CN111796176A - Thyristor converter valve base electronic equipment test system - Google Patents

Abstract

The invention discloses a testing system for valve base electronic equipment of a thyristor converter valve.A testing device provides a signal interface for tested valve base electronic equipment and judges whether the functions of the tested valve base electronic equipment are normal or not according to preset judgment logic; the testing device, the time synchronization device and the tested valve base electronic equipment are connected into a background communication network, the protocol conversion device converts various types of protocols, and the converted protocols are connected into a background workstation to form the communication network; the background workstation is provided with a human-computer interaction terminal, collects the running information of the accessed device through a communication network and provides a human-computer interaction function according to the collected information; the time synchronization device provides time synchronization signals with various protocols. The system can realize the comprehensive test of the valve base electronic equipment of the thyristor converter valve in the factory test stage, check whether the performance and the functional logic of the valve base electronic equipment meet the design requirements of the system before the field test, find and eliminate the fault of the tested equipment in time and improve the reliability of the valve base electronic equipment.

Description

Thyristor converter valve base electronic equipment test system

Technical Field

The invention belongs to the field of power systems and power electronics with thyristors as power devices, and particularly relates to a thyristor converter valve base electronic equipment test system.

Background

In the related engineering of a power system and power electronics, valve base electronic equipment plays a role in starting and stopping as an important component in a converter valve system. As shown in fig. 1, the valve-based electronic device pair is connected to the converter control unit for control signal interaction; the lower part of the converter is connected with the thyristor converter valve, receives voltage state feedback pulse sent by the thyristor converter valve through the interface optical fiber and sends trigger pulse to the thyristor converter valve, thereby realizing the control and monitoring functions of the thyristor.

In the actual engineering implementation process, an effective way for accessing the actual system to check the logic and the function of the valve-based electronic equipment before the valve-based electronic equipment leaves a factory is lacked. At present, the factory process is mainly used for testing a board card in the valve base electronic equipment, and the testing method can not provide the same signal type and logic combination of the upper interface and the lower interface as those of the field, and can not verify the function of the whole set of valve base electronic equipment. The complete set of valve base electronic equipment functions and the comprehensive verification of the upper interface and the lower interface can be completed only through joint debugging or even field debugging of a third party laboratory after leaving a factory, and at the moment, if the valve base electronic equipment finds a problem, the difficulty of solving the problem outside the factory is higher, and even the delay of the project period can be caused. At present, no in-plant test system suitable for valve base electronic equipment is available, the functions of an upper interface, a lower interface and the whole set of equipment of the whole set of valve base electronic equipment can be comprehensively tested before delivery, and the scheme is generated based on the requirement.

Disclosure of Invention

The invention aims to provide a testing system for valve-based electronic equipment of a thyristor converter valve, which can realize comprehensive testing of the valve-based electronic equipment of the thyristor converter valve in a factory testing stage, check whether the performance and functional logic of the valve-based electronic equipment meet the design requirements of the system before field testing, find and eliminate faults of the tested equipment in time and improve the reliability of the valve-based electronic equipment.

In order to achieve the above purpose, the solution of the invention is:

a valve base electronic equipment testing system for a thyristor converter valve comprises a background workstation, a network protocol conversion device, a time synchronization device and a testing device;

the testing device provides a signal interface for the tested valve-based electronic equipment and judges whether the function of the tested valve-based electronic equipment is normal or not according to preset judgment logic;

the testing device, the time synchronization device and the tested valve-based electronic equipment are connected to a background communication network, and are connected to a background workstation after passing through the network protocol conversion device, so that the communication network of the testing system is formed;

the background workstation is provided with a human-computer interaction terminal, the terminal collects the operation information of the accessed device through the communication network and provides human-computer interaction functions such as background remote control, alarm information uploading and the like according to the collected information;

the time synchronization device provides time synchronization signals of various protocols for other devices in the test system.

The testing device selects different modes, such as High Voltage Direct Current (HVDC), SFC, Static Var Compensation (SVC) and other modes, according to the application field of the tested valve base electronic equipment so as to adapt to the testing requirements of different valve base electronic equipment.

The test device simulates control signal interfaces of redundant converter control units, namely a control unit A and a control unit B, and the two control units ensure that one and only one control unit is in an on-duty state through an on-duty state signal.

The testing device provides simulation functions of the converter control units in different application fields, outputs different control signal combinations according to the change of testing conditions, and interacts control signals with the VBE device to be tested, wherein the testing conditions include but are not limited to converter valve charging, converter valve unlocking, converter control unit switching and the like.

The testing device has the function of simulating the interface signal of the thyristor converter valve, and the simulated converter valve sends voltage feedback pulse to the valve base electronic equipment and receives trigger pulse sent by the valve base electronic equipment according to the change of working conditions.

The testing device has the function of judging and outputting the running state of the VBE device to be tested, the input conditions required by the judging logic comprise the current selection mode of the testing device, the testing device sends a control signal and a voltage feedback signal to the valve base electronic equipment to be tested, the testing device receives a trigger pulse returned by the valve base electronic equipment to be tested, the judging logic is realized according to the combination relation programming of the signals in the actual engineering, and the running state of the VBE device to be tested is judged and output.

The testing device is connected to the background workstation through the communication network, on one hand, the testing device is controlled to select different testing modes and testing conditions through the human-computer interaction terminal of the background workstation, and on the other hand, running alarm information of the tested valve base electronic equipment device and running state information of the VBE device judged by the testing device are displayed and output through the human-computer interaction terminal.

The protocol conversion device converts various protocols adopted by the device in the test system, and the converted protocols are accessed to the background workstation, so that the running state of the device and the acquisition of alarm information are realized.

The background workstation is provided with the human-computer interaction terminal, the terminal can be compatible with communication protocols of various types of devices accessed by the protocol conversion device, the running state and alarm information of each device are output through a visual human-computer interaction interface, real-time monitoring of the test system is achieved, and meanwhile, monitoring data can also be reserved as test data.

After the scheme is adopted, the testing device is arranged to simulate the interaction control signal of the engineering field converter control unit and the tested valve base electronic equipment, meanwhile, the interaction converter valve interface signal of the engineering field thyristor converter valve and the valve base electronic equipment is simulated, the background workstation presents the operation alarm information of other devices connected into the network to the testing personnel through the human-computer interaction terminal through the protocol conversion device, and finally the testing personnel can judge the state of the tested system through the test information provided by the human-computer interaction terminal on the background workstation. The invention can comprehensively test the functions of the upper interface, the lower interface and the whole set of equipment of the thyristor converter valve base electronic equipment in a factory test stage, check whether the performance and the functional logic of the valve base electronic equipment meet the design requirements of a system or not before a field test, find and eliminate the faults of the tested equipment in time and improve the reliability of the valve base electronic equipment.

Drawings

FIG. 1 is a schematic diagram of an engineering field system architecture;

fig. 2 is a schematic diagram of the system architecture of the present invention.

Detailed Description

The technical solution and the advantages of the present invention will be described in detail with reference to the accompanying drawings.

As shown in fig. 2, the present invention provides a valve base electronic device (VBE for short) testing system for a thyristor converter valve, which includes a background workstation, a network protocol conversion device, a time synchronization device and a testing device, which are introduced below:

the testing device provides a signal interface for the tested valve base electronic equipment, and judges whether the function of the tested valve base electronic equipment is normal or not according to preset judgment logic, and the testing device can complete the function simulation of the redundant configuration mode converter valve control unit and realize the switching of the main mode and the standby mode.

The test device has the function of judging and outputting the running state of the VBE device to be tested, the input conditions required by the judgment logic comprise the current selection mode of the test device, the test device sends a control signal and a voltage feedback signal to the valve base electronic equipment to be tested, the test device receives a trigger pulse returned by the valve base electronic equipment to be tested, the judgment logic is realized according to the combination relation programming of the signals in the actual engineering, and the function of judging and outputting the running state of the VBE device to be tested is realized.

The testing device, the time synchronization device and the tested valve-based electronic equipment are connected to a background communication network, and are connected to a background workstation through the network protocol conversion device, so that the communication network of the testing system is formed.

The testing device is connected to the background workstation through the communication network, on one hand, the testing device is controlled to select different testing modes and testing conditions through the human-computer interaction terminal of the background workstation, and on the other hand, running alarm information of the tested valve base electronic equipment device and running state information of the VBE device judged by the testing device are displayed and output through the human-computer interaction terminal.

The protocol conversion device converts various types of protocols adopted by the device in the test system, and the converted protocols are accessed to the background workstation to realize the acquisition of the running state and the alarm information of the device.

The background workstation is provided with the human-computer interaction terminal, the terminal can be compatible with communication protocols of various types of devices accessed by the protocol conversion device, the operation information of the accessed devices is collected through the communication network, human-computer interaction functions such as background remote control, alarm information uploading and the like are provided according to the collected information, the operation state and the alarm information of each device are output through a visual human-computer interaction interface, the real-time monitoring of the test system is realized, and meanwhile, the monitoring data can also be reserved as test data.

The time synchronization device provides time synchronization signals of various protocols for other devices in the test system.

The testing device selects different modes, such as High Voltage Direct Current (HVDC), SFC, Static Var Compensation (SVC) and the like, according to different application fields of the VBE device to be tested so as to adapt to the testing requirements of different valve base electronic equipment. Taking the field of high-voltage/extra-high-voltage direct-current transmission as an example, after a high-voltage/extra-high-voltage direct-current transmission mode is selected, the test device sends control signals to the VBE device to be tested according to the characteristics of interface signals in the field, wherein the control signals comprise control pulse signals, duty state signals, unlocking state signals, charging state signals and the like; the interface signal sent between the VBE device to be tested and the converter valve is a voltage feedback signal of each stage of thyristor; the testing device receives a control signal of the VBE device to be tested as a normal VBE device and a tripping signal of the VBE device, and receives an interface signal between the VBE device to be tested and the converter valve as a trigger pulse signal of each stage of thyristor.

In order to simulate the signal characteristics of a redundancy control system, the A/B system control signals simulated by the testing device are characterized in that: and only one of the system A duty state signal and the system B duty state signal is in an effective state, and the other control signals, namely the system A and the system B, are in the same state.

In order to limit the timing relation of the signals, a voltage signal with a period of 20ms is calculated and generated in the test device as the timing reference of the signals.

According to the operation condition of a high-voltage/extra-high-voltage direct-current transmission site, the testing device simulates the following working conditions and outputs corresponding control signals:

(1) charging of converter valves

Under the working condition of charging of the converter valve, the state of a control signal sent by the testing device is that a charging state signal is valid, an unlocking state signal is invalid, the testing device simulates the converter valve to generate a forward voltage feedback signal when the phase of the synchronous voltage is 0 degree, and the simulation control device generates a control pulse signal when the phase of the synchronous voltage is 164 degrees, so that the control pulse signal lasts for 120 degrees of electrical angle.

(2) Converter valve unlocking

Under the working condition of converter valve unlocking, the state of a control signal sent by the testing device is that a charging state signal is effective, an unlocking state signal is effective, the tested VBE device simulates the converter valve to generate a forward voltage feedback signal when the synchronous voltage phase is 0 degrees, the simulation control device generates a control pulse signal when the synchronous voltage phase is 164 degrees, and the control pulse signal lasts for 120 degrees of electrical angle.

(3) System handover

Under the two working conditions, the VBE device to be tested simulates the effective switching of the duty signal of the system A to the effective duty signal of the system B, and then the duty signal of the system B is effectively switched to the effective duty signal of the system A.

According to the operation condition of the high-voltage/extra-high-voltage direct-current transmission site, the preset logic description of the test device for judging the operation state of the VBE device is as follows:

(1) charging of converter valves

Under the charging condition of the converter valve, the VBE to be tested receives an invalid unlocking state, and an effective trigger pulse signal is not required to be returned to the testing device; the measured VBE receives the effective charging state signal and the effective forward voltage feedback signal, the converter valve is judged to be normal, and a VBE tripping signal cannot be generated; therefore, the testing device detects that the VBE device to be tested does not return an effective trigger pulse signal in the whole charging test process, and the VBE device to be tested does not generate a positive voltage feedback signal abnormity and a VBE tripping signal, so that the VBE device can be judged to normally operate, and otherwise, the VBE device is judged to abnormally operate.

In the process of testing the charging condition of the converter valve, the measured VBE device does not generate a positive voltage feedback signal abnormity and a VBE tripping signal, and the measured VBE device does not generate abnormal alarm information.

(2) Converter valve unlocking

Under the working condition of converter valve unlocking, after the tested VBE receives an effective converter valve unlocking signal, an effective trigger pulse signal is returned to the testing device within a 120-degree interval in which the control signal is effective; meanwhile, the measured VBE receives an effective charging state signal and an effective forward voltage feedback signal, the converter valve is judged to be normal, and a VBE tripping signal cannot be generated; therefore, the testing device can receive the effective trigger pulse signal returned by the VBE device to be tested within 120-degree intervals in which the control signal is effective in the unlocking test process, and does not receive the effective trigger pulse signal returned by the VBE device to be tested within the intervals in which the control signal is ineffective, if the conditions are met, the VBE device is judged to be normally operated, and if the conditions are not met, the VBE device is judged to be abnormally operated.

In the process of the converter valve unlocking condition test, the measured VBE device should not generate a positive voltage feedback signal abnormity and a VBE tripping signal, and the measured VBE device should not generate abnormal alarm information.

(3) System handover

In the system switching process under two working conditions of a converter transformer charging state and a converter transformer unlocking state, the testing device judges that the preset logic of the VBE operation state maintains the principle unchanged; in the whole switching process, abnormal alarm information of the VBE device to be tested does not occur.

The testing device records the alarm information in the whole testing process and uploads the alarm information to the background workstation, meanwhile, the testing system can record various interface signals, and when the VBE device is judged to be abnormal in operation, the recording is automatically triggered and uploaded to the background workstation, so that a basis is provided for judging a specific abnormal position.

Protocol conversion device can satisfy the requirement that the VBE device under test who adopts multiple different communication protocols inserts communication network, including but not limited to Profibus bus, Modbus, IEC103 protocol, IEC61850 protocol etc. and VBE device under test can pass through protocol conversion access backstage workstation.

The background workstation is provided with a human-computer interaction terminal, the terminal outputs the running state and alarm information of the VBE device to be tested through the visual human-computer interaction terminal, and simultaneously outputs the running state information of the VBE device to be tested obtained by judging the testing device, so that the real-time monitoring of the testing system is realized, a tester can judge the running state of the VBE device to be tested through the information, and if abnormal information occurs, the fault condition of the VBE device to be tested can be comprehensively judged through the alarm information of the human-computer interaction terminal and a recording file of the testing device.

The above embodiments are only for illustrating the technical idea of the present invention, and the protection scope of the present invention is not limited thereby, and any modifications made on the basis of the technical scheme according to the technical idea of the present invention fall within the protection scope of the present invention.

Claims (8)

1. The utility model provides a thyristor converter valve base electronic equipment test system which characterized in that: the system comprises a background workstation, a network protocol conversion device, a time synchronization device and a test device;

the testing device provides a signal interface for the tested valve-based electronic equipment and judges whether the function of the tested valve-based electronic equipment is normal or not according to preset judgment logic;

the testing device, the time synchronization device and the tested valve base electronic equipment are connected to a background communication network, the protocol conversion device converts various types of protocols adopted by the testing device, the time synchronization device and the tested valve base electronic equipment, and the converted protocols are connected to a background workstation, so that the communication network of the testing system is formed;

the background workstation is provided with a human-computer interaction terminal, and the terminal collects the running information of the accessed device through the communication network and provides a human-computer interaction function according to the collected information;

the time synchronization device provides time synchronization signals of various protocols for other devices in the test system.

2. The thyristor converter valve base electronic device testing system of claim 1, wherein: the testing device selects different modes according to the application field of the tested valve base electronic equipment so as to adapt to the testing requirements of different valve base electronic equipment.

3. The thyristor converter valve base electronic device testing system of claim 1, wherein: the test device simulates control signal interfaces of redundant converter control units, namely a first control unit and a second control unit, and the two control units ensure that only one control unit is in an on-duty state through an on-duty state signal.

4. The thyristor converter valve base electronic device testing system of claim 1, wherein: the testing device provides simulation functions of the current converter control units in different application fields, outputs different control signal combinations according to the change of the testing working condition and interacts control signals with the tested valve base electronic equipment.

5. The thyristor converter valve base electronic device testing system of claim 4, wherein: the test working condition comprises converter valve charging, converter valve unlocking and converter control unit switching.

6. The thyristor converter valve base electronic device testing system of claim 1, wherein: the testing device has the function of simulating the interface signal of the thyristor converter valve, the simulated converter valve sends voltage feedback pulse to the tested valve base electronic equipment according to the change of working conditions, and receives trigger pulse sent by the tested valve base electronic equipment.

7. The thyristor converter valve base electronic device testing system of claim 1, wherein: the testing device has the functions of judging and outputting the running state of the tested valve-based electronic equipment, the input conditions required by the judgment logic comprise the current selection mode of the testing device, the testing device sends control signals and voltage feedback signals to the tested valve-based electronic equipment, the testing device receives trigger pulses returned by the tested valve-based electronic equipment, the judgment logic is realized according to the combination relation programming of the signals in the actual engineering, and the running state of the tested valve-based electronic equipment is judged and output.

8. The thyristor converter valve base electronic device testing system of claim 1, wherein: the testing device is connected to the background workstation through a communication network, on one hand, the testing device is controlled to select different testing modes and testing conditions through the human-computer interaction terminal of the background workstation, and on the other hand, running alarm information of the tested valve base electronic equipment and running state information of the valve base electronic equipment judged by the testing device are displayed and output through the human-computer interaction terminal.

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