RU170116U1 - HIGH VOLTAGE DIGITAL CURRENT MEASUREMENT DEVICE - Google Patents

Abstract

The utility model relates to measuring equipment, in particular to digital measuring devices of direct and alternating currents. A high-voltage digital device for measuring current, containing a supplying electromagnetic transformer, a measuring electromagnetic current transformer, a magnetotransistor converter and a Rogowski belt, covering the current-carrying conductor with a measured current; a cylindrical shunt with an internal cavity included in the dissection of the current lead; electronic unit, backup power unit, placed inside the shunt; two optical channels and a block of isolation transformers placed inside the reference insulator; the power supply unit, located on the low-voltage side, further comprises a second supplying electromagnetic transformer, a second measuring electromagnetic current transformer, a second magnetotransistor converter, a second Rogowski belt, covering the current-conducting conductor, a second power supply placed inside the shunt, a third optical channel placed in the reference an insulator, a second electronic unit located on the low-voltage side and having at least eight hardware devices for connecting external devices mouths, of which at least four are optical, and the first power supply has at least two hardware ports for connecting external devices, of which at least one is optical. The technical result is an increase in the reliability of the device. 1 ill.

Description

The utility model relates to measuring equipment, in particular to digital measuring devices of direct and alternating currents.

Known current sensor (patent for the invention of the Russian Federation No. 2377578, IPC G01R 19/00, 2008), containing a resistive element connected to an amplifier, and a power supply, a transformer galvanic isolation is installed between the resistive element and the sensor output, including an analog- a digital converter separating the transformer and the digital-to-analog converter, wherein the output of the amplifier is connected to an analog-to-digital converter, the output of the analog-to-digital converter is connected to the primary winding of the separating transformer, the secondary winding which is connected to a digital-to-analog converter, and the amplifier and analog-to-digital converter are connected to the power supply through a power transformer.

The disadvantages of this current sensor are the transmission of the measuring signal in digital form through an isolation transformer, the absence of electronic equipment shielding devices and, as a consequence, its sensitivity to electric and magnetic fields of the current-conducting conductor with the measured current, insufficient reliability due to the lack of redundancy of the current sensor and power system.

A high-voltage optoelectronic device for measuring current is known (patent for the invention of the Russian Federation No. 2346285, IPC G01R 19/00, 2009), containing a current sensor, an analog-to-digital converter and transmitter, the device is placed inside a current path with a measured current, and is under a high voltage potential in the zone of absence of magnetic and electric fields, and information on the magnitude of the measured current is transmitted in encoded digital form via an optical channel.

The disadvantage of this high-voltage optoelectronic device is that the measurement is carried out by determining the voltage on the shunt connected in parallel with the main current lead, changing the redistribution of currents between the current lead and the shunt leads to additional errors. Also, this device does not have a power supply unit for electronic equipment on the high-voltage side, which makes its operation impossible.

A high-voltage digital device for measuring current is known (patent for a utility model of the Russian Federation No. 137955, IPC G01R 19/00, 2014), containing a shunt, an analog-to-digital converter, an optical transceiver and an optical channel supplying an electromagnetic transformer and Rogowski belt covering the current conductor with measured current; a current-voltage converter, a voltage stabilizer, and a signal processing unit placed inside a shunt made cylindrical with an internal cavity and included in the cut of the current lead; a second optical transceiver, router, and power supply located on the low voltage side; wherein the optical transceiver is placed inside the shunt, and the signal processing unit includes an analog-to-digital converter; moreover, the feeding electromagnetic transformer is connected to a current-voltage converter, which is connected to a voltage stabilizer connected to the signal processing unit and to the first optical transceiver, potential shunt electrodes and Rogowski belt are connected to the signal processing unit, which is connected to the first optical transceiver through an optical channel, connected to the second optical transceiver connected to the router, and the power supply is connected to the second optical transceiver to the router and to the router.

The disadvantage of this device is the lack of diagnostics of the shunt signal, the lack of redundancy of the DC signal, the lack of accuracy of current measurements for commercial electricity metering systems, the lack of synchronization of measurements with the exact time system, the inability to operate the device in the absence or low current in the current lead, the absence of multiple power redundancy .

A high-voltage digital device for measuring current is known (patent for a utility model of the Russian Federation No. 150386, IPC G01R 19/00, 2015), adopted as a prototype containing a shunt, an analog-to-digital converter, an optical channel supplying an electromagnetic transformer, Rogowski belt, magnetotransistor a converter and a measuring electromagnetic current transformer, covering the current-conducting conductor with a measured current; a first power supply unit, a first electronic unit, a synchronization unit with an accurate time system and a battery placed inside a shunt made cylindrical with an internal cavity and included in a cut of a current lead; a block of isolation transformers placed inside the support insulator; a router, a second power supply, an optical pump module, and a second electronic unit located on the low voltage side; wherein the first electronic unit includes an analog-to-digital converter, and the second electronic unit includes a router; moreover, the supplying electromagnetic transformer is connected to the first power supply connected to the first electronic unit, potential shunt electrodes, Rogowski belt, magnetotransistor transducer, measuring electromagnetic current transformer and synchronization unit with the exact time system are also connected to the first electronic unit, the first power supply is additionally connected to a synchronization unit with an accurate time system, to a battery and an isolation transformer unit, an optical module the pump through the second optical channel is connected to the first power supply, the second power supply is connected to the second electronic unit, the block of isolation transformers and the optical pump module.

The disadvantage of this device is the lack of reliability due to the lack of multiple redundancy of power, the lack of redundancy of current sensors, as well as the lack of synchronization via 1PPS signals (optical or electrical) and the RTP protocol and backup of the output signal using the PRP and HSR protocols.

The technical result is to increase the reliability of the device.

The technical result is achieved in that a high-voltage digital device for measuring current, comprising a supply electromagnetic transformer, a measuring electromagnetic current transformer, a magnetotransistor transducer and a Rogowski belt, covering the current-carrying conductor with a measured current; a cylindrical shunt with an internal cavity included in the dissection of the current lead; electronic unit, backup power unit, placed inside the shunt; two optical channels and a block of isolation transformers placed inside the reference insulator; the power supply unit, located on the low-voltage side, further comprises a second supplying electromagnetic transformer, a second measuring electromagnetic current transformer, a second magnetotransistor converter, a second Rogowski belt, covering the current-conducting conductor, a second power supply placed inside the shunt, a third optical channel placed in the reference an insulator, a second electronic unit located on the low-voltage side and having at least eight hardware devices for connecting external devices mouths, of which at least four are optical, and the first power supply has at least two hardware ports for connecting external devices, of which at least one is optical, while the first supplying electromagnetic transformer and the second supplying electromagnetic transformer are connected to the second power supply, potential shunt electrodes, the first Rogovsky belt, the second Rogovsky belt, the first magnetotransistor converter, the second magnetotransistor converter, the first are connected to the first electronic unit The first measuring electromagnetic current transformer, the second electromagnetic current transformer and the second power supply unit, to which the backup power supply unit, the isolation transformer unit and through the second optical channel the first power supply unit, which is also connected to the isolation transformer unit and to the second electronic unit connected through the first and the third optical channels to the first electronic unit, moreover, the first and second supply electromagnetic transformers are located symmetrically relative but the cylindrical shunt, the first and second measuring electromagnetic current transformers are located symmetrically with respect to the cylindrical shunt, the first and second magnetotransistor converters are located symmetrically with respect to the cylindrical shunt, the first and second Rogowski belts are located symmetrically with respect to the cylindrical shunt.

The essence of the utility model is illustrated in the drawing. The following notation is used in the drawing: current lead 1, first supplying electromagnetic transformer 2, first measuring electromagnetic current transformer 3, first magnetotransistor converter 4, first Rogowski belt 5, cylindrical shunt 6, second Rogovsky 7 belt, second magnetotransistor converter 8, second measuring electromagnetic transformer current 9, the second supply electromagnetic transformer 10, the first electronic unit 11, the second power supply 12, the backup power supply 13, the first optical Channel 14, third optical channel 15, second optical channel 16, isolation transformer block 17, second electronic block 18, first power supply 19, support insulator 20, high-voltage digital devices for measuring the current of neighboring phases 21, GPS (GLONAS) - antenna 22 , a synchronization device issuing a 1PPS signal 23, a synchronization device operating according to the RTP 24 protocol, metrological information consumer devices or switches 25, an auxiliary system of a substation 26, an optical pump system 27.

The high-voltage digital device for measuring current contains a current lead 1, in the cut of which a cylindrical shunt 6 is included (combined with the current lead). The first supply electromagnetic transformer 2, the first measuring electromagnetic current transformer 3, the first magnetotransistor converter 4, the first Rogowski belt 5 cover the current lead 1 with the measured current, are the main set of sensors. The second Rogowski belt 7, the second magnetotransistor converter 8, the second measuring electromagnetic current transformer 9, the second supply transformer 10 also cover the current lead 1, are a backup set of sensors and are located symmetrically to the main set of sensors relative to the cylindrical shunt 6. The first electronic unit 11 is placed inside the cylindrical shunt 6 , the second power supply 12, the backup power supply 13. The first optical channel 14, the third optical channel 15, the second optical channel 16 and the block nyh transformers 17 placed inside the supporting insulator 20. The second electronic unit 18 is disposed on the low-voltage side and has at least eight hardware ports, of which at least four optic, for connecting external devices. The following external devices are connected to the second electronic unit 18: high-voltage digital devices for measuring the current of neighboring phases 21, GPS (GLONAS) - antenna 22, a synchronization device that generates a 1PPS 23 signal, a synchronization device operating according to the RTP 24 protocol, devices that consume metrological information or switches 25. The first power supply 19 is located on the low-voltage side and has at least two hardware ports, of which at least one is optical, for connecting external devices. The following external devices are connected to the first power supply 18: auxiliary system of substation 26, optical pumping system 27.

The first supply electromagnetic transformer 2 and the second supply electromagnetic transformer 10 are connected to the second power supply unit 12, potential electrodes of the shunt 6, the first measuring electromagnetic current transformer 3, the second electromagnetic current transformer 9, the first magnetotransistor converter 4, the second magnetotransistor converter are connected to the first electronic block 11 8, Rogowski’s first belt 5, Rogowski’s second belt 7 and the first power supply 12, to which a backup power supply 13, bl to the isolating transformer 17 and through a second optical channel 16, the first power supply 19 which is also connected to a block of isolating transformer 17 and the second electronic unit 18 connected through the first optical channel 14 and the third optical channel 15 to the first electronic unit 11.

The first electronic unit 11, the second power supply 12 and the backup power supply 13 are placed inside the shunt 6 to exclude the influence of electric and magnetic fields on them. The first optical channel 14, the third optical channel 15, the second optical channel 16 and the block of isolation transformers 17 are placed in the supporting insulator 20 to provide high-voltage isolation.

A cylindrical shunt 6 converts the entire spectrum of frequencies, including direct current and an aperiodic component with high accuracy, the first Rogovsky 5 belt and the second Rogovsky 7 belt allow currents to be measured in operating and transient modes. The first magnetotransistor converter 4 and the second magnetotransistor converter are designed to measure currents in transient and emergency operation in order to provide information for relay protection and automation, operate in the linear range with short-circuit currents of high multiplicity and convert the current without distortion in a wide range of frequencies, including constant and aperiodic components. The first measuring electromagnetic current transformer 3 and the second measuring electromagnetic current transformer 9 have a high accuracy class (since their magnetic cores are made of nanocrystalline alloy) and are designed to measure currents for automated information-measuring systems for commercial accounting of electricity. The first electronic unit 11 has ports for connecting a primary and backup set of sensors, a second power supply 12, optical ports for transmitting current information on the first optical channel 14 and for receiving a synchronization signal on the third optical channel 15. The second power supply 12 has ports for connecting the main and backup supplying electromagnetic transformers, the backup power supply unit 13, the isolation transformer unit 17 and the optical port for connecting the second optical channel 16. The backup power supply unit The output 13 may include a rechargeable battery and / or an ionistor and / or a battery (galvanic cell). The second electronic unit 18 has, for example, the following hardware ports for connecting external devices: optical ports for connecting high-voltage digital devices for measuring the current of neighboring phases, a port for connecting GPS (GLONAS) - antennas, a port for receiving an electrical synchronization signal 1PPS, a port for receiving 1PPS optical synchronization signal, a port for synchronization using the RTP protocol and two ports for transmitting current information to the consumer devices of metrological information. The synchronization signal option (GPS (GLONAS) - antenna, 1PPS (electric), 1PPS (optical), RTP protocol) is selected depending on the source and type of synchronization. Two ports for transmitting current information to the consumer devices of metrological information are made in order to implement PRP and HSR redundancy technologies. The first power supply 19, for example, has hardware ports for connecting the auxiliary system of the substation 26, the optical pumping system 27, the block of isolation transformers 17 and the second optical channel 16.

, на выходе первого магнитотранзисторного преобразователя 4, на выходе второго магнитотранзисторного преобразователя 8, на выходе первого измерительного электромагнитного трансформатора тока 3 и на выходе второго измерительного электромагнитного трансформатора тока 9 появляются напряжения, поступающие на первый электронный блок 11, где они обрабатываются в соответствии с запрограммированными алгоритмами, в том числе преобразуются в цифровую, а затем в оптическую форму. Также на первый электронный блок 11 через определенный интервал времени поступает сигнал синхронизации от второго электронного блока 18 через третий оптический канал 15. Информационный поток об измеренном токе с метками времени от первого электронного блока 11 через первый оптический канал 14 поступает на второй электронный блок 18. На второй электронный блок 18 через соответствующие аппаратные порты также поступают сигналы от первых электронных блоков высоковольтных цифровых устройств для измерения тока соседних фаз и сигнал синхронизации в зависимости от типа используемого источника синхронизации (GPS (ГJIOHAC) – антенна, или сигнал 1PPS (оптический), или сигнал 1PPS (электрический) или пакет данных, соответствующий протоколу РТР. Второй электронный блок 18 обрабатывает поступившие полученные данные в соответствии с запрограммированными алгоритмами, в том числе преобразует и передает их в соответствии с используемыми протоколами обмена данными с устройствами-потребителями информации о токах (например, IEC 61850-9-2). Потребителями информации могут быть устройства релейной защиты и автоматики, устройства коммерческого учета электроэнергии и др. Передача данных может осуществляться как напрямую устройствам-потребителям информации о токах, так и через промежуточные устройства (например коммутаторы). Электрический ток от первого питающего трансформатора 2 и второго питающего трансформатора 10, возникающий при протекании тока по токопроводу 1, поступает на второй блок питания 12, где осуществляется выпрямление, сглаживание, ограничение выходного напряжения. Питание для первого электронного блока 11 подается от второго блока питания 12. В свою очередь, питание ко второму блоку питания 12 подается либо от первого питающего электромагнитного трансформатора 2 (нормальный режим эксплуатации), либо от второго питающего трансформатора 10 (первый источник резервного питания в случае неисправности первого питающего электромагнитного трансформатора 2), либо от блока резервного питания 13 (второй источник резервного питания). В случае, если в блоке резервного питания 13 используется аккумуляторная батарея и/или ионистор, в нормальном режиме эксплуатации они подзаряжаются от второго блока питания 12. К первому блоку питания 19 подключается система собственных нужд подстанции 26 и система лазерной накачки 27. Первый блок питания 19 передает через второй оптический канал 16 оптический сигнал от системы лазерной накачки 27 второму блоку питания 12, где он, соответственно, преобразуется в электрический сигнал, используемый для питания первого электронного блока 11 внутри шунта 6. Оптический сигнал от системы лазерной накачки 27 может также преобразовываться в электрический сигнал первым блоком питания 19 для питания второго электронного блока 18 на низковольтной стороне высоковольтного цифрового устройства для измерения тока. Электрический сигнал от первого блока питания 19 может быть подан на блок разделительных трансформаторов 17, а затем на второй блок питания 12. Также электрический сигнал от второго блока питания 12 может быть подан на блок разделительных трансформаторов 17, а затем на первый блок питания 19. Питание для второго электронного блока 18 подается от первого блока питания 19.A high voltage digital device for measuring current and voltage operates as follows. When electric current flows through the current lead 1 and when voltage is applied to the line, a voltage drop is observed on the cylindrical shunt 6, in the first Rogovsky 5 belt and the second Rogovsky 7 belt, EMF equal to

, at the output of the first magnetotransistor converter 4, at the output of the second magnetotransistor converter 8, at the output of the first measuring electromagnetic current transformer 3 and at the output of the second measuring electromagnetic current transformer 9, the voltages supplied to the first electronic unit 11 appear, where they are processed in accordance with the programmed algorithms , including converted to digital, and then to optical form. Also, the synchronization signal from the second electronic unit 18 passes through the third optical channel 15 to the first electronic unit 11 after a certain time interval. The information stream about the measured current with time stamps from the first electronic unit 11 goes through the first optical channel to the second electronic unit 18. the second electronic unit 18 through the corresponding hardware ports also receives signals from the first electronic units of high-voltage digital devices for measuring the current of neighboring phases and a synchronization signal depending on the type of synchronization source used (GPS (ГJIOHAC) - antenna, or 1PPS signal (optical), or 1PPS signal (electric) or data packet corresponding to the RTP protocol. The second electronic unit 18 processes the received data in accordance with the programmed algorithms, including converts and transmits them in accordance with the used protocols for the exchange of data with consumer devices current information (for example, IEC 61850-9-2). Information consumers may include relay protection and automation devices, commercial electricity metering devices, etc. Data can be transmitted both directly to current information consumer devices and through intermediate devices (for example, switches). Electric current from the first supply transformer 2 and the second supply transformer 10, which occurs when current flows through the current lead 1, is supplied to the second power supply 12, where rectification, smoothing, and limitation of the output voltage are performed. The power for the first electronic unit 11 is supplied from the second power supply 12. In turn, the power to the second power supply 12 is supplied either from the first supply electromagnetic transformer 2 (normal operation) or from the second supply transformer 10 (first backup power source in the case of faults of the first supply electromagnetic transformer 2), or from the backup power supply unit 13 (second backup power source). If the backup power supply unit 13 uses a rechargeable battery and / or an ionistor, in normal operation they are recharged from the second power supply unit 12. The auxiliary system of substation 26 and the laser pumping system 27 are connected to the first power supply unit 19. First power supply unit 19 transmits through the second optical channel 16 an optical signal from the laser pumping system 27 to the second power supply unit 12, where it, accordingly, is converted into an electrical signal used to power the first electronic unit 11 inside coagulant 6. The optical signal from the laser pump system 27 may also be converted into an electric signal the first power supply unit 19 to supply the second electronic unit 18 on the low voltage side of the high-voltage digital device for measuring the current. An electrical signal from the first power supply 19 can be supplied to the block of isolation transformers 17, and then to the second power supply 12. Also, an electric signal from the second power supply 12 can be supplied to the block of isolation transformers 17, and then to the first power supply 19. Power for the second electronic unit 18 is supplied from the first power supply 19.

Thus, the use of a backup set of current sensors and a supplying electromagnetic transformer, the availability of hardware ports for receiving an electrical synchronization signal 1PPS, a port for receiving an optical synchronization signal 1PPS, a port for synchronization using the RTP protocol and two ports for transmitting current information to metrological information consumer devices in the claimed technical solution improves the reliability of the high-voltage digital device for measuring current and provides the ability to synchronize uu on signals 1PPS (optical and electrical) and PTP protocol.

Claims (1)

A high voltage digital device for measuring current, comprising a supply electromagnetic transformer, a measuring electromagnetic current transformer, a magnetotransistor transducer and a Rogowski belt, covering a current conducting conductor with a measured current; a cylindrical shunt with an internal cavity included in the dissection of the current lead; electronic unit, backup power unit, placed inside the shunt; two optical channels and a block of isolation transformers placed inside the reference insulator; a power supply unit located on the low-voltage side, characterized in that it further comprises a second supplying electromagnetic transformer, a second measuring electromagnetic current transformer, a second magnetotransistor transducer, a second Rogowski belt, covering the current-carrying conductor with a measured current, a second power supply placed inside the shunt, the third optical channel placed in the reference insulator, a second electronic unit located on the low-voltage side and having at least eight hardware ports, of which at least four are optical, and the first power supply has at least two hardware ports for connecting external devices, of which at least one is optical, while the first supplying electromagnetic transformer and the second supplying electromagnetic transformer are connected to the second power supply , potential shunt electrodes, the first Rogovsky belt, the second Rogovsky belt, the first magnetotransistor converter, the second magnetotransistor are connected to the first electronic block a converter, a first measuring electromagnetic current transformer, a second electromagnetic current transformer and a second power supply unit, to which a backup power unit, an isolation transformer unit are connected, and a first power supply unit, which is also connected to an isolation transformer unit and to a second electronic unit, connected through a second optical channel through the first and third optical channels to the first electronic unit, moreover, the first and second supply electromagnetic transformers are located with mmetrichno shunt relative to the cylindrical, the first and second electromagnetic measuring current transformers are arranged symmetrically relative to the cylindrical shunt magnitotranzistornye first and second transducers are disposed symmetrically relative to the cylindrical shunt, the first and second Rogowski coil arranged symmetrically relative to the cylindrical shunt.

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