CN214380071U - Overvoltage protection system and device based on polarity characteristics of bus and outgoing line - Google Patents

Abstract

The utility model relates to an overvoltage protection system and device based on generating line and the polarity characteristic of being qualified for the next round of competitions. An overvoltage protection system based on bus and outlet polarity characteristics comprises a voltage acquisition module, a current acquisition module, a calculation module and a control module; the voltage acquisition module is used for acquiring voltage data of a phase line and a zero sequence line in a distribution line and transmitting the voltage data to the calculation module; the current acquisition module is used for acquiring outlet zero sequence current data of a distribution line and transmitting the outlet zero sequence current data to the calculation module; and the computing module is used for judging the state of the distribution line according to the voltage data and the outgoing line zero sequence current data and driving the control module to execute protection operation. The utility model provides an overvoltage protection system can acquire overvoltage state data through the voltage data acquisition of voltage acquisition module, cooperation calculation module, and then uses control module to carry out the overvoltage protection operation.

Description

Overvoltage protection system and device based on polarity characteristics of bus and outgoing line

Technical Field

The present invention relates to electronic devices, and more particularly to an overvoltage protection system and apparatus based on bus and line polarity characteristics.

Background

Under the operation mode of a 6-10 kV distribution network neutral point ungrounded system, single-phase grounding, intermittent grounding, ferromagnetic resonance and load breaking operation can cause distribution line overvoltage. Because of the overvoltage of the circuit, the insulation of the electrical equipment in the operation of the power system is damaged, the service life of the equipment is shortened, even the electrical equipment is damaged, and a worse power grid accident is caused, therefore, the fault source causing the overvoltage is identified by a technical means, so that the fault is quickly removed, and the safety operation of the power distribution equipment is very necessary to be ensured.

The current scheme of line overvoltage protection mainly comprises: (1) aiming at power frequency overvoltage, a shunt reactor or a reactive power compensation device and the like can be arranged on the line to limit the power frequency overvoltage, and the shunt reactor can be arranged at the tail end, the middle part or the head end of the line. (2) For single-phase grounding and intermittent grounding, the neutral point can reduce the amplitude of overvoltage by adopting a mode of grounding an arc suppression coil series resistor so as to realize overvoltage protection. The main problems with these solutions are: the reactor is additionally arranged, a large amount of equipment needs to be additionally arranged on each line, engineering construction is very complicated, a fault source causing overvoltage cannot be identified, and implementation is not facilitated; the grounding mode of the series resistor of the arc suppression coil can reduce the overvoltage amplitude to a certain extent, but overvoltage hazards and hidden dangers still exist, and an overvoltage fault source cannot be judged and identified.

Patent document No. CN201310660004.8 discloses an active voltage-regulating arc extinction voltage-limiting protection device for a small-current grounding system, which includes an intelligent controller and an active voltage-regulating component, where the intelligent controller is used to monitor each phase voltage and zero sequence voltage of a power supply system in real time, and when a single-phase grounding fault occurs in the power supply system, controls the conduction and conduction rate of the active voltage-regulating component, and connects a grounding fault phase in a superior outlet cabinet cable with the system ground through the active voltage-regulating component; the active voltage regulating assembly is used for regulating the voltage of a fault phase to ground, so that the voltage of the fault phase is lower than the insulation withstand voltage of a fault point, the discharge of the fault point to the ground is eliminated, the damage of arc light overvoltage to the operation of a power supply system is avoided, and the protection state is automatically exited after the insulation of the fault point is recovered. The above problems have not yet been solved.

Therefore, the existing distribution line overvoltage protection technology has defects and needs to be improved and enhanced.

SUMMERY OF THE UTILITY MODEL

In view of the above-mentioned deficiencies of the prior art, it is an object of the present invention to provide an overvoltage protection system and apparatus based on bus and outgoing line polarity characteristics for solving the technical problems mentioned in the background art.

In order to achieve the purpose, the utility model adopts the following technical proposal:

an overvoltage protection system based on bus and outlet polarity characteristics comprises a voltage acquisition module, a current acquisition module, a calculation module and a control module;

the voltage acquisition module is used for acquiring voltage data of a phase line and a zero sequence line in a distribution line and transmitting the voltage data to the calculation module;

the current acquisition module is used for acquiring outlet zero sequence current data of a distribution line and transmitting the outlet zero sequence current data to the calculation module;

the computing module is used for judging the state of a distribution line according to the voltage data and the outgoing line zero sequence current data and driving the control module to execute protection operation;

and the control module is connected with the circuit breaker in the distribution line and controls the opening and closing of the circuit breaker.

Preferably, the overvoltage protection system based on the polarity characteristics of the bus and the outgoing line further comprises a communication module; the communication module is connected with the calculation module and uploads alarm information or trip information or line fault information to a server.

Preferably, the overvoltage protection system based on the polarity characteristics of the bus and the outgoing line is characterized by further comprising an alarm module; the alarm module is connected with the control module and used for displaying local alarm information.

Preferably, the overvoltage protection system based on the polarity characteristics of the bus and the outgoing line further comprises a clock synchronization module for synchronizing time; the sampling frequency of the voltage acquisition module and the current acquisition module is 12.8 kHz.

The overvoltage protection device based on the polarity characteristics of the bus and the outgoing line of the overvoltage protection system based on the polarity characteristics of the bus and the outgoing line is used for realizing the overvoltage protection of a distribution line.

Compared with the prior art, the utility model provides an overvoltage protection system and device based on generating line and the polarity characteristic of being qualified for the next round of competitions has following beneficial effect:

1) the utility model provides an overvoltage protection system can coordinate the calculation module to acquire overvoltage state data through the voltage data acquisition of the voltage acquisition module, and then uses the control module to carry out overvoltage protection operation, and can effectively ensure the safe operation of distribution equipment in the distribution line;

2) the utility model provides an overvoltage protection system adopts the utility model provides an overvoltage protection method can acquire the trouble source circuit of overvoltage fault fast to the accurate trouble source circuit that cuts off, in external warning message, also have corresponding and relevance.

Drawings

Fig. 1 is a block diagram of an overvoltage protection system based on bus and outgoing line polarity characteristics according to the present invention;

fig. 2 is a block diagram of bus access and outlet structure of the overvoltage protection system based on the polarity characteristics of the bus and the outlet;

fig. 3 is a schematic diagram of a circuit that operates normally in the overvoltage protection system provided by the present invention;

fig. 4 is a schematic diagram of an overvoltage fault occurring on a distribution line in the overvoltage protection system provided by the present invention;

fig. 5 is a flow chart of the overvoltage protection method based on the polarity characteristics of the bus and the outgoing line provided by the present invention;

fig. 6 is a flow chart of the overvoltage protection operation provided by the present invention;

fig. 7 is a flowchart illustrating the start of the overvoltage protection operation provided by the present invention.

Detailed Description

In order to make the objects, technical solutions and effects of the present invention clearer and clearer, the following description of the present invention will refer to the accompanying drawings and illustrate embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

It is to be understood by one of ordinary skill in the art that the foregoing general description and the following detailed description are exemplary and explanatory of specific embodiments of the invention, and are not intended as limitations on the invention.

The terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process or method that comprises a list of steps does not include only those steps, but may include other steps not expressly listed or inherent to such process or method. Also, without further limitation, one or more devices or subsystems, elements or structures or components beginning with "comprise. The appearances of the phrases "in one embodiment," "in another embodiment," and similar language throughout this specification may, but do not necessarily, all refer to the same embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Referring to fig. 1-4, the present invention provides an overvoltage protection system based on the polarity characteristics of bus and outgoing line, which includes a voltage collecting module 1, a current collecting module 2, a calculating module 3, and a control module 4;

the voltage acquisition module 1 is used for acquiring voltage data of a phase line and a zero sequence line in a distribution line and transmitting the voltage data to the calculation module 3; specifically, the voltage acquisition module 1 is configured to acquire voltage data of an accessed multi-segment distribution line bus, in this embodiment, the voltage acquisition module 1 is connected to two segments of buses, I segment of bus and II segment of bus, and is configured to detect distribution voltages of the I segment of bus and the II segment of bus, and specifically, the voltage acquisition module acquires Ua _1, Ub _1, Uc _1, U0_1 of the I segment of bus and Ua _2, Ub _2, Uc _2, U0_2 of the II segment of bus and transmits the acquired voltage data to the calculation module 3. It should be noted that Ua, Ub, Uc, U0 in each bus section are identical distribution lines (lines 1-6 in the figure) including three-phase lines.

The current acquisition module 2 is used for acquiring outgoing line zero sequence current data of a distribution line and transmitting the outgoing line zero sequence current data to the calculation module 3; in this embodiment, the current collection module 2 is configured to collect the zero sequence current I0 of the outgoing line of the distribution line, and the number of the zero sequence currents that can be detected is not limited, and is preferably zero sequence current I0 that supports collection of 2 to 30 loops. It should be noted that the zero-sequence current data of the outgoing lines detected by the current acquisition module 2 correspond to the voltage data detected by the voltage acquisition module 1, that is, each distribution line has a zero-sequence outgoing line, and can detect a zero-sequence current, for example, in this embodiment, voltage data Ua _1 in the I-section bus corresponds to the outgoing line zero-sequence current I01, voltage data Ua _2 in the I-section bus corresponds to the outgoing line zero-sequence current I02, voltage data Ua _3 in the I-section bus corresponds to the outgoing line zero-sequence current I03, voltage data Ua _1 in the II-section bus corresponds to the outgoing line zero-sequence current I04, voltage data Ua _2 in the II-section bus corresponds to the outgoing line zero-sequence current I05, and voltage data Ua _3 in the II-section bus corresponds to the outgoing line zero-sequence current I06; of course, when a new bus is connected, the bus can be arranged in sequence, or other arrangement rules can be adopted. In the following calculation in this embodiment, the above correspondence is adopted.

Preferably, the voltage acquisition module 1 and the current acquisition module 2 use acquisition devices commonly used in the art, for example, a voltage sensor and a current transformer are correspondingly used, in implementation, the same sampling frequency is used for sampling, and the sampling time is the same, so as to ensure the correlation of data, in this embodiment, the sampling frequency for each cycle of the analog quantity is 256 points, that is, the sampling frequency is 12.8 kHz.

The calculation module 3 is configured to determine a distribution line state according to the voltage data and the outgoing line zero sequence current data, and drive the control module 4 to perform a protection operation; specifically, the calculation module 3 is preferably an MCU (Microcontroller Unit), receives the voltage data of all the distribution lines (lines 1-6) transmitted by the voltage acquisition module 1 and the corresponding outgoing line zero-sequence current data transmitted by the current acquisition module 2, and is capable of determining the overvoltage (in a general embodiment, a common method in the field is used for determining the overvoltage, and the detected voltage data may be larger than a set voltage value or other determination methods, which is not limited by the present invention) and determining a specific overvoltage line (in a general embodiment, a common determination method in the field may be used, which is not limited by the present invention), and then driving the control module 4 to perform subsequent protection operations according to the overvoltage fault and the determined fault line.

And the control module 4 is connected with the circuit breaker in the distribution line and controls the opening and closing of the circuit breaker. The control module 4 is preferably an MCU, and may have a certain working mode built therein, and start the corresponding working module according to the instruction of the computing module 3, or of course, drive the circuit breaker and other devices only according to the driving instruction of the computing module 3.

As a preferred solution, in this embodiment, the distribution line overvoltage protection system further includes a power module (not labeled) configured to supply power to the system, specifically to supply power to the computing module 3, preferably to a dc power supply adapted to a voltage of the corresponding MCU, and may be a storage battery or an ac-to-dc power supply.

The utility model provides a distribution lines overvoltage protection system can confirm the circuit that has overvoltage fault simultaneously through judging whether there is overvoltage, through the circuit breaker of the corresponding circuit of control module 4 drive opens circuit, prevents other circuit faults that overvoltage fault leads to. The overvoltage protection device monitors the voltage change of the power grid, identifies the type of the overvoltage once the overvoltage occurs, judges the overvoltage fault source, and trips and cuts off or alarms the fault source according to the type of the overvoltage and the severity of the overvoltage fault so as to ensure that the voltages of other normal areas of the power grid are recovered to be normal and operate safely.

Correspondingly, please refer to fig. 5-7, the present invention further provides a distribution line overvoltage protection method using the overvoltage protection system based on the polarity characteristics of the bus and the outgoing line, comprising the steps of:

obtaining the variation of the transient zero-sequence voltage of the bus in the distribution line and the variation of the transient zero-sequence current of the outgoing line, and further obtaining the polarity characteristics of the distribution line;

specifically, after the overvoltage protection is started, the calculation process of the polarity characteristic is as follows: 1. acquiring the transient zero-sequence voltage variation of the bus; 2. obtaining the variation of outlet transient zero-sequence current; 3. acquiring the calculation time variation; 4. and calculating the polarity characteristics.

The bus transient state is zeroObtaining the sequence voltage variation firstly obtains the bus transient zero-sequence voltage (each distribution line in the bus is obtained respectively) through the voltage acquisition module 1, marks the position where the first sampling point of the zero-sequence voltage sampling point is larger than the set value (namely the first sampling point where the overvoltage occurs), finds the position where the amplitude of the voltage sampling point is maximum in the current power frequency cycle (the frequency of the power frequency signal is 50Hz, one power frequency cycle is 20ms, in this embodiment, one power frequency cycle is sampled 256 times), and marks the position as U₀[m1.max]The position is marked m1 and marked as the end, and the time 10ms before the position m1, i.e., the sample point m1-127 position, is marked as the start. Finding the minimum value of the amplitude of the same-polarity voltage sampling point in the range from the starting point to the end point of the data buffer area, and marking the minimum value as U₀[m2.min]And the buffer area position is marked as m2, the transient zero sequence voltage variation delta U₀The calculation is as follows:

ΔU₀＝U₀[m1.max]-U₀[m2.min]。

meanwhile, the zero sequence current sampling points acquired by the current sampling module according to the same frequency are stored in the cache of the calculation module 3, I₀[0,1,2,...,N]The voltage and current sampling for each channel is synchronous (i.e., the time points at which the voltage and current data are collected are the same). After starting the overvoltage fault source calculation, when the transient zero sequence voltage variation delta U is calculated₀And the marking positions m1 and m2 of the zero sequence current are calculated in the buffer area of m 1-m 2, the maximum amplitude of the sampling point of the zero sequence current is found, and the maximum amplitude is marked as I₀[max]Then finding out the minimum amplitude in the same direction of the zero sequence current sampling point, and marking as I₀[min]Then, the variation of the transient zero-sequence current is calculated as: delta I₀＝I₀[max]-I₀[min]. For each outgoing line, the variation of the transient zero-sequence current needs to be calculated and is marked as delta I_0.L1、ΔI_0.L2、……、ΔI_0.LN。

Calculating the time variation

Wherein 20000 is 20000us per cycle, and 256 is per cycleThe wave has 256 samples.

In the calculation of the polarity characteristics, because the extreme values of the transient zero-sequence voltage and the transient zero-sequence current are directional, the overvoltage fault source is identified by utilizing the polarity characteristics of the variation of the transient zero-sequence voltage of the bus and the variation of the transient zero-sequence current of the outgoing line. The polarity of the maximum value of the transient zero-sequence voltage variable quantity and the outlet transient zero-sequence current variable quantity is opposite,

judging as an overvoltage fault source line; otherwise, the polarity of the maximum value of the transient zero-sequence voltage variation and the outlet transient zero-sequence current variation is the same,

it is determined as a non-fault source line whose overvoltage is due to a fault of the other line. Specifically, as a preferred solution, in this embodiment, the polarity characteristics include that the polarity of the bus transient zero-sequence voltage variation is opposite to the polarity of the maximum value where the transient zero-sequence current variation occurs, and the polarity of the bus transient zero-sequence voltage variation is the same as the polarity of the maximum value where the transient zero-sequence current variation occurs;

and determining the distribution line state according to the polarity characteristics, and adopting corresponding protection operation.

Specifically, after the calculation module 3 obtains the polarity characteristics of the distribution line, it can be determined whether a fault source exists, and then the corresponding line can be driven to be disconnected through the control module 4, so as to ensure that the overvoltage fault of the line cannot cause other faults.

As a preferred scheme, in this embodiment, the system further includes an alarm module 5; the alarm module 5 is connected with the control module 4 and used for displaying local alarm information. Preferably, the alarm module 5 includes a speaker and a display, and can send out an alarm message according to an instruction of the control module 4.

The process of adopting corresponding protection operation after determining the distribution line state specifically comprises the following steps:

when the transient zero sequence voltage of the bus changesIf the magnitude is opposite to the maximum value polarity of the transient zero-sequence current variation, judging that the current line is a fault source line, and executing protection operation; the polarity of the maximum value of the transient zero-sequence voltage variable quantity and the outlet transient zero-sequence current variable quantity is opposite,

judging as an overvoltage fault source line; and then corresponding protection operation is carried out at the moment, wherein the operation comprises sending alarm information, prompting operation and maintenance personnel to maintain, carrying out tripping and breaking on a fault source line, realizing fault breaking and facilitating the operation and maintenance personnel to overhaul.

And when the transient zero-sequence voltage variation of the bus is the same as the maximum polarity of the transient zero-sequence current variation, judging that the current line is a non-fault source line, and continuously acquiring the polarity characteristics of the distribution line. The transient zero-sequence voltage variation and the maximum value of the outlet transient zero-sequence current variation have the same polarity,

it is determined as a non-fault source line whose overvoltage is due to a fault of the other line.

As a preferred scheme, in this embodiment, the protection operation specifically includes:

determining a line fault type; the line fault types include permanent overvoltage faults, transient overvoltage faults and resonant overvoltage faults;

the method specifically comprises the following steps: when the overvoltage judgment starting condition is met, which outlet line fault causes overvoltage can be calculated according to the overvoltage fault source calculation step, and after the set delay time, the overvoltage judgment starting condition is still met, and the permanent overvoltage fault is judged to occur.

When the overvoltage judgment starting condition is met, which outlet line fault causes overvoltage can be calculated according to the overvoltage fault source calculation step, but after the set delay time, the overvoltage judgment starting condition cannot be met, and then the transient overvoltage fault is judged to occur.

When the overvoltage judgment starting condition is met, the polarity characteristics of all the distribution lines in the single bus are kept consistent and are all

At this time, it cannot be calculated according to the overvoltage fault source calculation step which fault of any outgoing line causes overvoltage, the bus transient zero-sequence voltage variation and the polarity characteristics of the outgoing line transient zero-sequence current are consistent, and after the set delay time, the state is still unchanged, and the resonant overvoltage is determined.

According to the line fault type, executing alarm or fault source line tripping operation, specifically comprising:

when the line fault type is a permanent overvoltage fault, driving a fault source line to trip, outputting fault source line information and executing an alarm operation; the calculation module 3 judges that a permanent overvoltage fault occurs, calculates a fault source line, and sends the judged result data to the control module 4, if the control parameter setting in the control module 4 aims at the current result data (in the embodiment, the permanent overvoltage fault) to be tripping, the control module 4 outputs a tripping signal to cause the fault source line to trip (to drive a breaker of a corresponding distribution line to trip); and if the control parameter is set to alarm, the control output module outputs an alarm signal to alarm (realized by the alarm module 5).

When the line fault type is transient overvoltage fault, outputting fault source line information and executing alarm operation; the calculation module 3 judges the occurrence of the transient overvoltage fault and calculates a fault source line, and the control module 4 outputs an alarm signal to alarm.

And when the line fault type is the resonance overvoltage fault, executing alarm operation. And if the calculation module 3 judges that the resonance overvoltage is generated, the control module 4 outputs an alarm signal to alarm.

As a preferred scheme, in this embodiment, the system further includes a communication module; the communication module is connected with the calculation module 3 and uploads alarm information or trip information or line fault information to a server.

As a preferable scheme, in this embodiment, the system further includes a clock synchronization module 7, configured to synchronize time; the sampling frequency of the voltage sampling module and the current sampling module is 12.8 kHz. Specifically, the clock synchronization module 7 synchronizes and synchronizes the time of the calculation module 3 accurately, and the voltage sampling module and the current sampling module use the same sampling frequency for sampling, so that the high association degree of data is ensured, and the calculation is more accurate.

As a preferred scheme, in this embodiment, the method further includes an overvoltage protection starting step, specifically:

and acquiring voltage data in the phase line and the zero sequence line according to a preset frequency, and starting overvoltage protection when the voltage data shows an overvoltage state. Specifically, the step is overvoltage judgment and starting. The voltage module collects voltage data, 4 voltage sampling point arrays (each sampling point is a voltage detection value) in the I section of bus (the sampling point arrays are Ua _1, Ub _1, Uc _1 and U0_1 respectively), and 4 voltage sampling point arrays (the sampling point data of Ua _2, Ub _2, Uc _2 and U0_2 respectively) in the II section of bus are stored in a cache of the computing module 3; the overvoltage condition is characterized by: continuously judging sampling points, wherein in a power frequency cycle time of 20ms, phase voltage sampling points only need any 2 sampling points to meet U0_iIs greater than U0.set (U0.set is zero line voltage threshold), or any 2 zero-sequence voltage sampling points satisfy Up_iAnd if the voltage is more than up.set (the up.set is a phase voltage threshold), starting the calculation of the overvoltage fault source. After this step is performed, it is only possible to acquire whether a fault exists in a single distribution line (lines 1-6), but it is not possible to determine which phase of the distribution lines (lines 1-6) has a fault. After the operation of obtaining the fault source line is carried out, which phase (A phase, B phase and C phase) in the distribution line has the fault can be obtained, and the fault source line can be conveniently eliminated.

The utility model discloses still provide an use overvoltage protection device based on generating line and the polarity characteristic of being qualified for the next round of competitions of overvoltage protection system based on generating line and the polarity characteristic of being qualified for the next round of competitions, use overvoltage protection system realizes the overvoltage protection of distribution lines. The type that can lead to the overvoltage through technical means discernment, and then discernment trouble source circuit to can amputate the trouble fast, avoid electrical equipment to damage power equipment because the overvoltage leads to insulating impaired, avoid abominable electric wire netting accident to take place. It is necessary to ensure the safe operation of the power distribution equipment.

It should be understood that equivalent alterations and modifications can be made by those skilled in the art according to the technical solution of the present invention and the inventive concept thereof, and all such alterations and modifications should fall within the scope of the appended claims.

Claims (5)

1. An overvoltage protection system based on bus and outlet polarity characteristics is characterized by comprising a voltage acquisition module, a current acquisition module, a calculation module and a control module;

the voltage acquisition module is used for acquiring voltage data of a phase line and a zero sequence line in a distribution line and transmitting the voltage data to the calculation module;

the current acquisition module is used for acquiring outlet zero sequence current data of a distribution line and transmitting the outlet zero sequence current data to the calculation module;

the computing module is used for judging the state of a distribution line according to the voltage data and the outgoing line zero sequence current data and driving the control module to execute protection operation;

and the control module is connected with the circuit breaker in the distribution line and controls the opening and closing of the circuit breaker.

2. The bus bar and outlet polarity characterization based overvoltage protection system of claim 1, further comprising a communication module; the communication module is connected with the calculation module and uploads alarm information or trip information or line fault information to a server.

3. The bus bar and outlet polarity characterization based overvoltage protection system of claim 1, further comprising an alarm module; the alarm module is connected with the control module and used for displaying local alarm information.

4. The bus bar and outlet polarity characterization based overvoltage protection system of claim 1 further comprising a clock synchronization module for synchronizing time; the sampling frequency of the voltage acquisition module and the current acquisition module is 12.8 kHz.

5. An overvoltage protection device based on the polarity characteristics of a bus and an outgoing line using the overvoltage protection system based on the polarity characteristics of the bus and the outgoing line of any one of claims 1 to 4, wherein the overvoltage protection device is provided with the overvoltage protection system.

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