric centrifugal pump. The parameters of the electric motors are monitored in the telemetry system by transferring data from the measuring units (IU) 7 of the submersible unit (PB) 3 to the ground unit (NB) 1. Power cable 2 is a data transmission line and electrical energy from the ground unit (NB) 1.

The ground unit (NB) 1 contains a power source and a device for receiving and processing information (UPOI) 4, where the obtained data results from the submersible unit (PB) 3 are recorded.

PB 3 allows you to control the parameters of a submersible electric motor (SEM), such as oil temperature in the SEM, vibration level, pressure, etc., as well as parameters of the fluid at the pump inlet and outlet, for example, pressure, temperature, etc.

The submersible unit (PB) 3 contains a main module, a high-temperature electronics unit, including a device for receiving and processing information (UPOI) 4, switching elements of communication of measuring nodes (CE) 5, an electronic key (EC) 6, measuring nodes (IU) 7 and can include a filtering and protection device, a voltage stabilizer.

When the supply voltage is applied, PB 3 is activated. In the submersible unit 3, in the electronics unit UPOI 4, an electronic interrogation of the measuring units is performed and a pulse signal is generated, which is transmitted to the device for receiving and processing information of the ground unit.

The device for receiving and processing information (UPOI) 4 with a power cable 2 is directly connected to the power supply NB 1 and is constantly under supply voltage. UPOI 4 controls the switching elements of communication of measuring nodes (KESIU) 5 and an electronic key (EC) 6. As UPOI 4 can be used, in particular, a universal microcontroller.

Switching communication elements of measuring units (KESIU) 5 are semiconductor devices that, after establishing the supply voltage, receive a control signal to turn on the measuring units with UPOI 4. In one of the possible implementation options, field-effect transistors can be used as KESIU.

The electronic key (EK) 6 is designed to alternately turn on each measuring unit (IU) 7 at a predetermined time interval. UPOI 4 controls the EK 6 by supplying an activation control signal. After an electronic interrogation, the EC 6 alternately turns off the IU 7 with a predetermined time, due to this, the IU 7 is in the on state for a minimum amount of time, which increases their service life, which as a result increases the reliability of the PB 3 and the resource of the system as a whole.

The number of EC 6 can vary from one to N and depends on the number of measuring nodes (IU) 7, where N ≤ IU.

As EC 6 can be used, in particular, transistor switches.

The specified time interval is the time necessary to turn on, perform an electronic poll and turn off the IU 7, while during the data transfer from the UPOI 4 of the submersible block 3 to the NB 1, the measuring units 7 are in the off state.

The measuring units can be used, in particular, sensors for temperature, pressure, vibration, etc.

Thus, an increase in the service life of the PB 3, a decrease in power consumption and an increase in the service life of the telemetry system is ensured.

The method is implemented as follows.

In the first cycle, the ground unit (NB) 1 transmits a negative supply voltage through the power cable 2 to the SEM communication line, measures and calculates the insulation resistance data.

In the next cycle, after supplying a positive supply voltage from the ground unit 1 to the submersible unit 3, the supply voltage is supplied to the device for receiving and processing information (UPOI) 4 PB 3, while the measuring nodes 7 are in the off state.

After supplying the supply voltage to the switching elements of the communication of the measuring nodes 5, from the UPOI 4, the control signal for switching on is sent to the KESIU 5 and EK 6.

The electronic key (EC) 6 turns on each measuring unit 7 in turn with a predetermined time interval and carries out an electronic interrogation of each measuring unit.

EC 6 alternately with a predetermined time interval remove the supply voltage from each measuring unit 7.

The measuring units 7 are switched on after each cycle of measuring the insulation resistance in the circuit for a predetermined time interval.

In this case, the specified time interval is determined based on the time required for one measuring unit 7 to turn on, perform an electronic poll and remove the supply voltage from the IU 7.

After the electronic interrogation and removal of the supply voltage from the IU 7, electronic signals of the measuring units (IU) 7 are collected by means of the UPOI 4. Then, with the help of the UPOI 4, a pulse signal is generated and transmitted to the device for receiving and processing information of the ground unit 1.

As a result, the measuring units (IU) 7 are under the reduced influence of the supply voltage, performing the given data transfer functions in full, for a given time in the PB 3, which increases their service life, which as a result increases the reliability of the PB 3. Also, the described scheme allows to reduce the element base, which leads to a decrease in the dimensions of the device and expands the possibilities of its operation in small-diameter wells.

The claimed invention increases the service life of the telemetry system, while ensuring the transmission and reception of data without using additional backup and redundant functions of the system elements, increasing the technical and economic indicators of the system by saving electrical energy, time, and the absence of the need for the introduced system elements.

Claims (3)

1. The method of increasing the service life of the telemetry system, according to which the supply voltage from the ground unit, including the power source, the device for receiving and processing information, is supplied to the submersible unit, where by means of the device for receiving and processing information, the electronic key and the switching communication elements of the measuring nodes are controlled, collected electronic signals of the measuring units and generate a pulse signal, which is transmitted to the device for receiving and processing information of the ground unit, characterized in that power is supplied to the device for receiving and processing information of the submersible unit, while the measuring units are in the off state, supply voltage is supplied to the switching elements connection of the measuring nodes, after which the control signal of switching on is supplied to the switching elements of the communication of the measuring nodes and the electronic key, after the control signal of switching on, each change is switched on alternately with a predetermined time interval measurement unit and conduct an electronic poll of each measuring unit and alternately with a given time interval remove the supply voltage from each measuring unit. 2. The method of increasing the service life of the telemetry system according to claim 1, characterized in that the measuring units are switched on after each cycle of measuring the insulation resistance in the circuit for a predetermined time interval. 3. The method of increasing the service life of the telemetry system according to claim 1, characterized in that the predetermined time interval is determined based on the time required for one measuring unit to turn on, perform electronic polling and remove the supply voltage from the measuring unit.

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