RU2690515C1 - Cable condition monitoring device - Google Patents

Abstract

FIELD: measuring equipment.SUBSTANCE: invention relates to measurement equipment and can be used for prediction of short-circuit time of power cable by determination of its insulation resistance. Summary: cable state monitoring device (CSMD) comprises control device (CD) for collection, processing and transmission of information, input / output of which is information input / output CSMD. To first output CD first input of measuring voltage supply device (MVSD), which output is connected to multifunctional input / output CSMD, to which input of primary information removal device (PIRD), and quantiser, which output is connected to input CD. At that, CSMD additionally comprises a resistance range switching device (RRSD), the first input of which is connected to the output PIRD, second input is to the third output CD, and the output is to the IID input, and a measurement voltage control device (MVCD), the input of which is connected to the third output CD, and output is to second input MVSD. CSMD can contain calibration device (ClD) connected between fourth output CD and multifunctional input / output CSMD to enable adjustment of measurement channels in manual mode at installation site.EFFECT: possibility of determining cable resistance with given accuracy and evaluation of its state throughout operation.1 cl, 1 dwg

Description

The proposed solution relates to the measurement technique, can be used to prevent a short circuit of a power cable by determining its insulation resistance (for example, the power cable of a submersible electric motor during operation, maintenance and research of wells for the production of fluid).

A known method of detecting a single-phase earth fault (RF patent for invention No. 2438139, publ. 12/27/2011, Prozorovsky EE), based on the excitation of a pulsed high-frequency signal in a power cable through the grounding conductor of its conductive shell. A single-phase earth fault is judged by the jump in the amplitude of this signal.

There is also known a method of monitoring equipment of wired telecommunication networks and a device for its implementation (RF patent for invention No. 2331080, publ. 10.08.2008, ZAO Scientific and Technological Center Computer Technologies), containing a unit for normalizing input signals and multiplexing, a supply voltage switching unit associated with power supply and microprocessor. At the same time, the state of several lines is monitored, cyclically controlling in time a short circuit or open circuit by determining the current of the line to the sensor. The input signal normalization and multiplexing unit is configured to determine the current in each line and protect the device inputs from high voltage. The power supply switching unit is made in the form of two optocaps with the possibility of simultaneous switching of these optocouplers. Each line is equipped with two resistances installed at its end, one of which is shunted by the sensor contacts. Despite the possibility of continuous monitoring of the status of each of the lines, the device and method do not allow to monitor pre-emergency situations.

Currently known devices that allow continuous monitoring of the state of the power cable submersible electric motor, giving indications about the pre-emergency condition of the cable, before the occurrence of short circuit. Such monitoring is carried out in the ground-based modules that are part of the control stations for submersible electric pumps produced by ELEKTON JSC (Moscow), BORETS CJSC (Moscow), IRZ JSC (Izhevsk).

For example, the ground-based (MN) TMS-E5 module (manufactured by JSC IRZ, RE ETsVIYa.468156.117, 2012), which is the closest analogue of the proposed cable condition monitoring device, contains a control device connected to its first output connected to the multifunctional input / output MN, to which the input of the primary information removal unit is connected, and a quantizer (isolation measurement unit - for digitizing the residual voltage), the output of which is connected to the input of the control device, information input / output of which is an information input / output MN. MN allows, unlike the above-described technical solutions, to diagnose not a short circuit of a cable, but its insulation resistance, measuring a drop in the level of direct voltage on the cable under test. In this case, it is possible to detect only significant damage to the cable insulation. However, during the initial damage to the insulation of the cable cores, no leakage of current can be detected, since with a high insulation resistance of the cable (for power cables of submersible electric motors, this range is higher than 10 MΩ), the voltage drop is extremely small.

The task of the technical solution is to create a cable condition monitoring device that allows for long-term prediction of a motor power cable failure, monitoring cable condition indications throughout its operation, allowing the consumer to monitor the leakage of current to the casing of the well casing with minor damage to the cable core insulation. Detection of small values against the background of high-voltage broadband interference on the communication line is a nontrivial task.

Detection of current leakage at the initial stages of insulation damage will improve the procedure for predicting cable degradation due to the possibility of building long-term trends of resistance drop, starting from the beginning of its commissioning. For example, during the descent into the well one of the reasons for the cable line failure is the leakage of the well fluid to the conductor through the microcracks of the insulating layer of the cable. The process of cable resistance drop in case of such leakage proceeds along a descending exponential and, as a result, at the initial stages the resistance drop in time is extremely small.

To solve the problem, a cable condition monitoring device (UMSK) is used, made with the possibility of supplying the required supply voltage to all elements requiring power. UMSK contains a control unit (CU) for collecting, processing and transmitting information, the input / output of which is an information input / output of the UMSK. The input (first) of the measuring voltage supply (UPIN), the output of which is connected to the multifunctional input / output of the UMSC, to which the input of the primary information removal device (USPI) is connected, and a quantizer, the output of which is connected to the input of the SU, are connected to the first output of the CU. In this case, the UMSC additionally contains a device for switching the resistance range (UDS), the first input of which is connected to the output of the USPI, the output to the input of the quantizer, and the second input to the second output of the UU, as well as the measuring voltage adjustment device (URIN), whose input is connected to the third output of the control unit, and the output to the second (additional) input of the UPIN.

Preferably, a calibration device (CC) with a set of calibration insulation resistances, the output of which is connected to the multifunctional input / output of the UMSK, is connected to the fourth output of the CU in order to be able to set up the measuring paths (CU) in the manual mode at the installation site - when disconnected from the communication line .

In the proposed technical solution, the CU can be implemented on various programmable devices that satisfy the dimensions of the UMSK.

UPIN, UPDS, UII, USPI, UK, URIN can be implemented by hardware (electromechanical devices) or software and hardware to reduce hardware requirements and algorithmic simplification of the CU software.

The range of operation of the URIN 6, the set of filters in the COVS 4, the set of calibration insulation resistances in CC 7 is chosen in accordance with the characteristics of the cable and the required measurement accuracy.

Further, the composition and operation of the cable condition monitoring device will be described in a preferred embodiment.

FIG. - block diagram of a device for monitoring the state of the cable in the preferred embodiment.

Presented in FIG. The device for monitoring the state of the cable (hereinafter - UMSK) contains a control device 1 (UU), the input / output of which is the information input / output of the UMSK, as well as a device for applying measuring voltage 2 (UPIN), the first input of which is connected to the first output of UU 1, and output - to the multifunctional input / output (hereinafter - MF I / O) UMSK. The latter is connected to the input of the device removing the primary information 3 (USPI), the output of which is connected to the first input of the device switching resistance range 4 (UDS). The UPDS 4 output through the quantizer 5 is connected to the input of the CID 1, and the second input to the second output of the CCD 1. The third output of the CCD 1 is connected to the second input of the UPIN 2 through the measuring voltage adjustment device 6 (URIN). A calibration device 7 (CC) is connected between the fourth output of the CU 1 and the MF I / O of the UMSK.

As a quantizer 5 in this implementation of the technical solution, an analog-to-digital converter (ADC) of a certain voltage range is selected (usually it is ADC from 3 to 5V, in rare cases - up to 12V). In other implementations, devices that convert an analog signal into duration, frequency, or duty cycle of a periodic signal can be selected for further processing of CU 1.

The UMSK estimates the level of voltage drop across its MF I / O to assess the state of the insulation of a communication line connected to it with an electrical cable (main operating mode) or when periodically calibrating the device by sequential supplying calibration resistors to MF I / O from CM 7 (calibration mode ). Consider the work of UMSK connected three-phase transformer - power cable to the submersible electric motor (SEM) connected by a communication line. The UMSK starts operation when the required supply voltage is applied to all devices requiring power.

In the main mode, the CU via output 1 transmits a command to UPIN to apply the measuring voltage U _meas1 through the known resistance R _measuring (reference measuring resistance) installed in it to the MF I / O and then to the power cable. The voltage drop (residual from U _ism ) obtained on a resistive divider R _measuring / R _isolation comes from UFM I / O MF to the input of USPI 3, which performs the functions of overvoltage protection, filtering and amplification of the incoming signal. The selected signal of residual voltage is supplied to the first input of the UPSL 4, which is tuned to one of the set Y _n (1 <n <N) voltage amplifiers, which correspond to different gain factors K _usn for each installed range of insulation resistance drop ΔR _n . The parameters N _n , K _usn , ΔR _n depend on the initial parameters of the cable insulation, measuring voltage, as well as the parameters of the quantizer 5, the required measurement accuracy. At the initial stages of cable operation, when the voltage drops over time are still very small, the voltage drop in the DCFL 4 coming from the MF I / O is digitized in the quantizer 5. While the resulting voltage from the output of the UPSL 4 is in the range of the quantizer 5, in UU 1 it is recalculated its equivalent insulation resistance value. If the resulting voltage from the output UPDS 4 does not fall into the range of operation of the quantizer 5 in the CU 1 produce switching insulation resistance drop range ΔR _n, decreasing K _usn and supplied command to the second input UPDS 4 for the corresponding change Y _n, reducing the resulting voltage on UDS output 4. The process is repeated until an acceptable result is obtained, until the resulting voltage falls into the range of the quantizer 5. In the case of obtaining a high insulation resistance value by the resulting voltage eniyu W 1 via the third output delivers the command to the unit measuring the voltage control to increase the measuring voltage UPIN 2 via its second input. Larger up to the maximum possible measurement voltage (U _{MOD max)} through the same _measuring R MF through the I / O is fed to the cable. Next, the process of measuring and calculating the cable insulation is performed again, as described above - via MF I / O, USPI 3, UDS 4, quantizer 5. The final value of the insulation resistance at time t (R of _t ) is calculated with a given accuracy according to the established K _usn , ΔRn, measuring voltage, as well as the measured value of the voltage drop. R from _t pass through the input / output of the CU 1 to the information input / output of the UMSK for transmission to an external device (consumer). The transmission is made, for example, by modifying the readable values of the ModBus RTU registers.

Thus, for correct digitization gradually increasing voltage drop when the deterioration of the cable insulation at high resistances gradually pass to respective ranges of the measured resistance ΔR _n in W 1 and decreasing K _usn adjusting respectively Y _n to decrease the value U _rev, which can change smoothly - for example, for each of the defined ΔRn, either discretely - ΔRn corresponds to several successive U _{rev m} (1 <m <M, M <N , U _max = U _{MOD MOD M).}

For large voltage drops, similarly go to the appropriate range of measured resistances ΔR _n for correct digitization in the quantizer 5 and increase the accuracy of measurements. At the same time, in VU 1, it is changed by increasing K _usn for selection in SPS 4 U _n , increasing the value of the residual voltage, then the resulting voltage is digitized and, if necessary, U u is _reduced .

After a change in _Um , a measurement and calculation of the cable insulation is performed again, as described above. The final insulation resistance values calculated with a given accuracy are transmitted to the information input / output of the UMSK for transmission to the consumer.

It is possible to calibrate the transfer characteristic of the measuring paths of the UMSK at the installation site. Such a need arises when over the course of time the aging of radio elements occurs, leading to errors in the process of transmitting the analog signal to the quantizer. To start the calibration mode MF I / O, the UMSK is disconnected from the communication line and the calibration mode is started. In this mode, according to commands of CU 1 via CC 7, in which a set of calibration insulation resistances is installed, they are connected in series to these reference resistance values to the MF I / O (to the unit for supplying the measuring voltage). The process of measuring the resistance is similar to the process of measuring cable insulation. After the completion of the process, the VU 1 performs correction of the transfer coefficients of the analog path (calibration coefficients) K _usn to recalculate the insulation, according to which Y _n is installed in ATDS 4 and on different insulation resistance ranges ΔRn.

Although the technical solutions are shown and described with reference to their specific embodiments, those skilled in the art should understand that various changes in form and content can be made without departing from the spirit and scope of the invention as defined by the appended claims.

For example, Quantizer 5 can be built into the CU 1 or can be implemented as a separate device. The digitization rate of the signal is much higher, but the cost increases, which is not always justified and claimed.

Thus, in the proposed technical solution, the device monitors the state of the cable due to UDS-4 and URIN-6, which allow time correction of the residual voltage at different insulation resistances and the measured voltage provide the ability to calculate the insulation resistance of the cable with a given accuracy and the consumer's assessment of the cable condition its operation.

Claims (2)

1. A cable condition monitoring device (UMSK), configured to supply the required supply voltage to all elements requiring power, containing a control device (CU), to the first output of which the first input of the measuring voltage supply device (UPIN) is connected, the output of which is connected to the multifunctional input / output of the UMSK, to which the input of the device for removing the primary information (USPI) is connected, and the quantizer, the output of which is connected to the input of the CU, the input / output of the CU is the information input / output of the UMSK, wherein the UMSK additionally contains a resistance range switching device (UDS), the first input of which is connected to the USPI output, the second input to the second output of the UU, and the output to the input of the quantizer, and the measuring voltage adjustment device (URIN) whose input is connected to the third output of the control unit, and the output to the second input of the UPIN. 2. A device for monitoring the state of the cable according to claim 1, characterized in that it further comprises a calibration device (CC), the input of which is connected to the fourth output of the control unit and the output to the multifunctional input / output of the UMSK.

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