CN201654153U - Live tester of zinc oxide arrester - Google Patents

Abstract

The utility model discloses a live tester of a zinc oxide arrester, which belongs to the instrument used for testing AC parameters in live operation of the metal oxide arrester in the power system. The live tester comprises a master machine and a slave machine, a current sensor lead wire, a current sensor unit, a program-controlled amplification unit, a current signal processing control unit and a wireless signal receiving module are connected in sequence and are then connected with an upper computer, and the upper computer is respectively connected with the current signal processing control unit, a liquid crystal display, a keyboard and a mouse, thereby forming the master machine; a voltage sensor lead wire, a voltage sensor unit, a voltage signal processing control unit and a wireless signal transmitting module are connected in sequence to form the slave machine; and the master machine and the slave machine transmit control signals and data through wireless communication. The utility model is applicable to periodic testing of the total leakage current, resistive current fundamental wave and triple-frequency harmonics of the operating metal oxide arrester to check the operating performance of the metal oxide arrester.

Description

Electrified tester for zinc oxide arrester

Technical field

The utility model relates to the instrument of a kind of Hyper-Voltage of Power Systems protection with the charged detection of metal oxide arrester, relates in particular to the realization of the charged detection of kind of Resistive Current of Metal Oxide Surge Arrester, wireless data transmission pattern and the signals collecting method of synchronization.

Background technology

Metal oxide arrester (MOA) has obtained using widely in electric system with its superior nonlinear characteristic.Because long-term work is under working voltage, and repeatedly bears various superpotential impacts, and valve block reason such as make moist, wear out, the lightning arrester overall performance descends gradually.At present, metal oxide arrester mainly is comprehensively to judge its operation characteristic by charged detection and offline inspection.

Detection methods such as total leakage current, resistive current first harmonics and third harmonic are adopted in the charged detection of existing metal oxide arrester mostly.But owing to often have certain distance, particularly leakage conductor etc. between voltage sensor and the current sensor, the interference that long distance field wiring is subjected to is very serious, and the field wiring workload is big especially.Still there is not the charged checkout equipment of convenient effective metal oxide arrester at present.

Summary of the invention

The purpose of this utility model just is to overcome the above-mentioned shortcoming and defect that prior art exists, provide a kind of metal oxide arrester charged detecting instrument based on wireless telecommunications, realization is to the synchronous acquisition of voltage signal and current signal, the wireless transmission of image data, accurately calculate the resistive current first harmonics and the triple harmonic current of metal oxide arrester, judge the operation characteristic of metal oxide arrester.

The purpose of this utility model is achieved in that

The utility model comprises main frame and two parts of slave, and its special character is that current sensor is positioned at main frame, and voltage sensor is positioned at slave.Current sensor and voltage sensor is arranged apart, slave sends synch command by wireless telecommunications, current sensor (main frame) and voltage sensor (slave) begin to gather simultaneously, and the data of its collection being sent to main frame by wireless telecommunications by slave, main frame shows after both data operations are handled in real time.

Voltage signal processing and control element (PCE), current signal processing and control element (PCE) are made up of A/D converter, field programmable gate array (FPGA), single-chip microcomputer (CPU) and random-access memory (ram).The signal that voltage sensor and current sensor collect is respectively behind overvoltage signal processing and control element (PCE) and current signal processing and control element (PCE), obtain the amplitude and the phase data of three-phase voltage and three-phase current respectively, deposit in the random access memory of corresponding voltage signal processing and control element (PCE) and current signal processing and control element (PCE).

Wireless sending module is made up of serial communication converter, signal modulating equipment and antenna, and wireless sending module links to each other with the voltage signal processing and control element (PCE); The wireless signal receiver module is made up of antenna, signal demodulating apparatus and serial communication converter, and the wireless signal receiver module links to each other with the current signal processing and control element (PCE).After data acquisition and storage are finished, after the amplitude and phase data modulation of wireless sending module with the three-phase voltage in the random access memory of voltage signal processing and control element (PCE), send by wireless telecommunications, the wireless signal receiver module with the signal demodulation process that receives after, be sent in the random access memory of current signal processing and control element (PCE).

The current signal processing and control element (PCE) links to each other by pci bus with host computer.The current signal processing and control element (PCE) all is sent to the three-phase voltage that obtains, the amplitude and the phase data of three-phase current in the host computer, after the host computer calculation process gained result is shown.

The utility model concrete structure annexation is:

Current sensor lead-in wire (3), current sensor unit (4), program control amplifying unit (5), current signal processing and control element (PCE) (6), wireless signal receiver module (7) link to each other successively, link to each other with host computer (8) again, host computer links to each other with current signal processing and control element (PCE) (6), LCD (9), keyboard (10), mouse (11) respectively, forms main frame (1); Voltage sensor lead wire (12), voltage sensor unit (13), voltage signal processing and control element (PCE) (14) and wireless signal transmitting module (15) link to each other successively, form slave (2); Main frame (1) and slave (2) are by wireless communication transmission control signal and data.

Current sensor unit (4) and voltage sensor unit (13) are made up of three induction voltage transformer (VT) of passive linear and three induction current transformers of passive linear respectively, and current sensor unit (4) link to each other with program control amplifying unit (5) with current sensor lead-in wire (3) respectively; Voltage sensor unit (13) links to each other with voltage signal processing and control element (PCE) (14) with voltage sensor lead wire (12) respectively.

Current signal processing and control element (PCE) (6) is connected A/D converter (6.1), programmable gate array FPGA (6.2), singlechip CPU (6.3), random access memory ram (6.4) respectively successively with voltage signal processing and control element (PCE) (14).

Described wireless signal receiver module (7) is made up of antenna (7.1), signal demodulating apparatus (7.2) and serial communication converter (7.4), and its wireless signal receiver module (7) is connected with current signal processing and control element (PCE) (6).

Described wireless sending module (15) is made up of serial communication converter (15.1), signal modulating equipment (15.2) and antenna (15.4), and its wireless sending module (15) is connected with the voltage signal processing and control element (PCE).

The control end of described program control amplifying unit (5) links to each other with the single-chip microcomputer (6.2) of current signal processing and control element (PCE) (6), and the data output end of program control amplifying unit (5) links to each other with the A/D converter (6.1) of current signal processing and control element (PCE) (6).

As shown from the above technical solution, when detected lightning arrester group (comprises A, B, when the lightning arrester of C three-phase) the three-phase high-voltage tape of upper end electricity normally moves, the voltage sensor lead wire of electrified tester for zinc oxide arrester slave is linked to each other with the PT secondary survey of this three-phase high-voltage electric wire, the current sensor lead-in wire of main frame links to each other with the low pressure end of detected lightning arrester group, and with the no-load voltage ratio parameter of PT input electrified tester for zinc oxide arrester, after pressing " beginning " test button, electrified tester for zinc oxide arrester is finished this test automatically, and shows total leakage current of lightning arrester in real time, resistive current first harmonics, third harmonic etc.

The utility model has following advantage and good effect compared with prior art:

1. realize the long-distance transmissions of data by wireless telecommunications, simplified on-the-spot wiring, increased the detectable metal oxide arrester scope of tester;

2. realize the data synchronization collection, improved the precision of measuring resistive current first harmonics and third harmonic;

3. adopt complete data acquisition process and the full automation control technology of a cover, guarantee that whole measuring process finishes automatically; Realize man-machine interaction by host computer, easy to operate simple;

4. the utility model is applicable to that rules require the charged detection of total leakage current, resistive current first harmonics and third harmonic that the metal oxide arrester that has come into operation is regularly carried out, and check the runnability of metal oxide arrester.

Description of drawings

Fig. 1 is the utility model block scheme;

Fig. 2 is the block diagram of main frame (1);

Fig. 3 is the block diagram of slave (2);

Fig. 4 is the block diagram of current signal processing and control element (PCE) (6) and voltage signal processing and control element (PCE) (14);

Fig. 5 is wireless signal receiver module (a 7) block diagram;

Fig. 6 is wireless sending module (a 15) block diagram;

Wherein:

The 1-main frame;

The 2-slave;

3-current sensor lead-in wire;

4-current sensor unit;

The program control amplifying unit of 5-;

6-current signal processing and control element (PCE);

6.1-A/D converter, 6.2-field programmable gate array (FPGA),

6.3-single-chip microcomputer (CPU), the 6.4-random-access memory (ram);

7-wireless signal receiver module;

7.1-antenna, the 7.2-signal demodulating apparatus,

7.3-serial communication converter;

The 8-host computer;

The 9-LCD;

The 10-keyboard;

The 11-mouse;

The 12-voltage sensor lead wire;

13-voltage sensor unit;

14-voltage signal processing and control element (PCE);

15-wireless signal sending module,

15.1-the serial communication converter, the 15.2-signal demodulating apparatus,

15.3-antenna.

Embodiment

Below in conjunction with accompanying drawing and example in detail:

One, general structure

As Fig. 1, the utility model comprises main frame (1) and slave (2).Main frame (1) and slave (2) are powered by power supply separately, and realize data transmission by wireless telecommunications.

As Fig. 2, current sensor unit (4), program control amplifying unit (5), current signal processing and control element (PCE) (6), wireless signal receiver module (7) link to each other successively, link to each other with host computer (8) again, host computer links to each other with current signal processing and control element (PCE) (6), LCD (9), keyboard (10), mouse (11) respectively, forms main frame (1);

As Fig. 3, voltage sensor unit (13), voltage signal processing and control element (PCE) (14) link to each other successively with wireless signal transmitting module (15), form slave (2).

Principle of work of the present utility model is:

When the three-phase high-voltage tape electricity of detected lightning arrester group (lightning arrester that comprises A, B, C three-phase) upper end normally moves, measure three-phase voltage and the amplitude and the phase place that flow through the electric current of three lightning arresters respectively, by the software processes computing, respectively total leakage current, the first-harmonic of current in resistance property, the third harmonic of three lightning arresters shown respectively again.

The voltage sensor lead wire (12) of electrified tester for zinc oxide arrester slave (2) is linked to each other with the PT secondary survey of this three-phase high-voltage electric wire, the current sensor lead-in wire (3) of main frame (1) links to each other with the low pressure end of detected lightning arrester group, and with the no-load voltage ratio parameter of PT input electrified tester for zinc oxide arrester, after pressing " beginning " test button, electrified tester for zinc oxide arrester begins to carry out the measurement of three-phase voltage, three-phase current.

Current signal processing and control element (PCE) (6), voltage signal processing and control element (PCE) (14) are formed by A/D converter (6.1), field programmable gate array (FPGA) (6.2), single-chip microcomputer (CPU) (6.3) and random-access memory (ram) (6.4).The signal that voltage sensor unit (13) and current sensor unit (4) collect is respectively behind overvoltage signal processing and control element (PCE) (14) and current signal processing and control element (PCE) (6), obtain the amplitude and the phase data of three-phase voltage, three-phase current respectively, deposit in the random access memory of corresponding voltage signal processing and control element (PCE) (14) and current signal processing and control element (PCE) (6).

Wireless sending module (15) is made up of serial communication converter (15.1), signal modulating equipment (15.2) and antenna (15.3), and wireless sending module (15) links to each other with voltage signal processing and control element (PCE) (14); Wireless signal receiver module (7) is made up of antenna (7.1), signal demodulating apparatus (7.2) and serial communication converter (7.3), and wireless signal receiver module (7) links to each other with current signal processing and control element (PCE) (6).After data acquisition and storage are finished, after the amplitude and phase data modulation of wireless sending module (15) with the three-phase voltage in the random access memory of voltage signal processing and control element (PCE) (14), send by wireless telecommunications, wireless signal receiver module (7) is with the modulated signal that receives, after the demodulation process, be sent in the random access memory (6.4) of current signal processing and control element (PCE) (6).

Current signal processing and control element (PCE) (6) links to each other by pci bus with host computer (8).Current signal processing and control element (PCE) (6) all is sent to the three-phase voltage that obtains, the amplitude and the phase data of three-phase current in the host computer, after the host computer calculation process gained result is shown.

Two, each functional block structure

1, current sensor unit (4) and voltage sensor unit (13)

Current sensor unit (4) and voltage sensor unit (13) are made up of three induction voltage transformer (VT) of passive linear and three induction current transformers of passive linear respectively.Current sensor unit (4) links to each other with program control amplifying unit (5) with current sensor lead-in wire (3) respectively; Voltage sensor unit (13) links to each other with voltage signal processing and control element (PCE) (14) with voltage sensor lead wire (12) respectively.

Its principle of work is: with voltage signal in the three-phase high-voltage electric wire and the current signal that flows through three lightning arresters, dwindle or be amplified to suitable size by voltage sensor unit (13) and current sensor unit (4), the A/D converter of being convenient to voltage signal processing and control element (PCE) (14) and current signal processing and control element (PCE) (6) carries out analog to digital conversion.

2, program control amplifying unit (5)

Program control amplifying unit (5) is made up of the program control amplification chip of a Gain Adjustable.The control end of program control amplifying unit (5) links to each other with the single-chip microcomputer (6.2) of current signal processing and control element (PCE) (6), and the data output end of program control amplifying unit (5) links to each other with the A/D converter (6.1) of current signal processing and control element (PCE) (6).

Its principle of work is: the initial gain multiple of program control amplifying unit (5) is 1, carry out the pre-collection of current signal by current signal processing and control element (PCE) (6), calculate the maximal value of the data that collect by the single-chip microcomputer (6.3) of current signal processing and control element (PCE) (6), the gain multiple of controlling program control amplifying unit (5) thus is 1,2,4,8,16 times, the little current signal gain of input is amplified, carry out collection, processing and the calculating of data again, thereby improved the precision of measuring.

3, current signal processing and control element (PCE) (6) is identical with voltage signal processing and control element (PCE) (14) structure with voltage signal processing and control element (PCE) (14) current signal processing and control element (PCE) (6), as Fig. 4, form by A/D converter (6.1), field programmable gate array (FPGA) (6.2), single-chip microcomputer (CPU) (6.3) and random-access memory (ram) (6.4).A/D converter (6.1), field programmable gate array (FPGA) (6.2), single-chip microcomputer (CPU) (6.3) and random-access memory (ram) (6.4) link to each other successively.

Described A/D converter (6.1) is made up of the A/D conversion chip of 14 in one 8 passage; Described field programmable gate array (FPGA) (6.2) is made up of a fpga chip and the coupled outer EPROM of sheet; Described single-chip microcomputer (CPU) (6.3) is made up of a slice 8051 series monolithics; Described random-access memory (ram) (6.4) is made up of the random-access memory (ram) chip of the outer 128K of sheet.

Its principle of work is: the action of current signal processing and control element (PCE) (6) and voltage signal processing and control element (PCE) (14) comprises that signals collecting, data operation are handled, data send and Data Receiving.

When signal processing control unit is carried out signals collecting, earlier send the beginning acquisition to field programmable gate array (FPGA) (6.2) by single-chip microcomputer (CPU) (6.3), field programmable gate array (FPGA) (6.2) control A/D converter (6.1) begins to carry out analog to digital conversion, the resulting data of A/D converter (6.1) (digital quantity) are deposited in the random-access memory (ram) (6.4) through field programmable gate array (FPGA) biography.

When signal processing control unit is carried out the data operation processing, single-chip microcomputer (CPU) (6.3) calls random-access memory (ram) (6.4) and carries out data computation according to the computing formula of programming, and the result who obtains is finished in calculating deposits in the random-access memory (ram) (6.4).

When voltage signal processing and control element (PCE) (14) carries out the data transmission, send data read command by single-chip microcomputer (CPU) to field programmable gate array (FPGA), on-the-spot single-chip microcomputer (CPU) sends to the data in the random-access memory (ram) in the voltage signal processing and control element (PCE) (14) the serial communication converter (15.1) of wireless signal sending module (15) through the parallel port.

When current signal processing and control element (PCE) (6) carries out Data Receiving, send the data access order by single-chip microcomputer (CPU) (6.3) to field programmable gate array (FPGA) (6.2), single-chip microcomputer (CPU) (6.3) receives its parallel port from the serial communication converter (7.4) of wireless signal sending/receiving module (7) data deposit in the random-access memory (ram) (6.4) the current signal processing and control element (PCE) (6).

4, wireless signal receiver module (7) and wireless signal sending module (15)

As Fig. 5, wireless signal receiver module (7) is linked to each other successively by antenna (7.1), signal demodulating apparatus (7.2) and serial communication converter (7.3), and serial communication converter (7.3) is connected to form with the single-chip microcomputer of current signal processing and control element (PCE) (6) again.As Fig. 6, wireless signal sending module (15) is linked to each other successively by serial communication converter (15.1), signal modulating equipment (15.2) and antenna (15.3), and serial communication converter (15.1) is connected to form with the single-chip microcomputer of voltage signal processing and control element (PCE) (14) again.

Described serial communication converter (7.3) (15.1) is made up of monolithic chip RS485 respectively; Described signal demodulating apparatus (7.2) and signal modulating equipment (15.2) are made up of monolithic wireless receiving and dispatching one chip, and this chip can carry out high-frequency emission, high frequency reception, FSK modulation, FM modulation etc.The described antenna of wireless signal sending module (15) (7.1) (15.4) is made up of radio-frequency antenna.

Its principle of work is: this wireless receiving and dispatching one chip can be operated in high-frequency emission (i.e. modulation) pattern, also can be operated in high frequency and receive (being demodulation) pattern, the signal modulating equipment (15.2) of wireless signal sending module (15) is operated in the high-frequency emission pattern, and the signal demodulating apparatus (7.2) of wireless signal receiver module (7) is operated in the high frequency receiving mode.

Wireless signal receiver module (7) and wireless signal sending module (15) carry out the amplitude that signals collecting synch command, three-phase voltage are arranged and the phase data of wireless communication transmission.

When the transmission of signals collecting synch command is carried out in wireless telecommunications, the single-chip microcomputer of voltage signal processing and control element (PCE) (14) sends the synchronous acquisition order, control the collection of voltage signal on the one hand by voltage signal processing and control element (PCE) (14), single-chip microcomputer by voltage signal processing and control element (PCE) (14) is converted into the external random access storer (RAM) that numerical coding is stored in voltage signal processing and control element (PCE) (14) with this synch command on the other hand, and the serial communication converter (15.1) of this numerical coding by wireless signal sending module (15) is converted into serial ports outputs to signal modulating equipment (15.2), the synchronous acquisition order that signal modulating equipment (15.2) will have been modulated again is by the outside high-frequency emission of antenna (15.3).After the antenna (7.1) of wireless signal receiver module (7) receives this synchronous acquisition order, be demodulated into numerical coding by signal demodulating apparatus (7.2), this numerical coding enters the external random access storer (RAM) (6.4) of current signal processing and control element (PCE) (6) by the serial communication converter (7.3) of wireless signal receiver module (7), the single-chip microcomputer (CPU) (6.3) of current signal processing and control element (PCE) (6) recognizes the synchronous acquisition command code, i.e. the synchronous acquisition of Control current signal.

When the amplitude of three-phase voltage and phase data transmission are carried out in wireless telecommunications, the single-chip microcomputer of voltage signal processing and control element (PCE) (14) sends data transfer command, to be stored in the serial communication converter (15.1) of data by wireless signal sending module (15) in the external random access storer (RAM) of voltage signal processing and control element (PCE) (14) by the single-chip microcomputer (CPU) of voltage signal processing and control element (PCE) (14) and be converted into serial ports and output to signal modulating equipment (15.2), the amplitude of the three-phase voltage that signal modulating equipment (15.2) will have been modulated again and phase data are by the outside high-frequency emission of antenna (15.3).After the antenna (7.1) of wireless signal receiver module (7) receives the amplitude and phase data of this three-phase voltage, be demodulated into numerical coding by signal demodulating apparatus (7.2), this numerical coding enters the external random access storer (RAM) (6.4) of current signal processing and control element (PCE) (6) by the serial communication converter (7.3) of wireless signal receiver module (7), and the single-chip microcomputer (CPU) (6.3) of current signal processing and control element (PCE) (6) calls this partial data when carrying out data processing operation.

5, host computer (8)

Host computer (8) is made up of industrial control computer (industrial computer).Host computer (8) links to each other with current signal processing and control element (PCE) (6), LCD (9), keyboard (10) and mouse (11) respectively.

Its principle of work is: link to each other with current signal control module (6) by pci bus, realize the transmission of data and human-computer interactive control signal.

Claims (6)

1. electrified tester for zinc oxide arrester, comprise (2) two parts of main frame (1) and slave, main frame is made up of current sensor lead-in wire (3), current sensor unit (4), program control amplifying unit (5), current signal processing and control element (PCE) (6), wireless signal receiver module (7), host computer (8), LCD (9), keyboard (10), mouse (11); Slave is made up of voltage sensor lead wire (12), voltage sensor unit (13), voltage signal processing and control element (PCE) (14) and wireless signal transmitting module (15), it is characterized in that: current sensor lead-in wire (3), current sensor unit (4), program control amplifying unit (5), current signal processing and control element (PCE) (6), wireless signal receiver module (7) link to each other successively, link to each other with host computer (8) again, host computer links to each other with current signal processing and control element (PCE) (6), LCD (9), keyboard (10), mouse (11) respectively, forms main frame (1); Voltage sensor lead wire (12), voltage sensor unit (13), voltage signal processing and control element (PCE) (14) and wireless signal transmitting module (15) link to each other successively, form slave (2); Main frame (1) and slave (2) are by wireless communication transmission control signal and data.

2. by the described a kind of electrified tester for zinc oxide arrester of claim 1, it is characterized in that: current sensor unit (4) and voltage sensor unit (13) are made up of three induction voltage transformer (VT) of passive linear and three induction current transformers of passive linear respectively, and current sensor unit (4) link to each other with program control amplifying unit (5) with current sensor lead-in wire (3) respectively; Voltage sensor unit (13) links to each other with voltage signal processing and control element (PCE) (14) with voltage sensor lead wire (12) respectively.

3. by the described a kind of electrified tester for zinc oxide arrester of claim 1, it is characterized in that: current signal processing and control element (PCE) (6) is connected A/D converter (6.1), programmable gate array FPGA (6.2), singlechip CPU (6.3), random access memory ram (6.4) respectively successively with voltage signal processing and control element (PCE) (14).

4. by the described a kind of electrified tester for zinc oxide arrester of claim 1, it is characterized in that: described wireless signal receiver module (7) is made up of antenna (7.1), signal demodulating apparatus (7.2) and serial communication converter (7.4), and its wireless signal receiver module (7) is connected with current signal processing and control element (PCE) (6).

5. by the described a kind of electrified tester for zinc oxide arrester of claim 1, it is characterized in that: described wireless sending module (15) is made up of serial communication converter (15.1), signal modulating equipment (15.2) and antenna (15.4), and its wireless sending module (15) is connected with the voltage signal processing and control element (PCE).

6. the described a kind of electrified tester for zinc oxide arrester of claim 1, it is characterized in that: the control end of described program control amplifying unit (5) links to each other with the single-chip microcomputer (6.2) of current signal processing and control element (PCE) (6), and the data output end of program control amplifying unit (5) links to each other with the A/D converter (6.1) of current signal processing and control element (PCE) (6).

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