CN112327237A - Error calibration system and method for broadband wide-range current transformer - Google Patents

Abstract

The invention discloses an error calibration system and method of a broadband wide-range current transformer, which comprises the following steps: the system comprises a broadband wide-range standard transformer, a broadband large current generating device and a broadband wide-range transformer calibrator; the broadband large current generating device provides working current for the primary side of the broadband wide-range current transformer to be tested and the primary side of the broadband wide-range standard transformer; the wide-bandwidth range transformer calibrator acquires a standard current signal of a secondary side of a standard transformer and a current signal to be measured of the secondary side of a wide-bandwidth range current transformer to be measured, performs data preprocessing to obtain a digital signal capable of being calculated, and performs error calculation to obtain an error of the wide-bandwidth range current transformer to be measured; the wide-bandwidth range transformer calibrator adopts the multi-gear Hall sensor, and the sampling system also has the range switching capability, so that the current measurement range is expanded, the sampling precision of a low-current signal is ensured, and the wide-range frequency adaptability is realized.

Description

Error calibration system and method for broadband wide-range current transformer

Technical Field

The invention relates to the technical field of error measurement, in particular to an error calibration system and method for a broadband wide-range current transformer.

Background

With the wide application of power electronic equipment, in some special occasions of a power system, the load change range is very large, and the frequency band is wide. For example, a high-speed rail rapidly developed in China has the characteristics of high speed, large traction force, no direct pollution and the like, and a traction substation converts a high-voltage power supply of a public network into a power supply suitable for an electric locomotive. When an electric locomotive passes through the traction substation, the current passing through the traction substation can basically reach a rated value or even higher, and in the time period after the electric locomotive passes through the traction substation, the current passing through the traction substation is very small. For a special occasion with large load change, the traditional current transformer cannot meet the requirement of metering, so the broadband wide-range current transformer is more and more widely applied, and because the wide-range current transformer has the characteristics of wide range and wide frequency, the traditional current transformer calibration method (only aiming at 1% -120% of the rated current of the current transformer) is difficult to simply transplant to be applied to the error calibration of the broadband wide-range current transformer, so a corresponding error calibration method needs to be designed aiming at the wide-range current transformer.

Disclosure of Invention

In order to solve the technical problem, the invention provides an error calibration system and method for a broadband wide-range current transformer, which are used for completing error calibration or calibration of the broadband wide-range current transformer.

The invention is realized by the following technical scheme:

this scheme provides a wide band wide range current transformer's error calibration system, includes: the system comprises a broadband wide-range standard transformer, a broadband large current generating device and a broadband wide-range transformer calibrator;

the wide-bandwidth range transformer calibrator consists of a multi-gear Hall sensor A, a multi-gear Hall sensor B, a wide-bandwidth and wide-range standard transformer, a data processing module A, a data processing module B and a calculation module;

the primary side of the broadband wide-range standard transformer and the primary side of the broadband wide-range current transformer to be tested are connected in series and then connected to two ends of the broadband large current generating device; the secondary side of the standard transformer with wide frequency and wide range is connected with a multi-gear Hall sensor A, and the secondary side of the current transformer with wide frequency and wide range to be tested is connected with a multi-gear Hall sensor B;

the multi-gear Hall sensor A collects a standard current signal of a secondary side of a broadband wide-range standard mutual inductor and converts the standard current signal to output a standard small current signal in proportion to the standard current signal; the multi-gear Hall sensor B collects a current signal to be measured at the secondary side of the wide-bandwidth range current transformer to be measured, and converts and outputs a small current signal to be measured in proportion to the current signal to be measured;

the data processing module A converts the standard small current signal into a standard small voltage signal, amplifies the standard small voltage signal, converts the standard small voltage signal into a digital signal and outputs the digital signal to the computing module; the data processing module B converts the small current signal to be detected into a small voltage signal to be detected, amplifies the small voltage signal and converts the small voltage signal to be detected into a digital signal to be output to the computing module;

and the calculation module performs error calculation based on the data output by the data processing module A and the data output by the data processing module B to obtain the error of the wide-bandwidth range current transformer to be measured.

Further, the data processing module a or B comprises: the device comprises a sampling resistor, a program control operational amplifier module, an AD conversion module, a bottom layer 32-bit microcomputer and an embedded 32-bit microcomputer; the program control operational amplifier module amplifies the acquired small voltage signal by specified times;

the sampling resistor converts small current signals collected by the multi-gear Hall sensor A and the multi-gear Hall sensor B into small voltage signals;

the AD conversion module converts the voltage signal amplified by the program control operational amplifier module into a digital signal and outputs the digital signal;

the bottom layer 32-bit microcomputer controls the data processing module A and the data processing module B to sample simultaneously, converts the digital signals output by the AD conversion module into data capable of being calculated and transmits the data to the embedded 32-bit microcomputer;

the embedded 32-bit microcomputer performs digital filtering, integral operation and error calculation on digital signals transmitted by the bottom layer 32-bit microcomputer to obtain the error of the to-be-measured broadband wide-range current transformer.

In the wide-band wide-range mutual inductor calibrator: the standard current signal passes through a standard current sampling loop consisting of a sampling resistor R1 and an operational amplifier A1, and a standard small voltage signal proportional to the standard current is output;

the measured current signal passes through a current sampling loop to be measured consisting of a sampling resistor R2 and an operational amplifier A2, and a measured small voltage signal proportional to the current to be measured is output.

The standard small voltage signal is converted into a standard digital signal through AD 1;

the small voltage signal to be measured is converted into a digital signal to be measured through AD 2.

The FPGA (bottom layer 32-bit microcomputer) controls the AD1 conversion module and the AD2 conversion module to sample simultaneously, reads the standard digital signal converted by the AD1 conversion module and the standard digital signal converted by the AD2 conversion module, converts the standard digital signal and the standard digital signal into an operational data format and sends the data format into the embedded 32-bit microcomputer. The operational data is processed by digital filtering, Fourier operation, error calculation and other processes in the embedded 32-bit microcomputer to obtain the error data of the tested mutual inductor, and the embedded 32-bit microcomputer finally sends the result and related data to the human-computer interface. And displaying relevant information such as the waveform, the effective value, the error and the like in a human-computer interface.

The further optimization scheme is that the AD conversion module outputs digital signals to the bottom layer 32-bit microcomputer through the SPI bus.

The further optimization scheme is that the sampling resistor is used for converting a standard small current signal/a small current signal to be detected into a standard small voltage signal/a small voltage signal to be detected and outputting the standard small voltage signal/the small voltage signal to be detected to the program control operational amplifier module, and the sampling resistor is a precise resistor with high precision and low temperature drift.

The multi-gear Hall sensor is composed of a selector switch and a broadband sensor, and the broadband sensor is provided with a plurality of input terminals;

the input end of the selector switch is connected with a standard transformer with wide frequency range or a current transformer with wide frequency range to be tested, and the output end of the selector switch is selectively connected with one input terminal of the wide frequency sensor.

The further optimization scheme is that the selector switch consists of a plurality of paths of large-current relays and a driving circuit thereof.

The selector switches K1 and K2 are composed of a plurality of paths of heavy current relays and driving circuits thereof, are used for accessing standard current signals, and connect the standard current signals to terminals of the broadband sensor according to control signals of an FPGA (bottom layer 32-bit microcomputer); the broadband sensor adopts a high-precision multi-gear Hall sensor module and is used for converting a standard current signal and outputting a proportional standard small current signal to the sampling resistor.

The further optimization scheme is that the wide-bandwidth range transformer calibrator further comprises a human-computer interaction module, and the human-computer interaction module is used for parameter setting and graph and data display.

The standard transformer with wide frequency range adopts zero-flux current transformer technology, and provides accuracy of not less than 0.05 level within the range of 0.1-200% of rated current.

The program control operational amplifier module adopts an operational amplifier with controllable amplification factor, amplifies the standard small voltage signal/small voltage signal to be detected by specified factor according to the control signal of the FPGA, and outputs the amplified signal to the AD module;

the AD module adopts a broadband and high-precision 24-bit ADC chip as a core device, and a high-precision analog-digital conversion circuit is formed by an auxiliary circuit such as a differential circuit, analog-digital conversion is carried out on a standard voltage signal/voltage signal to be detected output by the program control operation module according to a configuration instruction of an FPGA (bottom layer 32-bit microcomputer), and the standard voltage signal/voltage signal to be detected is converted into a digital signal through an SPI bus and is output to the bottom layer 32-bit microcomputer;

the FPGA (bottom 32-bit microcomputer) adopts an Intel high-performance FPGA chip, an AD module controller, an operational amplifier controller and a switch controller are generated in the FPGA by using a hardware description language and are used for controlling the working states of an AD1 module, an AD2 module, a selection switch K1, a selection switch K2, a program control operational amplifier module A1, a program control operational amplifier module A2 and the like and carrying out information interaction, preprocessing data obtained from the modules and carrying out data interaction with the embedded 32-bit microcomputer by using a parallel bus;

the embedded 32-bit microcomputer adopts an ARM chip of Italian semiconductor company, performs data interaction with the bottom layer 32-bit microcomputer through a parallel bus FSMC, performs operation processing on data according to instructions of a human-computer interaction module, and outputs operation results to the human-computer interaction module; a human-computer interaction module: and a windows operating system is adopted to provide a rich information display interface for parameter setting, graph and data display.

The invention also provides a corresponding method based on the error calibration system of the broadband wide-range current transformer, which comprises the following steps:

s1, enabling a broadband large-current generating device to provide working current for the primary side of a broadband wide-range current transformer to be tested and the primary side of a broadband wide-range standard transformer;

s2, collecting a standard current signal of a secondary side of a standard transformer and a current signal to be detected of the secondary side of the wide-bandwidth range current transformer to be detected by a wide-bandwidth wide-range transformer calibrator, and performing data preprocessing to obtain a digital signal capable of being calculated;

and S3, carrying out error calculation on the basis of the calculable digital signals by the wide-band wide-range transformer calibrator to obtain the error of the wide-band wide-range current transformer to be measured.

The working current of the existing current transformer calibrator is power frequency 50Hz, and the calibrator has good adaptability to the frequency near 50Hz, but can gradually decrease the low-frequency and high-frequency signals along with the frequency away from the power frequency adaptability, and the electricity passing rate gradually decreases to 0%; in the conventional current transformer calibrator, in order to improve the stability and accuracy of the calibrator, a multi-tap current transformer is usually adopted for a current input end of the calibrator. The frequency adaptability of the current transformer is poor, and high-frequency and low-frequency signals which are not 50Hz pass through the current transformer and are attenuated; the wide-band and wide-range current transformer adopts a Hall sensor manufactured by utilizing the Hall effect at the current input end, the output of the Hall sensor is only related to the magnitude of input current and is not related to frequency, so that the wide-band and wide-range current transformer calibrator has wide-band frequency adaptability, and the wide-band and wide-range transformer calibrator has good adaptability to direct current to high frequency.

The working current input range of the existing current transformer calibrator is usually 0-6A, and the calibration precision is difficult to guarantee under the condition of 0.001A current; the working current input range of the broadband wide-range transformer calibrator is larger than 0-10A, and the precision is still high at 0.001A.

In order to ensure the measurement accuracy of the existing current transformer calibrator, the current transformers are generally utilized to convert input currents of different sizes into current signals in a specified range, so that the input signals of a sampling system are kept in a certain range, and thus, sampling errors can be effectively reduced. The current transformer for the instrument is limited by the size, so that a plurality of taps cannot be arranged, the measurement range of the current transformer is limited, the signal top cutting can be caused by the overlarge input current, the sampling error of the undersize input current can be increased, and the precision cannot be guaranteed. The wide-bandwidth range current transformer calibrator adopts a multi-gear Hall device, and the sampling system also has range switching capability, so that the current measurement range is expanded, and the sampling precision of low-current signals is ensured.

Compared with the prior art, the invention has the following advantages and beneficial effects:

according to the error calibration system and method for the broadband wide-range current transformer, the broadband large current generating device provides working current for the primary side of the broadband wide-range current transformer to be tested and the primary side of the broadband wide-range standard transformer; the wide-bandwidth range transformer calibrator collects a standard current signal of a secondary side of a standard transformer and a current signal to be measured of the secondary side of a wide-bandwidth range current transformer to be measured, performs data preprocessing to obtain a digital signal capable of being calculated, and performs error calculation to obtain an error of the wide-bandwidth range current transformer to be measured. The wide-bandwidth range current transformer calibrator adopts a multi-gear Hall device, and the sampling system also has range switching capability, so that the current measurement range is expanded, the sampling precision of low-current signals is ensured, and the wide-range frequency adaptability is realized.

Drawings

The accompanying drawings, which are included to provide a further understanding of the embodiments of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the principles of the invention.

FIG. 1 is a schematic diagram of an error calibration system of the broadband wide-range current transformer according to the present invention;

FIG. 2 is a schematic diagram of the error calibration system of the broadband wide-range current transformer of the present invention;

FIG. 3 is a schematic diagram of a design of a broadband wide-range calibrator;

fig. 4 is a verification connection diagram of an error calibration system of the broadband wide-range current transformer according to the embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to examples and accompanying drawings, and the exemplary embodiments and descriptions thereof are only used for explaining the present invention and are not meant to limit the present invention.

Example 1

As shown in fig. 1, an error calibration system for a broadband wide-range current transformer includes: the system comprises a broadband wide-range standard transformer, a broadband large current generating device and a broadband wide-range transformer calibrator;

the wide-bandwidth range transformer calibrator consists of a multi-gear Hall sensor A, a multi-gear Hall sensor B, a wide-bandwidth and wide-range standard transformer, a data processing module A, a data processing module B and a calculation module;

the primary side of the broadband wide-range standard transformer and the primary side of the broadband wide-range current transformer to be tested are connected in series and then connected to two ends of the broadband large current generating device; the secondary side of the standard transformer with wide frequency and wide range is connected with a multi-gear Hall sensor A, and the secondary side of the current transformer with wide frequency and wide range to be tested is connected with a multi-gear Hall sensor B;

the multi-gear Hall sensor A collects a standard current signal of a secondary side of a broadband wide-range standard mutual inductor and converts the standard current signal to output a standard small current signal in proportion to the standard current signal; the multi-gear Hall sensor B collects a current signal to be measured at the secondary side of the wide-bandwidth range current transformer to be measured, and converts and outputs a small current signal to be measured in proportion to the current signal to be measured;

the data processing module A converts the standard small current signal into a standard small voltage signal, amplifies the standard small voltage signal, converts the standard small voltage signal into a digital signal and outputs the digital signal to the computing module; the data processing module B converts the small current signal to be detected into a small voltage signal to be detected, amplifies the small voltage signal and converts the small voltage signal to be detected into a digital signal to be output to the computing module;

and the calculation module performs error calculation based on the data output by the data processing module A and the data output by the data processing module B to obtain the error of the wide-bandwidth range current transformer to be measured.

As shown in fig. 2, the data processing module a or B includes: the circuit comprises a sampling resistor (a sampling resistor R1 and a sampling resistor R2), a program control operational amplifier module (A1 and A2), an AD conversion module (AD1 and AD2), a bottom layer 32-bit microcomputer and an embedded 32-bit microcomputer; the program control operational amplifier modules (A1 and A2) amplify the acquired small voltage signals by specified times;

the sampling resistor R1 converts a standard small current signal acquired by the multi-gear Hall sensor A into a standard small voltage signal, and the sampling resistor R2 converts a small current signal to be detected acquired by the multi-gear Hall sensor B into a small voltage signal to be detected;

the AD conversion module (module AD1 and module AD2) converts the voltage signal amplified by the program control operational amplifier module into a digital signal and outputs the digital signal;

the bottom layer 32-bit microcomputer controls the data processing module A and the data processing module B to sample simultaneously, converts the digital signals output by the AD conversion module into data capable of being calculated and transmits the data to the embedded 32-bit microcomputer;

the embedded 32-bit microcomputer performs digital filtering, integral operation and error calculation on digital signals transmitted by the bottom layer 32-bit microcomputer to obtain the error of the to-be-measured broadband wide-range current transformer.

The AD conversion module (module AD1 and module AD2) outputs digital signals to the bottom layer 32-bit microcomputer through the SPI bus.

The sampling resistors (the sampling resistor R1 and the sampling resistor R2) are precision resistors.

As shown in fig. 3, the multi-position hall sensor is composed of a selector switch and a broadband sensor, and the broadband sensor has 4 input terminals;

the input ends of the selector switch K1 and the selector switch K2 are connected with a broadband wide-range standard transformer or a to-be-tested wide-range current transformer, and the output ends of the selector switch K1 and the selector switch K2 are selectively connected with one input terminal of the broadband sensor.

The selector switches (K1 and K2) are composed of a multi-path high-current relay and a driving circuit thereof.

The wide-bandwidth range transformer calibrator further comprises a human-computer interaction module, and the human-computer interaction module is used for parameter setting and graph and data display.

Example 2

As shown in fig. 4, the programmable broadband large current generator is responsible for outputting a primary working current, the frequency range of the alternating current is 5Hz to 2kHz, the range of the output 50Hz fundamental wave alternating current is 0.1% to 200% of 600A, the current stability ensures the accuracy and stability of the measurement error, the output capacity of the programmable broadband large current generator is correspondingly reduced when each harmonic wave is output, and the output capacity of the 2kHz alternating current is not less than 60A.

The wide-band wide-range transformer calibrator adopts a difference measurement principle and is responsible for measuring the secondary current of a standard current transformer and the secondary side current of a current transformer to be measured and calculating the ratio difference and the phase difference of the current transformer to be measured, and the wide-band wide-range transformer calibrator adopts a Fourier algorithm to decompose an in-phase component and an orthogonal component without an orthogonal phase shifter.

The basic accuracy grade of the broadband wide-range transformer calibrator is 2 grades, in order to ensure the measurement of harmonic signals, the AD module in the broadband wide-range transformer calibrator adopts the technology of combining the variable sampling rate and the variable sampling point number, the measurement precision and the measurement speed are both met, when the fundamental wave error is measured, the sampling rate is 20k/s, and the sampling point number of each period reaches 400 points.

The broadband wide-range standard current transformer adopts a zero-flux current transformer technology, and provides accuracy of not less than 0.05 level within the range of 0.1-200% of rated current.

Example 3

When the multi-gear Hall sensor is set to be a selector switch with the same transformation ratio, the system can perform self calibration, and specific self calibration data (the precision level is 0.02) are shown in the following tables 1 and 2:

TABLE 1

TABLE 2

The error calibration system using the wide-bandwidth range current transformer is characterized in that the multi-gear Hall sensor is set to be in other gears, and data (with the precision level of 0.2) obtained by calibration based on a standard transformer are as follows in the following tables 3 and 4:

TABLE 3

TABLE 4

The error calibration system of the broadband wide-range current transformer can perform error calibration aiming at the situation that the rated current of the current transformer is 0.1% -200%, and both self calibration and standard current transformers can be realized.

The above-mentioned embodiments are intended to illustrate the objects, technical solutions and advantages of the present invention in further detail, and it should be understood that the above-mentioned embodiments are merely exemplary embodiments of the present invention, and are not intended to limit the scope of the present invention, and any modifications, equivalent substitutions, improvements and the like made within the spirit and principle of the present invention should be included in the scope of the present invention.

Claims (9)

1. The utility model provides a wide band wide range current transformer's error calibration system which characterized in that includes: the system comprises a broadband wide-range standard transformer, a broadband large current generating device and a broadband wide-range transformer calibrator;

the wide-bandwidth range transformer calibrator consists of a multi-gear Hall sensor A, a multi-gear Hall sensor B, a wide-bandwidth and wide-range standard transformer, a data processing module A, a data processing module B and a calculation module;

the primary side of the broadband wide-range standard transformer and the primary side of the broadband wide-range current transformer to be tested are connected in series and then connected to two ends of the broadband large current generating device; the secondary side of the standard transformer with wide frequency and wide range is connected with a multi-gear Hall sensor A, and the secondary side of the current transformer with wide frequency and wide range to be tested is connected with a multi-gear Hall sensor B;

the multi-gear Hall sensor A collects a standard current signal of a secondary side of a broadband wide-range standard mutual inductor and converts the standard current signal to output a standard small current signal in proportion to the standard current signal; the multi-gear Hall sensor B collects a current signal to be measured at the secondary side of the wide-bandwidth range current transformer to be measured, and converts and outputs a small current signal to be measured in proportion to the current signal to be measured;

the data processing module A converts the standard small current signal into a standard small voltage signal, amplifies the standard small voltage signal, converts the standard small voltage signal into a digital signal and outputs the digital signal to the computing module; the data processing module B converts the small current signal to be detected into a small voltage signal to be detected, amplifies the small voltage signal and converts the small voltage signal to be detected into a digital signal to be output to the computing module;

and the calculation module performs error calculation based on the data output by the data processing module A and the data output by the data processing module B to obtain the error of the wide-bandwidth range current transformer to be measured.

2. The system of claim 1, wherein the data processing module A or B comprises: the device comprises a sampling resistor, a program control operational amplifier module, an AD conversion module, a bottom layer 32-bit microcomputer and an embedded 32-bit microcomputer; the program control operational amplifier module amplifies the acquired small voltage signal by specified times;

the sampling resistor converts small current signals collected by the multi-gear Hall sensor A and the multi-gear Hall sensor B into small voltage signals;

the AD conversion module converts the voltage signal amplified by the program control operational amplifier module into a digital signal and outputs the digital signal;

the bottom layer 32-bit microcomputer controls the data processing module A and the data processing module B to sample simultaneously, converts the digital signals output by the AD conversion module into data capable of being calculated and transmits the data to the embedded 32-bit microcomputer;

the embedded 32-bit microcomputer performs digital filtering, integral operation and error calculation on digital signals transmitted by the bottom layer 32-bit microcomputer to obtain the error of the to-be-measured broadband wide-range current transformer.

3. The system of claim 2, wherein the AD converter module outputs the digital signal to the bottom 32-bit microcomputer via the SPI bus.

4. The system of claim 2, wherein the sampling resistor is a precision resistor.

5. The system of claim 1, wherein the multi-step hall sensor comprises a selector switch and a broadband sensor, the broadband sensor having a plurality of input terminals;

the input end of the selector switch is connected with a standard transformer with wide frequency range or a current transformer with wide frequency range to be tested, and the output end of the selector switch is selectively connected with one input terminal of the wide frequency sensor.

6. The system of claim 5, wherein the selector switch comprises a plurality of high current relays and a driving circuit thereof.

7. The system of claim 1, wherein the wide-band wide-range current transformer calibrator further comprises a human-machine interaction module for parameter setting, graphics and data display.

8. The system of claim 1, wherein the wide-bandwidth standard transformer uses zero-flux current transformer technology to provide no less than 0.05 level accuracy within 0.1% -200% of rated current.

9. An error calibration method of a broadband wide-range current transformer is characterized by comprising the following steps:

s1, enabling a broadband large-current generating device to provide working current for the primary side of a broadband wide-range current transformer to be tested and the primary side of a broadband wide-range standard transformer;

s2, collecting a standard current signal of a secondary side of a standard transformer and a current signal to be detected of the secondary side of the wide-bandwidth range current transformer to be detected by a wide-bandwidth wide-range transformer calibrator, and performing data preprocessing to obtain a digital signal capable of being calculated;

and S3, carrying out error calculation on the basis of the calculable digital signals by the wide-band wide-range transformer calibrator to obtain the error of the wide-band wide-range current transformer to be measured.

Images