RU2615790C1 - Monitoring device for power transformers - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device has a control unit 20 of the partial discharge, vibration control unit 21 and the transformer block colour visualization of the transformer technical condition of 22 levels. Continuous recording of the level and distribution of partial discharges in isolation bushings, coil, and magnetic circuit to determine the place of origin of the partial discharge and insulation failure mechanism. Control parameters of the vibration of the walls of the power transformer load tap changer tank and the body in real time allows you to determine the status of the compact coil and magnetic circuit. Specifying classification level technical condition of the transformer and the implementation of a light-signaling alert attendants different colour signals can improve the accuracy and timeliness of informing staff about the severity of deviations of parameters from the set limits.

EFFECT: enhanced functionality and increase the reliability of the power transformer through the implementation of a comprehensive work on the diagnostic monitoring main working transformer parameters in real-time assessment of defects of development and the level of danger of accidents, localization and identification of faults in the isolation transformer and the device voltage regulation under load, promptly informing staff about the level of deviation from the prescribed limits and severity of accidents.

3 dwg

Description

The invention relates to electrical engineering and is intended to monitor the main operating parameters and the technical condition of power transformers of arc steel-smelting furnaces and ladle-furnace assemblies during their operation in real time.

A device is known for continuously monitoring the technical condition of a transformer, comprising a cooling system, a unit for measuring the current value of the windings, a unit for monitoring the temperature of the windings, a unit for measuring the temperature of the oil cooling system, a unit for measuring the temperature of the transformer body and the environment, a unit for measuring partial discharges in the transformer, and a unit for monitoring the dielectric constant oils, a unit for monitoring the composition and concentration of gases dissolved in the oil, a block for the level and flow of liquid in the cooling system, a unit the cooling bearings of the pumping system, the storage unit for the maximum and minimum values for each monitored parameter and the time of their appearance, the unit for selecting four threshold levels, the alarm activation unit, the unit for transmitting the controlled parameters to the central computer, the control unit for actuating mechanisms of the power transformer by command from the central computer (see U.S. Pat. No. 4,654,806, H02H 7/04).

The disadvantage of this device is the low reliability of the assessment of the technical condition of the transformer due to the fact that it provides continuous measurement and calculation of only a limited number of parameters that determine the technical condition of high-voltage, including furnace, transformers. Accordingly, it does not implement a complete list of the necessary methods for monitoring the condition of transformers. This does not allow us to analyze the change in the parameters of the transformer during operation, which is necessary to identify and evaluate developing malfunctions, as well as the prompt response of personnel to eliminate problems.

The closest analogue to the claimed device is a device for monitoring power transformers, containing a current measuring unit, a voltage measuring unit, an ambient temperature measuring unit, a transformer oil cooling system monitoring unit, a transformer high voltage input state monitoring unit, a winding temperature control unit, a unit monitoring the status of transformer oil, processing and archiving unit of received data, unit for alerting maintenance personnel about when the protection system is in operation, the unit for monitoring the position of the voltage regulation device under load (on-load tap-changer), the unit for calculating the integral characteristics of the transformer, the unit for recording emergency processes, the unit for calculating models, the control unit for the oil cooling system of the transformer, the remote control unit for the on-load tap-changer, the unit for transformer status control parameters visualization unit, monitoring system integration unit in other automated systems, parameter change control unit transformer, while the first output of the current measuring unit is connected to the first input of the unit for calculating the integral characteristics of the transformer, its second output is connected to the first input of the unit for recording emergency processes, its third output is connected to the first input of the unit of calculation models, its fourth output is connected to the first input block for processing and archiving the received data, its fifth output is connected to the first input of the transformer status logging unit, its sixth output is connected to the first input of the alert unit maintenance personnel about the state of the protection system, its seventh output is connected to the first input of the on-load tap-changer remote control unit, the first output of the voltage measurement unit is connected to the second input of the integrated characteristics calculation unit, its second output is connected to the second input of the emergency process registration unit, its third the output is connected to the second input of the block of calculation models, its fourth output is connected to the second input of the block for processing and archiving the received data, its fifth output is connected with the second input of the transformer status logging unit, its sixth output is connected to the second input of the service personnel alert unit about the state of the protection system, the first output of the ambient temperature measuring unit is connected to the third input of the calculation model unit, its second output is connected to the third input of the logging unit transformer status, its third output is connected to the third input of the processing and archiving unit of the received data, its fourth output is connected to the first input of the control unit oil cooler of the transformer, its fifth output is connected to the third input of the notification unit for maintenance personnel about the status of the protection system, the first output of the control unit of the oil cooling system of the transformer is connected to the fourth input of the calculation model unit, its second output is connected to the fourth input of the transformer status logging unit, its third output is connected to the fourth input of the processing and archiving unit of the received data, its fourth output is connected to the second input of the control unit the topic of oil cooling of the transformer, its fifth output is connected to the fourth input of the personnel alert unit about the status of the protection system, the first output of the transformer high-voltage bushings state monitoring unit is connected to the seventh input of the personnel alert unit, the second output is connected to the seventh input of the unit transformer status logging, its third output is connected to the seventh input of the processing and archiving unit of the received data, the first output of the the temperature of the windings is connected to the fifth input of the block of calculation models, its second output is connected to the fifth input of the transformer status logging unit, its third output is connected to the fifth input of the processing and archiving unit of the received data, its fourth output is connected to the third input of the control unit of the oil cooling system transformer, its fifth output is connected to the fifth input of the personnel alert unit about the status of the protection system, the first output of the transformer oil state monitoring unit connected to the sixth input of the block of calculation models, its second output is connected to the sixth input of the transformer status logging unit, its third output is connected to the sixth input of the processing and archiving unit of received data, its fourth output is connected to the fourth input of the transformer oil cooling system control unit, fifth its output is connected to the sixth input of the personnel alert unit about the status of the protection system, the first output of the on-load tap-changer position control unit is connected to the seventh input of the bl OK of the calculation models, its second output is connected to the eighth input of the transformer status logging unit, its third output is connected to the eighth input of the processing and archiving unit of received data, its fourth output is connected to the second input of the on-load tap-changer remote control unit, the first output of the maintenance personnel alert unit about the state of the protection system is connected to the ninth input of the transformer status logging unit, its second output is connected to the ninth input of the processing and archiving unit data, the first output of the unit for calculating the integral characteristics of the transformer is connected to the eighth input of the unit of calculation models according to real-time measurements, its second output is connected to the tenth input of the transformer status logging unit, its third output is connected to the tenth input of the processing and archiving unit data, the first output of the emergency recording unit is connected to the eleventh input of the transformer status logging unit, its second output is connected to one the twentieth input of the processing and archiving unit of the received data, its third output is connected to the eighth input of the notification unit for maintenance personnel about the status of the protection system, its fourth output is connected to the first input of the visualization block of monitored parameters, the first output of the calculation model block is connected to the twelfth input of the state logging block transformer, its second output is connected to the twelfth input of the processing and archiving unit of the received data, its third output is connected to the first input of the integral unit monitoring system into other automated systems, its fourth output is connected to the fifth input of the transformer oil cooling control unit, its fifth output is connected to the second input of the monitored parameters visualization unit, the first output of the on-load tap-changer remote control unit is connected to the third input of the monitored parameters visualization unit, its second output is connected to the thirteenth input of the transformer status logging unit, its third output is connected to the second input of the unit integration of the monitoring system into other automated systems, its fourth output is connected to the ninth input of the warning personnel unit about the status of the protection system, the first output of the oil cooling control unit is connected to the fourth input of the monitored parameters visualization unit, its second output is connected to the fourteenth input of the logging unit state of the transformer, its third output is connected to the third input of the integration block of the monitoring system into other automated systems, the first output of the processing and archiving unit of the received data is connected to the fifth input of the visualization block of the monitored parameters, its second output is connected to the fourth input of the integration block of the monitoring system into other automated systems, its third output is connected to the input of the control unit for changing parameters of the transformer, its fourth output is connected to the third input of the remote control unit of the on-load tap-changer, its fifth output is connected to the sixth input of the control unit of the transformer oil cooling system, its sixth output is connected to the tenth input of the notification unit for maintenance personnel about the status of the protection system, the first output of the transformer status logging unit is connected to the sixth input of the monitored parameters visualization unit, its second output is connected to the thirteenth input of the data processing and archiving unit, the first output of the control unit changes in the parameters of the transformer is connected to the fifth input of the integration block of the monitoring system into other automated systems, its second output is connected to yrnadtsatym input processing and archiving of the data block, the first output imaging unit controlled parameters is connected to the fourth input of the remote control unit of RPN (see. RF patent for the invention No. 2242830, Н02Н 7/04).

A disadvantage of the known device is that it does not provide continuous monitoring of the whole complex of operating parameters necessary for a reliable assessment of the technical condition of the power transformer.

Another disadvantage is that the known device does not provide a classification of the technical condition of the transformer according to hierarchical levels depending on the degree of deviation of the controlled parameters from the set values. The known device provides only the inclusion and deactivation of the sound and light signaling alerts staff according to the results of a comparison of controlled or calculated parameters with valid transformer parameters. The above disadvantages lead to a decrease in the reliability of monitoring the technical condition of the power transformer and limit the possibility of preventing its accidents by the operational intervention of staff.

The problem solved by the present invention is to expand the functionality and increase the reliability of the power transformer.

The technical result, which provides a solution to the problem, is to prevent emergencies by carrying out comprehensive work on the diagnostic monitoring of the main operating parameters of the transformer in real time, assessing the degree of development of defects and the danger level of emergencies, localization and identification of malfunctions in the insulation of the transformer and device voltage regulation under load, as well as operational informing personnel about the level deviations from the prescribed limits and severity of accidents.

The problem is solved in that a device for monitoring power transformers, comprising a current measuring unit, a voltage measuring unit, an ambient temperature measuring unit, a transformer oil cooling system monitoring unit, a transformer high voltage input state monitoring unit, a winding temperature control unit, a control unit state of transformer oil, processing and archiving unit of received data, unit for alerting maintenance personnel about the status of the protection system , a unit for monitoring the position of the voltage regulation device under load (RPN), a unit for calculating the integral characteristics of the transformer, a unit for recording emergency processes, a unit for calculation models, a control unit for the oil cooling system of the transformer, a remote control unit for the on-load tap-changer, a unit for transformer status logging, a visualization unit controlled parameters, a unit for integrating the monitoring system into other automated systems, a unit for monitoring changes in transformer parameters, at m, the first output of the current measuring unit is connected to the first input of the transformer integral characteristics calculation unit, its second output is connected to the first input of the emergency recording unit, its third output is connected to the first input of the calculation models unit, its fourth output is connected to the first input of the processing unit and archiving the received data, its fifth output is connected to the first input of the transformer status logging unit, its sixth output is connected to the first input of the notification unit of the serving trans the status of the protection system, its seventh output is connected to the first input of the on-load tap-changer remote control unit, the first output of the voltage measurement unit is connected to the second input of the integral characteristics calculation unit, its second output is connected to the second input of the emergency recording unit, its third output is connected with the second input of the block of calculation models, its fourth output is connected to the second input of the processing and archiving unit of the received data, its fifth output is connected to the second input of the block the transformer status logs, its sixth output is connected to the second input of the personnel alert unit about the state of the protection system, the first output of the ambient temperature measuring unit is connected to the third input of the calculation model unit, its second output is connected to the third input of the transformer status logging unit, third its output is connected to the third input of the processing and archiving unit of the received data, its fourth output is connected to the first input of the oil cooler control unit of the transformer, its fifth output is connected to the third input of the notification unit for maintenance personnel about the state of the protection system, the first output of the control unit of the oil cooling system of the transformer is connected to the fourth input of the calculation model unit, its second output is connected to the fourth input of the transformer status logging unit, its third the output is connected to the fourth input of the processing and archiving unit of the received data, its fourth output is connected to the second input of the control unit of the oil cooling system of the transformer, its fifth output is connected to the fourth input of the personnel alert unit about the status of the protection system, the first output of the control unit of the high voltage inputs of the transformer is connected to the seventh input of the personnel alert unit, the second output is connected to the seventh input of the logging unit state of the transformer, its third output is connected to the seventh input of the processing and archiving unit of the received data, the first output of the coil temperature control unit the current is connected to the fifth input of the block of calculation models, its second output is connected to the fifth input of the transformer status logging unit, its third output is connected to the fifth input of the processing and archiving unit of received data, its fourth output is connected to the third input of the transformer oil cooling system control unit, its fifth output is connected to the fifth input of the personnel alert unit about the status of the protection system, the first output of the transformer oil condition monitoring unit is connected to the sixth input ohm of the block of calculation models, its second output is connected to the sixth input of the transformer status logging unit, its third output is connected to the sixth input of the processing and archiving unit of the received data, its fourth output is connected to the fourth input of the transformer oil cooling system control unit, its fifth output is connected with the sixth input of the personnel alert unit about the status of the protection system, the first output of the on-load tap-changer position control unit is connected to the seventh input of the calculation model unit, its output is connected to the eighth input of the transformer status logging unit, its third output is connected to the eighth input of the processing and archiving unit of the received data, its fourth output is connected to the second input of the on-load tap-changer of the on-load tap-changer, the first output of the notification unit of maintenance personnel about the status of the protection system connected to the ninth input of the transformer status logging unit, its second output is connected to the ninth input of the processing and archiving unit of the received data, the first the output of the unit for calculating the integral characteristics of the transformer is connected to the eighth input of the unit of calculation models according to real-time measurements, its second output is connected to the tenth input of the transformer status logging unit, its third output is connected to the tenth input of the processing and archiving unit of received data, the first output the emergency recording unit is connected to the eleventh input of the transformer status logging unit, its second output is connected to the eleventh input of the transformer working and archiving the received data, its third output is connected to the eighth input of the personnel alert unit about the status of the protection system, its fourth output is connected to the first input of the monitored parameters visualization unit, the first output of the calculation models block is connected to the twelfth input of the transformer status logging unit, the second its output is connected to the twelfth input of the processing and archiving unit of the received data, its third output is connected to the first input of the monitoring system integration unit and to other automated systems, its fourth output is connected to the fifth input of the transformer oil cooling control unit, its fifth output is connected to the second input of the monitored parameters visualization unit, the first output of the on-load tap-changer remote control unit is connected to the third input of the monitored parameters visualization unit, its second the output is connected to the thirteenth input of the transformer status logging unit, its third output is connected to the second input of the moni system integration unit toring to other automated systems, its fourth output is connected to the ninth input of the personnel warning unit about the status of the protection system, the first output of the oil cooling control unit is connected to the fourth input of the monitored parameters visualization unit, its second output is connected to the fourteenth input of the transformer status logging unit , its third output is connected to the third input of the integration block of the monitoring system into other automated systems, the first output of the processing unit The current data archiving is connected to the fifth input of the monitored parameters visualization unit, its second output is connected to the fourth input of the monitoring system integration unit into other automated systems, its third output is connected to the input of the transformer parameter change control unit, its fourth output is connected to the third input of the unit remote control of the on-load tap-changer, its fifth output is connected to the sixth input of the control unit of the transformer oil cooling system, its sixth output is connected connected with the tenth input of the notification unit for maintenance personnel about the status of the protection system, the first output of the transformer status logging unit is connected to the sixth input of the monitored parameters visualization unit, its second output is connected to the thirteenth input of the received data processing and archiving unit, the first output of the transformer parameter change control unit connected to the fifth input of the integration block of the monitoring system into other automated systems, its second output is connected to the fourteenth input of the unit while processing and archiving the received data, the first output of the visualization block of the monitored parameters is connected to the fourth input of the remote control unit of the on-load tap-changer, according to the invention it is equipped with a unit for monitoring the intensity of partial discharges, a vibration control unit for the transformer and a color visualization unit for the levels of the technical condition of the transformer, with the first output the partial discharge intensity control unit is connected to the fifteenth input of the processing and archiving unit received data, its second output is connected to the eleventh input of the notification unit for maintenance personnel about the status of the protection system, its third output is connected to the ninth input of the calculation model unit, its fourth output is connected to the fifteenth input of the transformer status logging unit, while the first output of the transformer vibration control unit connected to the sixteenth input of the processing and archiving unit of the received data, its second output is connected to the twelfth input of the notification unit of maintenance personnel about yanii protection system, a third output connected to its input to a tenth calculation block models fourth its output connected to input of the sixteenth reference state logs transformer and the input color imaging unit levels technical condition of the transformer is connected to the second output imaging unit controlled parameters.

Continuous recording of the level and distribution of partial discharges (PD) in the insulation of bushings, windings and the magnetic circuit allows you to determine the occurrence of PD and the mechanism of insulation failure: PD on the surface of the windings indicate the destruction of the semiconductor coating as a result of vibration and loosening of the fastening; PD in the depth of isolation - about the presence of cavities and delaminations as a result of constant temperature rise during prolonged operation of the power transformer outside the range of acceptable operating modes; PD between the insulation and the conductor result from cyclic loads.

Thus, this allows you to determine the localization of the place of occurrence of defects, and therefore, quickly identify malfunctions caused by destructive processes in the insulation of windings and magnetic circuits, for example, defects such as windings, insulation failures due to overheating, mechanical damage, etc. And registration of three-dimensional coordinates of each partial discharge pulse in the tank of the transformer allows you to evaluate the volume distribution of partial discharges in individual zones of the tank, veniya areas with increased discharge activity and the dynamics of change in their condition.

Setting the classification levels of the technical condition of the transformer and the implementation of light signaling alerts personnel with various color signals can increase the reliability and efficiency of informing personnel about the degree of danger of deviations of parameters from specified permissible limits.

Thus, the set of essential distinguishing features of the claimed device allows you to continuously measure and process information about the intensity, amplitudes, phases and spatial coordinates of the pulses of partial discharges in high-voltage bushings and the tank of the power transformer, measure the vibration parameters on the surface of the tank of the transformer and on-load tap-changer, to increase the reliability of the operational assessment technical condition of the power transformer by expanding the list of controlled parameters.

The invention is illustrated by drawings, where:

- in FIG. 1 shows a diagram of a device for monitoring power transformers;

- in FIG. 2 is a three-dimensional diagram explaining the formation of areas with increased discharge activity in the transformer tank;

- in FIG. 3 shows time diagrams of the change in vibration velocity measured on the tank wall and the load current of the transformer phase.

The inventive device for monitoring power transformers, comprises a current measuring unit 1, a voltage measuring unit 2, an ambient temperature measuring unit 3, a transformer oil cooling system monitoring unit 4, a transformer 5 high voltage input state monitoring unit, a winding temperature control unit 6, a unit monitoring the status of transformer oil 7, the processing and archiving unit of the received data 8, equipped with a system programmed in accordance with the main operating parameters power transformer in operation, a unit for notifying maintenance personnel about the state of the protection system 9, a unit for monitoring the position of the voltage regulation device under load (on-load tap-changer) 10, a unit for calculating the integral characteristics of the transformer 11, a unit for recording emergency processes 12, a unit for calculating models 13 according to measurements in real time, the control unit of the oil cooling system of the transformer 14, the remote control unit of the on-load tap-changer 15, the unit for maintaining the status logs of the transformer 16, b approx visualization controlled parameters 17, the block integration monitoring system in other automated system 18, such as the automated remote control system (ADCS), the automated system of electricity metering (ASUE); a control unit for changing the parameters of the transformer 19 during its operation.

In this case, the first output of the unit for measuring the current value 1 is connected to the first input of the unit for calculating the integral characteristics of the transformer 11, its second output is connected to the first input of the unit for recording emergency processes 12, its third output is connected to the first input of the unit of calculation models 13, and its fourth output is connected to the first input of the processing and archiving unit of the received data 8, its fifth output is connected to the first input of the transformer 16 status logging unit, its sixth output is connected to the first input of the notification unit get on the staff of the state security system 9, the seventh of its output is connected to the first input of the remote control device 15 RPN.

The first output of the voltage value measuring unit 2 is connected to the second input of the integral characteristics calculation unit of the transformer 11, its second output is connected to the second input of the emergency process recording unit 12, its third output is connected to the second input of the calculation models unit 13, and its fourth output is connected to the second input block processing and archiving the received data 8, its fifth output is connected to the second input of the transformer 16 status logging unit, its sixth output is connected to the second input of the notification unit maintenance personnel about the status of the protection system 9.

The first output of the ambient temperature measuring unit 3 is connected to the third input of the calculation model unit 13, its second output is connected to the third input of the transformer 16 status logging unit, its third output is connected to the third input of the received data processing and archiving unit 8, and its fourth output is connected with the first input of the control unit of the oil cooling system of the transformer 14, its fifth output is connected to the third input of the notification unit for maintenance personnel about the status of the protection system 9.

The first output of the control unit of the oil cooling system of the transformer 4 is connected to the fourth input of the unit of calculation models 13, its second output is connected to the fourth input of the transformer 16 status logging unit, its third output is connected to the fourth input of the processing and archiving unit of received data 8, and its fourth output connected to the second input of the control unit of the oil cooling system of the transformer 14, its fifth output is connected to the fourth input of the notification unit of maintenance personnel about the status of the systems 9 protection.

The first output of the control unit for the state of the high-voltage inputs of the transformer 5 is connected to the seventh input of the notification unit for maintenance personnel about the status of the protection system 9, its second output is connected to the seventh input of the transformer 16 status logging unit, its third output is connected to the seventh input of the processing and archiving unit for received data 8.

The first output of the temperature control unit of the windings 6 is connected to the fifth input of the calculation model unit 13, its second output is connected to the fifth input of the transformer 16 status logging unit, its third output is connected to the fifth input of the received data processing and archiving unit 8, and its fourth output is connected to the third input of the control unit of the oil cooling system of the transformer 14, its fifth output is connected to the fifth input of the notification unit of maintenance personnel about the status of the protection system 9.

The first output of the transformer oil condition monitoring unit 7 is connected to the sixth input of the calculation model unit 13, its second output is connected to the sixth input of the transformer 16 status logging unit, its third output is connected to the sixth input of the received data processing and archiving unit 8, its fourth output is connected with the fourth input of the control unit of the oil cooling system of the transformer 14, its fifth output is connected to the sixth input of the notification unit of maintenance personnel about the status of the protection system 9.

The first output of the position control unit of the on-load tap-changer 10 is connected to the seventh input of the block of calculation models 13, its second output is connected to the eighth input of the transformer 16 status logging unit, its third output is connected to the eighth input of the processing and archiving unit received 8, its fourth output is connected with the second input of the remote control unit of the on-load tap changer 15.

The first output of the notification unit for maintenance personnel about the state of the protection system 9 is connected to the ninth input of the transformer 16 status logging unit, its second output is connected to the ninth input of the processing and archiving unit of received data 8.

The first output of the unit for calculating the integral characteristics of the transformer 11 is connected to the eighth input of the block of calculation models 13 according to real-time measurements, its second output is connected to the tenth input of the transformer 16 status logging unit, its third output is connected to the tenth input of the processing and archiving unit received data 8.

The first output of the emergency recording unit 12 is connected to the eleventh input of the transformer 16 status logging unit, its second output is connected to the eleventh input of the processing and archiving unit of received data 8, its third output is connected to the eighth input of the notification unit for maintenance personnel about the status of the protection system 9, its fourth output is connected to the first input of the visualization block of the controlled parameters 17.

The first output of the block of calculation models 13 is connected to the twelfth input of the transformer 16 status logging unit, its second output is connected to the twelfth input of the processing and archiving unit for received data 8, its third output is connected to the first input of the integration block of the monitoring system into other automated systems 18, the fourth its output is connected to the fifth input of the control unit of the oil cooling system of the transformer 14, its fifth output is connected to the second input of the visualization unit of the monitored parameters 17.

The first output of the remote control unit of the on-load tap changer 15 is connected to the third input of the visualization block of the monitored parameters 17, its second output is connected to the thirteenth input of the transformer 16 status logging unit, its third output is connected to the second input of the monitoring system integration block into other automated systems 18, the fourth its output is connected to the ninth input of the unit 9 for alerting maintenance personnel about the state of the protection system.

The first output of the control unit of the oil cooling system of the transformer 14 is connected to the fourth input of the visualization block of the monitored parameters 17, its second output is connected to the fourteenth input of the status logging unit of the transformer 16, its third output is connected to the third input of the monitoring system integration unit into other automated systems 18.

The first output of the processing and archiving unit of the received data 8 is connected to the fifth input of the visualization block of the monitored parameters 17, its second output is connected to the fourth input of the integration block of the monitoring system 18 (for example, into an automated remote control system, an automated electricity metering system), its third output is connected with the input of the control unit for changing the parameters of the transformer 19, its fourth output is connected to the third input of the remote control unit of the on-load tap-changer 15, its fifth exit d is connected to the sixth input of the control unit of the oil cooling system of the transformer 14, its sixth output is connected to the tenth input of the notification unit of maintenance personnel about the status of the protection system 9.

The first output of the transformer 16 status logging unit is connected to the sixth input of the visualization unit of the monitored parameters 17, its second output is connected to the thirteenth input of the processing and archiving unit of the received data 8.

The first output of the control unit for changing the parameters of the transformer 19 is connected to the fifth input of the integration unit of the monitoring system into other automated systems 18, its second output is connected to the fourteenth input of the unit 8 for processing and archiving the received data.

The first output of the visualization block of the monitored parameters 17 is connected to the fourth input of the remote control unit of the on-load tap-changer 15.

In addition, the device for monitoring power transformers is equipped with a unit for controlling the intensity of partial discharges 20, a unit for vibration control of the transformer 21 and a unit for color visualization of the levels of the technical state of the transformer 22.

Moreover, as the block 20, the AR700 device can be used, which is used to register and analyze acoustic signals on the outer surface of the tank of power transformers and other oil-filled high-voltage equipment. The presence in the device of 4 synchronous channels for recording signals from acoustic sensors makes it possible to effectively solve the problem of location of the place of occurrence of a defect inside the transformer. The main parameter for this is the difference in the time of arrival of the acoustic signal to different sensors.

As a block 21, a “Diana-2M” brand of vibration signals analyzer included in the delivery of the “Vesta” system can be used. The vibration sensor is fixed on the surface of the transformer tank with a magnet. In idle mode of the transformer, only the magnetic circuit vibrates, and in load mode, the vibration of the windings is added. If the winding is well pressed in, then it vibrates at a frequency of 100 Hz. If the pressing force of the winding or core is less than normal, then higher harmonics appear in the vibration spectrum, which are multiples of 100 Hz - 200, 300, ..., 1000 Hz. For a quantitative assessment of the quality of the compact, the calculated “state factors” of the compact are used. This allows you to unify the diagnostic conclusions for all types of transformers.

The boundaries of the technical condition of the controlled parameters are determined as follows:

- If the value of the calculated state coefficient (winding compaction, active steel compaction) is more than 0.9, then this is a zone of good condition.

- If it is less than 0.9, but more than 0.8, then this parameter meets the criteria for a satisfactory condition

- If its value is below 0.8, this is a zone of alarm and even emergency status. Measures should be taken on possible ways to improve the condition of the transformer.

As a block 22, a monitor screen can be used, which shows an area in the form of five color traffic lights: green, yellow, orange, red and Bordeaux, or a separately made light panel based on light diodes of the indicated colors.

Distinctive features of the inventive monitoring device allow the early stages to identify problems requiring quick analysis and immediate elimination, as well as to ensure operational information content of the staff on the status of the transformer.

In this case, the first output of the partial discharge intensity control unit 20 is connected to the fifteenth input of the processing and archiving unit of the received data 8, its second output is connected to the eleventh input of the notification unit for maintenance personnel about the state of the protection system 9, its third output is connected to the ninth input of the calculation model unit 13 , its fourth output is connected to the fifteenth input of the transformer 16 state logging unit.

In this case, the first output of the vibration control unit of the transformer 21 is connected to the sixteenth input of the processing and archiving unit of the received data 8, its second output is connected to the twelfth input of the notification unit for maintenance personnel about the state of the protection system 9, its third output is connected to the tenth input of the block of calculation models 13, its fourth output is connected to the sixteenth input of the transformer 16 state logging unit.

The input unit of the color visualization of the levels of the technical state of the transformer 22 is connected to the second output of the visualization unit of the controlled parameters. 17

A device for monitoring power transformers (Fig. 1) works as follows.

All the main operating parameters of the power transformer are measured and monitored using primary parameter measuring units.

The unit for measuring the current value 1 measures the instantaneous, average, and current values of the current in the high, medium, and low voltage windings in phases A, B, C, providing constant monitoring of all current values and monitoring the presence or absence of current overloads.

The voltage measurement unit 2 measures the instantaneous, average, and current voltage values in the high, medium, and low voltage windings in phases A, B, C, providing constant monitoring of all voltage values and monitoring for the presence or absence of voltage overloads.

The unit for measuring the ambient temperature 3 constantly monitors the value of the specified temperature.

The control unit of the oil cooling system of transformer 4 measures the temperature of the upper layers of transformer oil, measures the temperature of transformer oil at the inlet and outlet of coolers, controls the oil level and controls the oil pressure in the transformer tank and on-load tap-changer tank, which allows full control of the transformer oil cooling system and in a timely manner to prevent emergencies that may occur when the oil level in or in the transformer tank rises or falls troystva tap changer, with a sharp increase of oil pressure in the tank of the transformer or tap changer tank, with an increase in the oil temperature in the transformer tank or tank OLTC above permissible.

The unit for monitoring the state of the high-voltage bushings of the transformer 5 measures the oil pressure in the bushings and measures the leakage currents in the insulation.

The temperature control unit of the windings 6 measures the temperature in the windings of high, medium and low voltage in phases A, B, C.

The transformer oil condition monitoring unit 7 measures the oil temperature, its humidity and the concentration of dissolved gases in the oil in the transformer tank and on-load tap-changer tank. For power transformers of arc steel-smelting furnaces and units, the ladle furnace unit 7 must provide continuous monitoring of six to nine combustible gases present in the oil and the speed of their generation. Minimum list of gases to be controlled: СО, Н ₂ , С ₂ Н ₂ , С ₂ Н ₄ , С ₂ Н ₆ , СН ₂ .

The primary parameters are processed by the unit for calculating the integral characteristics of the transformer 11 and the unit for recording emergency processes 12. Based on the information received from the unit for measuring the magnitude of the current 1 and from the unit for measuring the magnitude of the voltage 2, the unit for calculating the integral characteristics of the transformer 11 calculates all the necessary electrical and non-electric characteristics , including active, reactive and apparent power, energy, load factor, power factor. Based on the information received from the unit for measuring the magnitude of current 1 and the unit for measuring the magnitude of voltage 2, taking into account the calculated integral characteristics in the unit for recording emergency processes 12, the oscillograms are automatically recorded when the permissible instant, average and effective values of any of the measured parameters are exceeded.

The control unit of the position of the on-load tap-changer device 10 provides information on the position of the on-load tap-changer in phases A, B and C, the start and end times of the on-load tap-changer switching in each phase, the number of switching-over of the on-load tap-changer, which allows operational monitoring of the on-load tap-changer operation.

The block of calculation models 13 according to measurements in real time based on information from the block for measuring the magnitude of the current 1, the block for measuring the magnitude of the voltage 2, the block for measuring the ambient temperature 3, the block for monitoring the oil cooling system of the transformer 4, the block for monitoring the state of the high-voltage inputs of the transformer 5, the temperature control unit of the windings 6, the transformer oil condition monitoring unit 7, the position control unit of the on-load tap-changer 10, calculates the service life of the power transfer ormator taking into account the temperature value of the warmest point of the winding, the quality of the transmitted energy, active, reactive and apparent power, average values of current and voltage in a three-phase network, positive and negative sequences of current and voltage, unbalance of currents and voltages in a three-phase network, power factor, ratio the amplitude of the zero harmonic of the current to the sum of all harmonics of the current, the cosine of the phase difference of the harmonics of the current and voltage, the consumption of electricity (active and reactive), the total percentage of harmonic distortions, transformation coefficient, permissible load factor, transformer service life, on-load tap-changer service life, insulation aging rate.

In the event of an emergency in one or more transformer systems, the protection system is activated, which triggers the sound and light signaling of the personnel warning unit about the status of the protection system 9. The alarm is disabled only after the maintenance personnel take measures to eliminate the emergency.

The control unit for the oil cooling system of the transformer 14 uses the information received from the control unit for the oil cooling system of the transformer 4 and the unit of the calculation models 13. The control of the oil cooling system of the transformer allows for minimum fluctuations in the oil temperature in the oil cooling system of the transformer, as well as to control the wear of the cooling system drives.

The on-load tap-changer remote control unit 15 switches the on-load tap-changer at the command of an operator or dispatcher from a remote control room through the visualization unit of the monitored parameters 17. The on-load tap-changer 15 remote control unit can block its switching when receiving information from the current measuring unit about current transformer overloads.

The transformer 16 status logging unit continuously records all current parameters measured and controlled by the current magnitude measuring unit 1, voltage magnitude measuring unit 2, ambient temperature measuring unit 3, transformer oil cooling system control unit 4, transformer 5 high-voltage bushings state monitoring unit , winding temperature control unit 6, transformer oil condition control unit 7, on-load tap-changer position control unit 10. Reference unit transformer 16 status logs also continuously records all the calculation parameters coming into it from the transformer 11 integrated characteristics calculation unit, calculation model units 13, and also from the emergency process recording unit 12. Registers the transformer 16 status logging unit and information about the operation of the service notification unit personnel about the state of the protection system 9, as well as about actions carried out using the remote control unit of the on-load tap-changer 15 and the control unit for transformer cooling 14.

The processing and archiving unit of the received data 8, equipped with a system programmed in accordance with the main permissible parameters of the power transformer in operation, processes and archives all measured and calculated parameters, as well as all events occurring during the operation of the transformer, compares it data with valid transformer operation parameters.

The control unit for changing the parameters of the transformer 19 during its operation allows, on the basis of archival data coming from the processing and archiving unit of the received data 8, to restore information at any time about the processes that have occurred and are occurring during the operation of the transformer and about changes in the state of its most important systems, and also predict its condition based on existing trends.

The visualization block of the monitored parameters 17 provides the operator with the opportunity to conveniently work with the current, archived and calculated values of the operating parameters in the form of tables and / or graphs, which allows you to timely track the occurrence of a pre-emergency or emergency situation and take measures to prevent and / or eliminate such a situation.

The integration unit of the monitoring system into other automated systems 18 allows dispatchers to monitor at a distance all operating parameters and work with archive data, as well as with information about changes that occur during operation of the transformer. Information about the values of the measured operating parameters, about the parameters obtained by calculation, and about the events that occur during the operation of the transformer are received in the integration unit of the monitoring system 18 from the block of calculation models 13, the remote control unit of the on-load tap changer 15, the control unit of the oil cooling system of the transformer 14, processing unit and archiving the received data 8, the control unit changes the parameters of the transformer 19 during its operation. This allows you to remotely control the operation of the most important transformer systems from the central control center and constantly monitor its operation modes.

Functions for recording controlled parameters, storing and displaying initial and calculated information, processing and archiving data, processing information about changes that occur during operation of the transformer, maintaining transformer status logs, visualization, and ensuring working with current, archived and calculated values of operating parameters in the form tables and / or graphs, remote monitoring of the operation of transformer systems from the central control room do not differ from the functions of the device state, taken as a prototype.

The unit for controlling the intensity of partial discharges 20 provides acoustic control and continuous fixation of the intensity of partial discharges, as well as the amplitude, phase, and spatial coordinates of each pulse. Using the built-in software, information is processed on the intensity, amplitude, phase and spatial coordinates of the pulses of partial discharges, the results of which determine the areas with the highest discharge activity. Since partial discharges are signs of destructive processes in isolation, this allows you to quickly localize the place of occurrence of the malfunction in the volumetric space of the transformer tank. The foregoing is explained using the partial discharge diagram shown in FIG. 2 in three-dimensional coordinates. The diagram conventionally shows the centers of sites with increased intensity of discharge phenomena. An analysis of the spatial displacement of these centers, as well as the dynamics of changes in bit activity, allows one to evaluate the intensity of the development of destructive processes in isolation in real time. It is advisable to implement this method of processing spatial coordinates using a subprogram that implements the subtractive clustering algorithm included in the MATLAB application package (see, for example, Shtovba SD. Introduction to the theory of fuzzy sets and fuzzy logic. Designing control systems \ Fuzzy Logic Toolbox - http://matlab.exponenta.ru/fuzzylogic/book1/12_2.php).

The vibration control unit of the transformer 21 controls the vibration parameters: vibration velocity and / or vibration acceleration, measured directly on the transformer tank and on-load tap-changer cover. The need to control these parameters is explained with the help of time diagrams (trends) of vibration velocity (upper graph) and phase current of the power transformer (lower graph) obtained from the results of measurements during the month shown in FIG. 3. A comparative analysis of these trends allows us to conclude that they are mutually identical, that is, about the unambiguous effect of a rapidly changing load on vibration indicators. The range of vibration velocity fluctuations exceeds 50 mm / s at an acceptable level of 10 mm / s. This leads to a weakening of the pressing of the windings and the magnetic circuit of the power transformer and the resulting emergency consequences. In addition, vibration control of the power transformer allows you to evaluate the state of its mechanical system, identify and subsequently eliminate defects, for example, resonant vibration of pipelines, wear of bearings of oil pumps. The above diagrams confirm the relevance of continuous monitoring of vibration parameters of the power transformer and on-load tap-changer.

According to the results of processing information about the excess of the current values of any of the measured parameters of the specified permissible limits, registration and monitoring of the development of emergency processes are carried out. To do this, in the color visualization block of the technical state of the transformer 22, the classification levels of the technical state of the transformer are set. According to the results of calculating the diagnostic parameters, the technical condition is graded according to several conditional levels characterizing the technical condition. According to the recommendations of the ROSENERGOATOM concern's governing documents, the classification levels are set: “norm”, “norm with deviations”, “norm with significant deviations”, “deteriorated”, “pre-emergency”. The signaling that one or more parameters has exceeded the threshold values set for each level causes the inclusion of a differential color signal on the monitor screen or light panel. So, the range “norm” corresponds to a green signal, the ranges “norm with deviations”, “norm with significant deviations”, “deteriorated”, “pre-emergency” correspond to yellow, orange, red and Bordeaux, respectively. This allows you to timely track the occurrence of a pre-emergency situation and take operational measures to prevent its development.

The inventive device for monitoring power transformers of arc steel-smelting furnaces and ladle-furnace assemblies during their operation in real time provides monitoring of its main operating parameters, an operational assessment of the degree of development of defects and the level of danger of an emergency, localization of the location of the malfunction in the insulation of the transformer, high-voltage inputs and mechanical units.

The technical implementation of the device for monitoring power transformers reduces the likelihood of accidents by increasing the reliability of diagnostic monitoring of the technical condition of the transformer, localization and identification of malfunctions in the insulation of the transformer windings, on-load tap-changer devices, mechanical components, and promptly informing personnel about the level of deviations of parameters from the specified permissible limits and degree danger of accidents.

Claims (5)

A device for monitoring power transformers, comprising a current measuring unit, a voltage measuring unit, an ambient temperature measuring unit, a transformer oil cooling system monitoring unit, a transformer oil high voltage condition monitoring unit, a winding temperature monitoring unit, a transformer oil state monitoring unit, a processing unit and archiving the received data, a unit for alerting maintenance personnel about the status of the protection system, a unit for monitoring the position of the device p voltage regulation under load (on-load tap-changer), transformer integral characteristic calculation unit, emergency process registration unit, calculation model unit, transformer oil cooling system control unit, on-load tap-changer remote control unit, transformer status logging unit, monitored parameter visualization unit, system integration unit monitoring to other automated systems, a control unit for changing the parameters of the transformer, while the first output of the unit for measuring The current is connected to the first input of the transformer integral characteristics calculation unit, its second output is connected to the first input of the emergency process registration unit, its third output is connected to the first input of the calculation models unit, its fourth output is connected to the first input of the processing and archiving unit of received data, fifth its output is connected to the first input of the transformer status logging unit, its sixth output is connected to the first input of the notification unit for maintenance personnel about the status of the protection system, gray Its seventh output is connected to the first input of the on-load tap-changer remote control unit, the first output of the voltage measurement unit is connected to the second input of the integrated characteristics calculation unit, its second output is connected to the second input of the emergency recording unit, its third output is connected to the second input of the calculation models block , its fourth output is connected to the second input of the block processing and archiving the received data, its fifth output is connected to the second input of the transformer status logging unit, its sixth output is connected to the second input of the notification unit for maintenance personnel about the state of the protection system, the first output of the ambient temperature measuring unit is connected to the third input of the calculation model unit, its second output is connected to the third input of the transformer status logging unit, its third output is connected to the third input of the processing and archiving unit received data, its fourth output is connected to the first input of the transformer oil cooling system control unit, its fifth output is connected to the third input of the personnel alert notification unit, the first output of the transformer oil cooling control unit is connected to the fourth input of the calculation model unit, its second the output is connected to the fourth input of the transformer status logging unit, its third output is connected to the fourth input of the processing and archiving unit received ny, its fourth output is connected to the second input of the transformer oil cooling system control unit, its fifth output is connected to the fourth input of the personnel alert unit about the status of the protection system, the first output of the transformer high voltage inputs state control unit is connected to the seventh input of the personnel alert unit protection system, its second output is connected to the seventh input of the transformer status logging unit, its third output is connected to the seventh input of the transformer As for processing and archiving the received data, the first output of the temperature control unit of the windings is connected to the fifth input of the block of calculation models, its second output is connected to the fifth input of the transformer status logging unit, its third output is connected to the fifth input of the processing and archiving unit of the received data, its fourth the output is connected to the third input of the transformer oil cooling control unit, its fifth output is connected to the fifth input unit for notifying maintenance personnel about the status of the protection system, the first output of the transformer oil status monitoring unit is connected to the sixth input of the calculation model unit, its second output is connected to the sixth input of the transformer status logging unit, its third output is connected to the sixth input of the processing and archiving received data , its fourth output is connected to the fourth input of the transformer oil cooling system control unit, its fifth output is connected to the sixth input of the warning unit staff on the status of the protection system, the first output of the on-load tap-changer position control unit is connected to the seventh input of the calculation model unit, its second output is connected to the eighth input of the transformer status logging unit, its third output is connected to the eighth input of the processing and archiving unit of received data, fourth its output is connected to the second input of the on-load tap-changer remote control unit; the first output of the personnel alert unit about the status of the protection system is connected to the ninth the transformer status logging unit, its second output is connected to the ninth input of the processing and archiving unit of the received data, the first output of the transformer integral characteristics calculation unit is connected to the eighth input of the calculation model unit according to real-time measurements, its second output is connected to the tenth input transformer status logging unit, its third output is connected to the tenth input of the processing and archiving unit of the received data, the first output of the av recording unit The process is connected to the eleventh input of the transformer status logging unit, its second output is connected to the eleventh input of the processing and archiving unit of the received data, its third output is connected to the eighth input of the personnel alert unit, the fourth output is connected to the first input of the unit visualization of controlled parameters, the first output of the block of calculation models is connected to the twelfth the input of the transformer status logging unit, its second output is connected to the twelfth input of the processing and archiving unit of the received data, its third output is connected to the first input of the monitoring system integration unit in other automated systems, its fourth output is connected to the fifth input of the transformer oil cooling system control unit , its fifth output is connected to the second input of the visualization block of the controlled parameters, the first output of the remote control unit of the on-load tap-changer is connected the third input of the monitored parameters visualization unit, its second output is connected to the thirteenth input of the transformer status logging unit, its third output is connected to the second input of the monitoring system integration unit into other automated systems, its fourth output is connected to the ninth input of the system personnel alert unit protection, the first output of the control unit of the oil cooling system is connected to the fourth input of the visualization unit of the controlled parameters, the second the output is connected to the fourteenth input of the transformer status logging unit, its third output is connected to the third input of the monitoring system integration unit in other automated systems, the first output of the processing and archiving unit of the received data is connected to the fifth input of the monitored parameters visualization unit, its second output is connected to the fourth the input of the integration block of the monitoring system into other automated systems, its third output is connected to the input of the control unit of changes in the parameters of trans rmator, its fourth output is connected to the third input of the on-load tap-changer remote control unit, its fifth output is connected to the sixth input of the transformer’s oil-cooling system control unit, its sixth output is connected to the tenth input of the personnel alert unit, the first output of the logging unit the state of the transformer is connected to the sixth input of the visualization block of the controlled parameters, its second output connected to the thirteenth input of the processing and archiving unit of the received data, the first output of the control unit for changing the parameters of the transformer is connected to the fifth input of the integration unit of the monitoring system into other automated systems, its second output is connected to the fourteenth input of the processing and archiving of the received data, the first output of the monitored visualization unit parameters connected to the fourth input of the remote control unit of the on-load tap-changer, characterized in that it is equipped with an intensifier control unit partial discharges, a transformer vibration control unit and a color visualization unit for the transformer technical status levels, while the first output of the partial discharge intensity control unit is connected to the fifteenth input of the processing and archiving unit of the received data, its second output is connected to the eleventh input of the state personnel notification unit protection systems, its third output is connected to the ninth input of the block of calculation models, its fourth output is connected to the fifteenth input m of the transformer status logging unit, while the first output of the transformer vibration monitoring unit is connected to the sixteenth input of the processing and archiving unit of the received data, its second output is connected to the twelfth input of the service personnel notification unit about the status of the protection system, its third output is connected to the tenth input of the unit calculation models, its fourth output is connected to the sixteenth input of the transformer status logging unit, and the input of the color visualization unit of technical levels th state of the transformer is connected to the second output imaging unit controlled parameters.

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