RU2510033C2 - Device for continuous monitoring of cable insulation resistance - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is designed for use as a technical facility for continuous monitoring of insulation resistance and electric strength of the circuit "submersible electric motor (PED) - three-strand power cable" with working voltage of 1-2.5 kV, used in devices of an electric centrifugal pump (ECPD), The device comprises a source of DC voltage 3, a current leakage meter 7, units of light 1 and sound alarm 4, a step-up transformer 11, a comparator of DC voltage source charge 5, a microcontroller 2, a source of reference voltage 6, a generator reset comparator 8, a generator of reference frequency 9 and a power amplifier 10, a capacitor 14, a resistive divider 13, a rectifying diode 12, a reference resistor 17, one of outlets of which is connected to a test terminal 16; a measurement shunt 15 with the possibility of connection with the bus 19 of the body and a braiding of a controlled cable, a clamp 18 for connection to strands of the controlled cable. Elements of the design are connected in a certain manner according to the figure 1.

EFFECT: development of a device having high reliability and efficiency, providing continuous monitoring of insulation resistance and electric strength of a PED circuit - a three-strand power cable.

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Description

The invention relates to the field of electrical engineering, in particular to instrumentation, and is intended for use as a technical means of continuous monitoring of insulation resistance and electric strength of the circuit "submersible electric motor (PED) - three-core power cable" with an operating voltage of 1-2.5 kV used in devices of an electric centrifugal pump (ESP).

A device for monitoring the quality of electrical insulation [1], containing a pulse generator that generates electrical pulses with a predetermined high energy, a transformer, a switch of operating modes. A pulse generator is used to create pulses of coil insulation control. The device also contains bridge circuits, capacitors, a microammeter and a microvoltmeter. However, this device due to the use of high energy generators is unsafe for use in the oil industry.

A device is also known for measuring the electrical insulation resistance in electric harnesses and cables of networks under constant current voltage [2], the operation of which is that before starting to affect the measured circuit of a capacitor of known nominal value, the busbar potential is digitized and stored. At the end of the transient assessment, a charged recovery capacitor is connected to the chassis bus, which restores the chassis bus potential to a stored value. The technical result - the minimum time between measurement cycles - is achieved through the use of a recovery capacitor, a digital-to-analog converter and a comparator as a comparison element that changes during the restoration of the housing potential and the stored initial housing potential.

However, this device has the disadvantage that in the technical solution for measuring the insulation resistance there are measurement cycles for evaluating the transient process and the reaction time of the device to turn on the alarm when the insulation resistance is reduced will be significant compared with the claimed invention.

The closest in technical essence to the claimed invention is a device for monitoring the quality of electrical insulation [3], including a constant voltage source connected to a current leakage meter, sound and / or light signaling units, a transformer.

The disadvantage of this technical solution is that the cable is not continuously checked for electrical insulation strength with an operating voltage of 1-2.5 kV when the equipment is lowered into the well, and the response threshold is checked in laboratory conditions, and not immediately before starting work, as with the use of the claimed invention.

The objective of the invention is to determine the reduction of the controlled parameter below the maximum permissible value and prompt informing technical personnel about this during the underground repair of the well, as well as the exclusion of settings and adjustments before starting work and, as a result, ease of operation. Before starting work, the performance of the product can be checked by connecting a clamp to fix the three-wire cable to the test terminal. Along with the presence of an autonomous power supply built into the device, it is possible to install the product directly on the edge of a metal drum onto which a three-core cable is wound, while monitoring the cable insulation resistance continuously and, as a result, reducing the labor and time costs of technical personnel for measuring manual parameter.

The problem is solved due to the fact that the device for continuous monitoring of the insulation resistance of the cable, including a constant voltage source, current leakage meter, light and sound alarm units, step-up transformer, according to the invention, contains a discharge voltage comparator of the constant voltage source and a microcontroller, the output of which is connected with inputs of light and sound alarm units; a series-connected reference voltage source, a generator reset comparator, a reference frequency generator and a power amplifier; a capacitor and a resistive divider connected in parallel, the output of which is connected to the second input of the generator reset comparator; a rectifier diode, the anode of which is connected to one of the outputs of the secondary winding of the transformer, and the cathode is connected to one of the terminals of the resistive divider and capacitor and is configured to connect to three cores of the controlled cable; a reference resistor, one of the terminals of which is connected to a test terminal; a measuring shunt, one terminal of which is connected to the other terminals of the resistive divider and capacitor and is connected to the other output of the secondary winding of the transformer and the first input of the current leakage meter, and its other terminal is connected to the other terminal of the reference resistor and is configured to connect to the housing bus and the braid of the controlled cable; the output of the leakage current meter is connected to the second input of the microcontroller, and its second input is connected to the second output of the reference voltage source, the third output of which is connected to the first input of the discharge comparator of the reference voltage source, the second input of which is connected to the output of the constant voltage source.

The inventive device is illustrated in a block diagram and includes the following elements:

1 - light signaling unit;

2 - microcontroller;

3 - source of constant voltage;

4 - block sound alarm;

5 - discharge comparator of a constant voltage source;

6 - source of reference voltage;

7- current leakage meter;

8 - generator reset comparator;

9 - reference frequency generator;

10 - power amplifier;

11- step-up transformer;

12 - rectifying diode;

13 - resistive divider;

14 - capacitor;

15 - measuring shunt;

16 - test terminal;

17 - reference resistor;

18 - clamp;

19 - housing tire.

In the device for continuous monitoring of the cable insulation resistance (not shown in the figure), the discharge comparator of the constant voltage source 5 and the microcontroller 2 are connected in series, while the output of the microcontroller is connected to the inputs of the light 1 and sound 4 signaling units. The reference voltage source 6, the reset comparator of the generator 8, the reference frequency generator 9 and the power amplifier 10 are also connected in series. In addition, the device contains a parallel-connected capacitor 14 and a resistive divider 13, the output of which is connected to the second input of the reset comparator of the generator 8, as well as a high-voltage rectifier diode 12, the anode of which is connected to one of the outputs of the secondary winding of the transformer 11, and the cathode is connected to one of the findings of the resistive divider 13 and the capacitor 14 and is configured to connect to the three cores of the controlled cable through the clamp 18. The device is connected to the bus 19 of the housing by one of the outputs and to the braid cable through a measuring shunt 15, the other output of which is connected to other terminals of the resistive divider 13 and capacitor 14 and connected to another output of the secondary winding of the transformer 11 and the first input of the current leakage meter 7. The output of the current leakage meter 7 is connected to the second input of the microcontroller 2, and its second input is connected to the second output of the reference voltage source 6, the third output of which is connected to the first input of the discharge comparator of the reference voltage source 5, the second input of which is connected to the output of the source DC voltage 3.

The device is a self-contained electronic measuring unit and is placed in a sealed metal container fixed on the edge of the working drum with a cable lowered into the well together with the SEM. It has specially designed switching elements to ensure fast and reliable connection to a controlled electrical circuit.

The device is powered from an internal source of constant voltage (battery) 3 voltage of 12 V, located in a special insulated compartment of the container.

The battery is charged, as necessary, from an alternating current electric network of voltage 220 V 50 Hz by means of a standard charging unit such as a network adapter, which is supplied with the device.

The device for continuous monitoring of insulation resistance of the electric circuit "submersible electric motor (SEM) - three-core power cable" works as follows.

For operational monitoring of the device’s operability, before starting work, the clamp 18 is connected to the test terminal 16, simulating a situation in which the insulation resistance falls below the permissible limit (100 MΩ) due to the reference resistor 17, while the device is considered operable if the light 1 and sound 4 alarm units are activated .

The device is connected by its output terminal 18 “clamp” to the 3 cores of the power cable, and the device casing, structurally interfaced with the terminal 19 “housing bus”, is mounted on the edge of the working drum with the power cable with a special clamp that makes reliable electrical contact. The high-frequency voltage supplied from the reference frequency generator 9 to the input of the power amplifier 10, to which the step-up transformer 11 is connected, is converted at the output of the step-up transformer 11 into high voltage polarity pulses. Then, they are detected by a rectifier diode 12 and smoothed by a capacitor 14 to the voltage level necessary to measure the insulation resistance between the clamp terminals 18 and the housing bus 19. The feedback voltage from the common point of the resistive divider 13 is fed to the input of the generator reset comparator block 8, where is compared with the reference voltage of the block 6 of the reference voltage source. Upon reaching the specified value of the measuring voltage at terminal 18, the “clamp” from the output of block 8 of the reset comparator receives a signal inhibiting generation to block 9 of the reference frequency generator, performing a start / stop mode of the latter, thereby reducing the current consumption of the device as a whole for continuous operation maintaining a given value of the measuring voltage.

With a decrease in the insulation resistance in the controlled circuit, the voltage drop across the measuring shunt 15 increases, which enters the unit 7 of the current leakage meter, where it is compared with the reference voltage coming from the unit 6 of the reference voltage source. When the insulation resistance in the measured circuit is lower than the allowable limit, the output of block 7 of the current leakage meter receives a signal to block 2 of the microcontroller, which includes block 1 of light and sound 4 alarm.

When the voltage level coming from the constant voltage source 3 is lower than the level necessary for the normal operation of all units of the device, after comparing with the reference voltage coming from the voltage source block 6, the discharge comparator of the constant voltage source 5 is triggered and transfers to the microcontroller block 2 signal prohibiting the operation of the device. From the output of block 2 of the microcontroller, the set of control signals in a given sequence includes light 1 and sound 4 alarm blocks, which indicates the need for charging a constant voltage source 3.

Thus, due to the use of a rechargeable DC voltage source in the device, continuous monitoring of the insulation resistance is ensured, and due to the presence in the device of other elements that are essential features of the claimed device and are included in the distinctive part of the claims, the reduction of the controlled parameter - resistance is quickly determined insulation of a three-core cable is below the maximum permissible value.

Information sources

1. DE 1927302, IPC Н02К 15/00, publ. 02/12/1970

2. RU 2289142 C1, IPC G01R 27/16, publ. December 10, 2006

3. RU 11414 U1, IPC Н02К 15/00, H01B 11/00, published on September 16, 1999. g.

Claims (1)

A device for continuous monitoring of cable insulation resistance, including a constant voltage source, current leakage meter, light and sound alarm blocks, a step-up transformer, characterized in that it contains a DC discharge source comparator and a microcontroller, the output of which is connected to the inputs of the light and sound blocks signaling; a series-connected reference voltage source, a generator reset comparator, a reference frequency generator and a power amplifier; a capacitor and a resistive divider connected in parallel, the output of which is connected to the second input of the generator reset comparator; a rectifier diode, the anode of which is connected to one of the outputs of the secondary winding of the transformer, and the cathode is connected to one of the terminals of the resistive divider and capacitor and is configured to connect to three cores of the controlled cable; a reference resistor, one of the terminals of which is connected to a test terminal; a measuring shunt, one terminal of which is connected to the other terminals of the resistive divider and capacitor and is connected to the other output of the secondary winding of the transformer and the first input of the current leakage meter, and its other terminal is connected to the other terminal of the reference resistor and is configured to connect to the housing bus and the braid of the controlled cable; the output of the leakage current meter is connected to the second input of the microcontroller, and its second input is connected to the second output of the reference voltage source, the third output of which is connected to the first input of the discharge comparator of the reference voltage source, the second input of which is connected to the output of the constant voltage source.