JP2016192870A - Protection control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a protection control system that adopts new solving means for enhancing reliability to error in data transmission.SOLUTION: A protection control system associated with a power system is provided. The protection control system includes a first device and one or plural second devices connected to the first device through a transmission path. Each of the second devices includes sending means for sending information collected from the electric power system at a predetermined transmission period by using a pre-allocated channel. The first device includes calculation means for performing protection control calculation using information sent from the one or more second devices. The sending means adds specific information collected from the electric power system to the first channel and sends it by using the second channel. In the case where a transmission error occurs in the information transmitted through the first channel, the calculation means executes the protection control calculation by using the information transmitted through the second channel in place of the information transmitted through the first channel.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a protection control system that collects power system information at a predetermined period and performs protection control calculation.

  The power system is provided with a protection control system for identifying and removing a fault that has occurred in the system. The protection control system may be referred to as a protection relay or a protection relay system. The protection control calculation executed in the protection control system includes a calculation (for example, a differential relay) that determines a failure by using measured values collected at a plurality of points in the power system and comparing them. obtain. For this reason, relay devices for collecting and transmitting power system information are arranged at a plurality of monitoring target points (typically electrical stations such as substations and distribution stations) in the power system, and each relay device In general, a network configuration is adopted.

  For example, Japanese Patent Laying-Open No. 2011-055660 (Patent Document 1) employs a configuration in which detailed information on terminal devices is collected by a central device. Japanese Laid-Open Patent Publication No. 63-052624 (Patent Document 2) discloses a data transmission system in a current differential relay that determines a fault in a system by obtaining a current differential value between its own end and the other end. To do.

  A configuration that assumes that a transmission error occurs during such data transmission is also known. For example, Japanese Patent Laying-Open No. 2012-095498 (Patent Document 3) discloses a digital protection control device having a communication path for transmitting digital data from a conversion unit to a calculation unit. This digital protection control device employs a configuration that reduces the risk of losing data continuity even when a transmission error occurs due to noise or the like.

  A configuration is also known in which time synchronization is performed between networked devices. For example, Japanese Patent Laying-Open No. 2008-141866 (Patent Document 4) discloses a time synchronization method for a transmission / distribution system that can perform highly accurate time synchronization between each slave station and the master station.

JP 2011-055660 A JP 63-052624 A JP2012-095498A JP 2008-141866 A

  The protection control system is responsible for detecting and removing faults occurring in the power system as soon as possible. Therefore, even when a transmission error occurs, it is necessary to avoid the situation where the protection control calculation cannot be performed as much as possible.

  Of the above-described prior art documents, in Japanese Patent Application Laid-Open No. 2012-095498 (Patent Document 3) that deals with a problem caused by a transmission error, when any error occurs, the error is acquired in a period before the period in which the error occurred. Adopting a solution that uses alternative data instead. According to this solution, the situation where the protection control calculation cannot be performed can be avoided, but the data used for the protection control calculation is not the latest data, and therefore the operation is delayed.

  Of the above-described prior art documents, Japanese Patent Application Laid-Open No. 2011-055660 (Patent Document 1) that collects detailed information of a terminal device at a central device acquires unnecessary data because the data to be collected is not selected. It takes time to collect and is not efficient.

  Of the above-described prior art documents, Japanese Patent Application Laid-Open No. 2008-141866 (Patent Document 4) that synchronizes time between networked devices uses a GPS, and therefore costs high for implementation.

  The present invention provides a protection control system that employs a new solution for improving reliability against errors during data transmission.

  According to one aspect of the present invention, a protection control system associated with a power system is provided. The protection control system includes a first device and one or more second devices connected to the first device via a transmission line. Each of the second devices includes sending means for sending the information collected from the power system at a predetermined transmission cycle using a pre-assigned channel. The first device includes calculation means for executing a protection control calculation using information sent from one or a plurality of second devices. The sending means adds the specific information collected from the power system to the first channel and sends it using the second channel. The arithmetic means, when a transmission error occurs in the information sent on the first channel, uses the information sent on the second channel instead of the information sent on the first channel, and performs protection control. Perform the operation. Here, the information transmitted on the second channel is the latest information as the information transmitted on the first channel.

  Preferably, the sending means sends the specific information collected from the power system using a plurality of second channels. That is, instead of sending information by duplication, information may be sent by triple.

  Preferably, the second device further includes storage means for storing detailed information including information collected from the power system when a predetermined condition is satisfied, and the first device is stored in the second device. The information processing apparatus further includes acquisition means for acquiring necessary information among the detailed information obtained via the transmission line.

  More preferably, each of the first device and the second device further includes a clock for controlling timing related to data transmission via the transmission path. The protection control system further includes means for synchronizing between the clock of the first device and the clock of the second device. The storage means of the second device includes information for synchronizing information between the clock contained in the second device and the clock contained in the second device and the clock of the first device and the clock of the second device. Time information based on and is given. At this time, by adding the transmission delay time, it becomes possible to match the time information of each second device with the first time information on the basis of the time information of the first device.

  Preferably, the sending means of the second device sends the detailed information using a channel assigned to the second device.

  ADVANTAGE OF THE INVENTION According to this invention, the reliability with respect to the error at the time of data transmission can be improved.

It is a schematic diagram which shows the whole structure of the protection control system according to this Embodiment. It is a schematic diagram which shows the outline | summary of the data transmission in the protection control system shown in FIG. It is a figure which shows an example of the transmission format in the protection control system according to this Embodiment. It is a figure which shows an example of the data structure contained in each channel in the protection control system according to this Embodiment. It is a figure which shows an example of the channel format in the protection control system according to this Embodiment. It is a flowchart which shows the principal part of the process sequence of the protection control calculation in the protection control apparatus which comprises the protection control system according to this Embodiment. It is a schematic diagram which shows the outline | summary of the detailed information collected with the protection control system shown in FIG. It is a figure which displays visually an example of the content contained in detailed information. It is a figure which shows another example of the channel format in the protection control system according to this Embodiment. It is a schematic diagram for demonstrating the synchronization method in the protection control system according to this Embodiment. It is a flowchart which shows the process sequence of the time synchronization of the protection control system according to this Embodiment. It is a flowchart which shows the process sequence when the relay apparatus of the protection control system according to this Embodiment collects detailed information. It is a figure which shows another example of the channel format in the protection control system according to this Embodiment.

Embodiments of the present invention will be described in detail with reference to the drawings. In addition, about the same or equivalent part in a figure, the same code | symbol is attached | subjected and the description is not repeated.
[A. overall structure]
First, the overall configuration of protection control system 1 according to the present embodiment will be described. FIG. 1 is a schematic diagram showing an overall configuration of a protection control system 1 according to the present embodiment. For convenience of explanation, FIG. 1 also shows a power system, but the protection control system according to the present invention should be determined based on the description of the scope of claims.

  Referring to FIG. 1, a protection control system 1 according to the present embodiment is associated with a power system, and includes a protection arithmetic device 100A that is a main body that executes a protection control calculation, and one or more relay devices 100B to 100E. Including. The protection arithmetic device 100A and the relay devices 100B to 100E are connected via a transmission line 2 for exchanging data.

  In the data transmission method adopted by the protection control system 1 according to the present embodiment, any device connected to the transmission path 2 becomes a master station (master), and other devices become slave stations (slaves). Adopt a master / slave system. Any device may be set as the master station, but generally, the protection arithmetic device 100A is set as the master station. The master station manages a data string (data frame) sequentially propagated in the transmission path 2. In the following description and drawings, the protection arithmetic device 100A and the relay devices 100B to 100E may be expressed as “terminal A” to “terminal E” in the sense of a terminal device in the transmission path 2. In addition, the protection arithmetic device 100A which is the master station is described as “terminal A (parent station)”, and the relay devices 100B to 100E which are slave stations are “terminal B (slave station)” to “terminal E (slave station). ) ”.

  FIG. 1 shows an example of a two-line power transmission system. More specifically, two transmission lines 2A and 2B are provided between the electric station 10 and the electric station 20, and the electric transmission line is connected to the bus 14 and the bus 24 at the electric station 10 and the electric station 20, respectively. 2A and 2B are connected. Two generators 4 </ b> A and 4 </ b> B are connected to the bus 14 of the electric station 10. Electric power is supplied from the bus 24 of the electric station 20 to one or a plurality of loads.

  In order to eliminate a failure that may occur in the power transmission line 2A, the electrical station 10 and the electrical station 20 are provided with a circuit breaker 11A and a circuit breaker 21A, respectively. Similarly, in order to eliminate a failure that may occur in the transmission line 2B, the electrical station 10 and the electrical station 20 are provided with a circuit breaker 11B and a circuit breaker 21B, respectively.

  As detectors for operating the circuit breakers 11A and 21A, current transformers (CT: Current Transformer) 12A and 22A are provided in the power transmission line 2A, and a measurement current is applied to the relay device 100B. Similarly, the measurement currents by the instrument current transformers 22A and 22B are given to the relay device 100C.

  Similar to the electric station 20, in the electric station 30, the power transmission lines 2 </ b> A and 2 </ b> B are connected to the bus 34, and electric power is supplied from the bus 34 to one or more loads. The electrical station 30 is further provided with a circuit breaker 31A and a circuit breaker 31B. In association with these circuit breakers, an instrument current transformer 32A and an instrument current transformer 32B are provided. Measurement currents from the current transformers 22A and 22B for the instruments are given to the relay device 100D.

  In the electric station 40, the power transmission lines 2 </ b> A and 2 </ b> B are connected to the bus 44, and power is supplied from the bus 44 to one or a plurality of loads. The electrical station 40 is further provided with a circuit breaker 41A and a circuit breaker 41B. A current transformer 42A and a current transformer 42B are provided in association with these circuit breakers. The measurement current by the instrument current transformers 42A and 42B is given to the relay device 100E.

The relay devices 100B to 100E transmit information (measured values) of the power system input to each of them through the transmission path 2 to the protection arithmetic device 100A. The protection arithmetic device 100A executes the protection control calculation using the information received from each of the relay devices 100B to 100E. As a result, if it is determined that some failure has occurred, the position where the failure has occurred is identified. Then, a trip command is given to the circuit breaker related to the specified position.
[B. Data transmission]
Next, data transmission in protection control system 1 according to the present embodiment will be described.

  FIG. 2 is a schematic diagram showing an outline of data transmission in the protection control system 1 shown in FIG. In the typical example illustrated in FIG. 2, the protection arithmetic device 100 </ b> A and the relay devices 100 </ b> B to 100 </ b> E are connected in a ring shape via the transmission path 2.

  The protection arithmetic device 100A includes an arithmetic device 120A that is an execution subject of the protection control arithmetic and a transmission device 110A. Arithmetic device 120A performs protection control calculation using information sent from relay devices 100B to 100E. Relay devices 100B to 100E include transmission devices 110B to 110E, respectively. In relay device 100B, transmission device 110B sends measurement value 1 and measurement value 2 output from protection control device 13A and protection control device 13B via transmission line 2.

  Similarly, in relay device 100C, transmission device 110C sends measurement value 3 and measurement value 4 output from protection control device 23A and protection control device 23B via transmission line 2. In relay device 100D, transmission device 110D sends measurement value 5 and measurement value 6 output from protection control device 33A and protection control device 33B via transmission line 2. In relay device 100E, transmission device 110E sends measurement value 7 and measurement value 8 output from protection control device 43A and protection control device 43B via transmission line 2.

  The transmission apparatuses 110 </ b> B to 110 </ b> E can realize scheduled data transmission by assigning the measurement values of the own apparatuses to the timing slots given in advance. In addition, as for the period which each of relay apparatus 100B-100E transmits the information (measurement value) of an electric power grid | system, for example, 30 degrees is preferable with an electrical angle (equivalent to 1.67 msec period at 50 Hz / 1.39 msec period at 60 Hz). .

  In FIG. 1 and FIG. 2, the protection arithmetic device 100A and the relay devices 100B to 100E are independent from each other, but the function of the protection arithmetic device 100A may be incorporated in any of the relay devices. That is, the protective arithmetic device 100A employs substantially the same configuration as the relay devices 100B to 100E except that the protective arithmetic device 100A includes the arithmetic device 120A. Furthermore, since the function of the arithmetic device 120A can also be realized by using sharable hardware, one of the plurality of devices having the same device configuration is operated by software or the like for one device. The protection control system 1 including the protection arithmetic device 100A and the relay devices 100B to 100E may be realized by implementing the function of 120A.

  FIG. 3 is a diagram showing an example of a transmission format in the protection control system 1 according to the present embodiment. In the protection control system 1 according to the present embodiment, an ITU-T (International Telecommunication Union Telecommunication Standardization Sector) G.G. A transmission format defined in 704 is used. ITU-T G. In 704, several transmission formats are prepared according to the difference in transmission rate. FIG. 3 shows a transmission format of 1544 kbps. As shown in FIG. The transmission format of 1544 kbps defined in 704 has a configuration in which the time width of one frame (one transmission cycle) is 125 μs and includes 193 bits, and 24 channels (CH1 to CH24) are prepared.

  FIG. 4 is a diagram showing an example of a data structure included in each channel in protection control system 1 according to the present embodiment. Referring to FIG. 4, the measurement value of each channel includes data for three phases (for example, A phase current data, B phase current data, and C phase current data) at a certain measurement time point. Also, control data including the open / close state of the circuit breaker and the switch, control signals input from the outside, information such as data validity, data for frame synchronization, and the like are transmitted.

  In addition to these data, frame synchronization, which is control information for realizing frame transmission at a fixed period, and CRC (Cyclic Redundancy Check) for detecting a transmission error are also added.

  The protection arithmetic device 100A detects a transmission error by determining a match / mismatch with the CRC added to each frame unit.

As described above, each of relay devices 100B to 100E includes a transmission function for transmitting information collected from the power system at a predetermined transmission cycle using a channel assigned in advance. Note that a similar sending function is also implemented in the protection arithmetic device 100A.
[C. Improved reliability against transmission errors]
Next, the protection control system 1 according to the present embodiment implements the following functions so that the protection control calculation can be continued more reliably even for transmission errors that occur in the data transmission method as described above. .

  FIG. 5 is a diagram showing an example of a channel format in the protection control system 1 according to the present embodiment. Referring to FIG. 5, for example, in protection control system 1, it is assumed that 24 types of independent data can be transmitted every predetermined transmission period. The transmission path 2 is logically prepared with 24 channels (CH1 to CH24). In the protection control calculation application executed by the protection calculation device 100A, the data of each channel can be used as shown in FIG.

  FIG. 5A shows a state in which data D1 to D8 corresponding to measurement values 1 to 8 shown in FIG. 2 are allocated to channels CH1 to CH8, respectively. In the configuration example shown in FIG. 2, only the measurement values 1 to 8 are transmitted, and the channels CH9 to CH24 are empty channels.

  The protection control system 1 according to the present embodiment uses such an empty channel, that is, a communication resource that is not used, to implement a function for improving reliability against a transmission error. More specifically, as shown in FIG. 5B, data D1 to D8 assigned to channels CH1 to CH8 are also assigned to other channels CH11 to CH18. That is, the data D1 to D8 assigned to the channels CH1 to CH8 are copied to the channels CH11 to CH18.

  For example, even if a transmission error occurs in the channel CH1 to which the data D1 is assigned, if the transmission error does not occur in the channel CH11 to which the same data D1 is assigned, the protection arithmetic device 100A has the original power The protection control calculation can be continued using the system information.

  The protection arithmetic device 100A may execute a protection control calculation using past data and current data, and when a transmission error occurs in one channel in a certain transmission cycle, the protection arithmetic device 100A (for example, There are cases where the protection control calculation cannot be performed over several tens of milliseconds). Even in such a case, as shown in FIG. 5B, redundancy is generated by transmitting the same measurement value independently through a plurality of channels. In the protection arithmetic device 100A, it is possible to execute the protection control calculation using the measurement value in which no error occurs, that is, correctly transmitted.

  Each of the relay devices 100B to 100E sets and transmits the measurement values collected from the corresponding instrument current transformer to a plurality of channels designated in advance. For example, the transmission apparatus 110B (FIG. 2) that transmits the measurement value 1 and the measurement value 2 sets the measurement value 1 (data D1) in the channel CH1 and the channel CH11, and the measurement value 2 (data D2) in the channel CH2 and the channel CH12. ) Is set. The set of data for the two channels is executed within the same transmission period.

  As described above, the transmission apparatuses 110B to 110E of the relay apparatuses 100B to 100E send specific information collected from the power system using the spare channel (empty channel) in addition to the original channel (normal channel), respectively. To do. The computing device 120A of the protection computing device 100A replaces the information sent on the original channel (normal channel) with a spare channel when a transmission error occurs in the information sent on the original channel (normal channel). The protection control calculation is executed using the information transmitted in (empty channel).

  FIG. 5 shows an example in which the same data is set in two channels within the same transmission cycle. However, redundancy (reliability) may be further increased by setting the same data in more channels. . In the example illustrated in FIG. 5, for example, data D1 to D8 may be set in three channel groups of channels CH1 to CH8, channels CH9 to CH16, and channels CH17 to CH24. That is, the transmission devices 110B to 110E of the relay devices 100B to 100E may send specific information collected from the power system using a plurality of spare channels (empty channels).

  FIG. 6 is a flowchart showing a main part of a processing procedure of protection control calculation in protection calculation device 100A constituting protection control system 1 according to the present embodiment. Referring to FIG. 6, arithmetic device 120A (see FIG. 2) constituting protection arithmetic device 100A completes the data reception process at transmission device 110A (see FIG. 2) (YES in step S100). It is determined whether or not a transmission error has occurred in the other channel (step S102). If no transmission error has occurred in any channel (NO in step S102), arithmetic unit 120A obtains the original measured value (data) transmitted in each channel (step S104).

  On the other hand, if a transmission error has occurred in any of the channels (YES in step S102), arithmetic unit 120A, for the channel in which no transmission error has occurred, the measured value ( Data) is acquired, and for a channel in which a transmission error has occurred, a measurement value (data) transmitted on the channel to which the copy is assigned is acquired (step S106).

  The computing device 120A executes the protection control computation using each acquired measurement value (data) (step S108). Then, the arithmetic device 120A determines whether or not any failure has occurred based on the execution result of the protection control calculation (step S110).

If any failure has occurred (YES in step S110), arithmetic device 120A outputs a trip signal to the target circuit breaker (step S112). And the process after step S100 is repeated. The same procedure is executed for descending.
[D. Detailed information collection function]
As shown in FIG. 5 above, when there are many empty channels other than the channel through which the measurement value (data) is transmitted, in addition to the channel use for improving the reliability against the transmission error described above, The empty channel may be used for other purposes. Various utilization methods are assumed for such an empty channel. As an example, the function of collecting detailed information held by the relay devices 100B to 100E in the protection arithmetic device 100A will be described below.

(D1: Overview)
FIG. 7 is a schematic diagram showing an outline of detailed information collected by the protection control system 1 shown in FIG. It is assumed that conditions (freeze conditions) for collecting detailed information are set in advance in relay devices 100B to 100E. For example, when a certain circuit breaker trips, the power system information (measured value) related to the circuit breaker is collected over a predetermined period including the trip time. However, the detailed information 140B to 140E includes not only the measurement value transmitted to the protection arithmetic device 100A but also various information.

  FIG. 7 shows an example in which the relay devices 100B to 100E hold the detailed information 140B to 140E. The protection arithmetic device 100A can collect the detailed information 140B to 140E using a channel that is not used to transmit the measurement value. The detailed information 140B to 140E collected by the protection arithmetic device 100A is used for analysis by an operator / manager of the power system.

  That is, relay devices 100B to 100E have a storage function for storing detailed information including information collected from the power system when a predetermined condition is satisfied. The protection arithmetic device 100A has an acquisition function of acquiring detailed information stored in the relay devices 100B to 100E via the transmission path 2.

  FIG. 8 is a diagram visually displaying an example of contents included in the detailed information. In FIGS. 8A and 8B, measurement values at different monitoring target points are collected over a predetermined period for the same failure. Here, since the relay devices that collect the detailed information are different, the attributes given to the detailed information may be different. Here, when there is no common time information between the protection arithmetic device 100A and the relay devices 100B to 100E, the failure is the same as shown in FIGS. 8A and 8B. Nevertheless, in each detailed information, different times (T1 and T2) are given as attributes.

  Multiple accidents may occur in combination, and when analyzing the detailed information actually collected, the cause of the failure of the target after matching the time axis between the multiple detailed information Will be investigated. However, when the time information is not shared between the protection arithmetic device 100A and the relay devices 100B to 100E, it is difficult to match the time axis among a plurality of detailed information, and the subsequent analysis processing is accurate. And can be an obstacle to doing efficiently.

  Therefore, as shown in FIG. 7, in protection control system 1 according to the present embodiment, protection arithmetic device 100A and relay devices 100B to 100E have time information 130A to 130E synchronized with each other. In this embodiment, since a master-slave data transmission method is employed, a method is employed in which each of relay devices 100B to 100E serving as slaves synchronizes time information with respect to protection arithmetic device 100A. That is, each of the relay devices 100B to 100E corrects the time information of the protection device 100A each time so that the time information of the device itself follows. And each of relay apparatus 100B-100E is provided to the detailed information which collects the time information of an own apparatus.

  As described above, the time information synchronized in the protection control system 1 is held by each device, so that the accuracy and efficiency of the analysis can be improved even when collecting and analyzing detailed information collected by a plurality of devices. Can be increased. For example, even when multiple faults occur simultaneously in a short time in the power system and multiple detailed information is generated, they have time information synchronized with each other, so the time axes match It is possible to easily perform various kinds of analysis such as comparison after being performed.

(D2: channel format)
FIG. 9 is a diagram showing another example of the channel format in the protection control system 1 according to the present embodiment. The channel format shown in FIG. 9 can further transmit detailed information and time information as compared with the channel format shown in FIG. That is, FIG. 10A shows a state in which data D1 to D8 corresponding to measurement values 1 to 8 shown in FIG. 2 are allocated to channels CH1 to CH8, respectively. On the other hand, as shown in FIG. 10B, the data D1 to D8 assigned to the channels CH1 to CH8 are assigned to the other channels CH9 to CH16, and the remaining channels CH17 to CH24 are used for further details. Transmits information and time information.

  As a method of transmitting detailed information and time information from each of the relay devices 100B to 100E using the channels CH17 to CH24, (1) a protection arithmetic device 100A as a master specifies a relay device to which detailed information is transmitted. (2) A method in which a dedicated channel is set for each of the relay devices 100B to 100E, and each device starts transmission of detailed information at an arbitrary timing. (3) A channel is set between the relay devices 100B to 100E. Sharing method can be adopted.

  In the method (1) described above, in response to a user operation or the like, the protection arithmetic device 100A instructs the specific relay device to transmit detailed information. Receiving this instruction, the relay device transmits detailed information using channels prepared in advance (channels CH17 to CH24 in the example shown in FIG. 10). In this method, since the protection arithmetic device 100A (master) can control the relay device (slave) that occupies the channel for transmitting the detailed information, efficient data transmission is possible.

  In the method (2) described above, for example, one channel of channels CH17 to CH24 is assigned to the relay devices 100B to 100E, respectively, and each of the relay devices 100B to 100E assigns a channel assigned to the own device. The detailed information is transmitted at an arbitrary timing. When the amount of detailed information is large, it is transmitted in a plurality of frames. Relay devices 100B to 100E transmit detailed information using channels assigned to relay devices 100B to 100E, respectively. In this method, since the relay devices 100B to 100E can transmit detailed information according to their own control logic, the processing in the protection arithmetic device 100A can be simplified.

  In the method (3) described above, each of the relay devices 100B to 100E transmits detailed information as appropriate after confirming that no data is transmitted through the shared channel. That is, each of relay devices 100B to 100E transmits detailed information as appropriate. In this method, detailed information can be transmitted with a relatively simple procedure regardless of the size of the shared channel.

(D3: Synchronization method)
Next, a method for synchronizing time information between the protection arithmetic device 100A and the relay devices 100B to 100E connected via the transmission line 2 will be described. In protection control system 1 according to the present embodiment, each of protection arithmetic device 100A and relay devices 100B to 100E holds an internal clock. Based on the count value generated by the clock, absolute or relative time information 130A to 130E is generated. Also, each of protection arithmetic device 100A and relay devices 100B to 100E controls frame transmission timing and the like based on the count value generated by the internal clock.

  The internal clock of each device is corrected each time the frame is transmitted on the transmission path 2 using the time information 130A to 130E, and each of the relay devices 100B to 100E is based on the clock of the protection arithmetic device 100A. The clock is corrected.

FIG. 10 is a schematic diagram for illustrating a synchronization method in protection control system 1 according to the present embodiment. Referring to FIG. 10 (A), in protection control system 1 according to the present embodiment, protection arithmetic device 100A and relay device 100B each generate a reference timing (every transmission period based on its own clock). Hereinafter, each of the synchronization control flags is transmitted at “sampling timing”. The synchronization control flag is a predetermined pattern (for example, “00001” for the relay device 100B) that can identify the target relay device. The protection arithmetic device 100A measures the time (T _M ) from the time when the synchronization control flag is received from the relay device 100B to the latest sampling timing, and notifies the relay device 100B of the measured time. Similarly, the relay device 100B measures the time (T _S ) from the time when the synchronization control flag is received from the protection arithmetic device 100A to the latest sampling timing. Finally, the relay device 100B, the value of T _M received from the protection operation device 100A, and a value of T _S measured by the own apparatus, the sampling timing of the own device for the sampling timing in the protection operation unit 100A Delay (synchronization error time ΔT) is calculated. Then, the relay device 100B corrects the sampling timing (clock) of the device itself using the calculated synchronization error time ΔT.

  A method for calculating the synchronization error time ΔT will be described in more detail with reference to FIG. Referring to FIG. 10B, protection arithmetic device 100A and relay device 100B generate sampling timings every transmission period T according to the internal clock of each device. More specifically, the protection arithmetic device 100A generates sampling timings 211, 212, 213,..., And the relay device 100B generates sampling timings 221, 222, 223,. Here, it is assumed that the internal clocks of the protection arithmetic device 100A and the relay device 100B have a difference in synchronization error time ΔT.

First, the relay device 100B sends out a synchronization control flag at the sampling timing 221 (reference numeral 231). Protection computing device 100A, from the point of receiving the synchronous control flag from the relay apparatus 100B, measures the time _{T M} to the most recent sampling timing 212. After the transmission of several frames is completed, the same synchronization control flag is sent out (reference numeral 232). Protection computing device 100A, the synchronous control flag sent simultaneously or at another frame, and sends the measured time T _M to the relay apparatus 100B.

Relay device 100B, from the point of receiving the synchronous control flag from the protection operation devices 100A, it measures the time _{T S} to the most recent sampling timing 224.

Here, using the uplink transmission delay time Tdu and the downlink transmission delay time Tdd, the following relationship is established among the synchronization error time Δt, the time T _M , and the time T _S.

Tdu + T _M = Δt + T (1)
Δt + Tdd + T _S = T (2)
Here, assuming that Tdu = Tdd, the expressions (1) and (2) can be modified as follows.

ΔT = (T _M −T _S ) / 2
The relay device 100B can synchronize with the sampling timing of the protection arithmetic device 100A by controlling the sampling timing of its own device using the synchronization error time ΔT. That is, the sampling timing of the relay device 100B is controlled so that the synchronization error time ΔT becomes zero (time T _S = time T _M ).

  The protection computing device 100A transmits the item information of the protection computing device 100A from the protection computing device 100A to the relay devices 100B to 100E, and stores the time information obtained by adding the calculated downlink transmission delay time Tdd in the relay devices 100B to 100E. The time information of 100A and the relay devices 100B to 100E can be relatively synchronized.

  Note that the timing synchronization method is not limited to the above-described method, and a known method can be employed. For example, each device may receive a reference signal such as a GPS (Global Positioning System) signal and synchronize timing based on the reference signal.

  As described above, each of the protection arithmetic device 100 </ b> A and the relay devices 100 </ b> B to 100 </ b> E has an internal clock for controlling timing related to data transmission via the transmission path 2. The protection control system 1 is provided with a function of synchronizing between the internal clock of the protection arithmetic device 100A and the internal clocks of the relay devices 100B to 100E. In addition, each of the relay devices 100B to 100E includes, in the stored detailed information, information from the internal clock of the relay devices 100B to 100E, the internal clock of the protection arithmetic device 100A, and the internal clock of the relay devices 100B to 100E. Time information based on the information for synchronization between them is given.

  FIG. 11 is a flowchart showing a time synchronization processing procedure of protection control system 1 according to the present embodiment. Referring to FIG. 11, protection arithmetic device 100A serving as a master station transmits time data of the own station (protective arithmetic device 100A) to relay devices 100B to 100E serving as slave stations (step S150). Each relay device 100B to 100E (slave station) stores time data obtained by adding the synchronization error time ΔT from the master station to the slave station to the acquired time data (step S152).

The processes in steps S150 and S152 are repeated.
(D4: Processing procedure)
Next, a processing procedure for collecting detailed information in the relay device according to the present embodiment will be described.

  FIG. 12 is a flowchart showing a processing procedure when the relay device of protection control system 1 according to the present embodiment collects detailed information. In the flowchart shown in FIG. 12, processing in the transmission apparatus 110B will be described, but the same processing is similarly executed in other transmission apparatuses.

  Referring to FIG. 12, transmission apparatus 110B determines whether or not a condition (freeze condition) for collecting detailed information set in advance is satisfied (step S200). If the condition (freeze condition) for collecting the detailed information is not satisfied (NO in step S200), the processes in and after step S200 are repeated.

  On the other hand, if the condition (freeze condition) for collecting the detailed information is satisfied (YES in step S200), the transmission apparatus 110B stores the data related to the protection function information acquired from the measuring instrument or the like ( Step S202). At the same time, the transmission apparatus 110B acquires the time data of the slave station (step S204), and adds the acquired time data to the detailed information (step S206).

Then, when the collection of detailed information is completed (YES in step S208), the processes after step S200 are repeated.
[E. Modified example]
In the above description, the same measurement value (data) is assigned to a plurality of channels, and a configuration is provided in which a channel for transmitting detailed information including synchronized time information is prepared. However, the present invention is not limited to this. Only detailed information including synchronized time information may be transmitted.

  FIG. 13 is a diagram showing still another example of the channel format in the protection control system 1 according to the present embodiment. In the channel format shown in FIG. 13, in FIG. 13A, data D1 to D8 respectively corresponding to the measured values 1 to 8 shown in FIG. 2 are assigned to the channels CH1 to CH8, and the remaining channel CH9. This shows a state where ~ CH24 is an empty channel. On the other hand, as shown in FIG. 13B, channels CH9 to CH24 may be used for transmitting detailed information and time information.

That is, in the protection control system 1 according to the present embodiment, each device has the same measurement value (data) redundantly transmitted using a plurality of channels, and each device has time information synchronized with each other. It is possible to implement at least one of transmitting detailed information provided with time information.
[F. advantage]
Since the protection control system 1 according to the present embodiment transmits the same information acquired from the power system in parallel through a plurality of channels, even if a transmission error occurs in any of the channels, the remaining channels may be healthy. Thus, the protection control calculation can be executed. Therefore, reliability against transmission errors can be improved.

  In protection control system 1 according to the present embodiment, detailed information collected by each of relay devices 100B to 100E can be acquired from protection arithmetic device 100A. That is, detailed information from a plurality of discretely arranged relay devices can be collected in a collective manner to the protection arithmetic device 100A in the case where it is necessary to analyze the cause of some failure, etc. Cause analysis can be performed efficiently.

  In the protection control system 1 according to the present embodiment, since the time stamp synchronized with the protection control device is added to the detailed information collected by each relay device, the protection control device and the relay device In addition, a time stamp synchronized between the relay devices is given. Therefore, even when it is necessary to analyze a failure using a plurality of detailed information collected by a plurality of different relay devices, the work can be performed efficiently.

  The protection control system 1 according to the present embodiment has a new solution for improving reliability against errors during data transmission and a new analysis function for improving the analysis function by efficiently collecting detailed information remotely. The solution was adopted. Furthermore, the protection control system 1 according to the present embodiment employs a solution that implements time synchronization of detailed information of each protection control device at low cost without using a special device such as GPS.

  Since the protection control system 1 according to the present embodiment can select and acquire necessary information from the detailed information stored in the slave station, it can perform efficient failure analysis. In addition, according to the protection control system 1 according to the present embodiment, it is possible to perform efficient failure analysis by performing time synchronization between the protection control devices at low cost and using synchronized detailed information. it can.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  DESCRIPTION OF SYMBOLS 1 Protection control system, 2 Transmission line, 2A, 2B Power transmission line, 4A, 4B generator 10, 20, 30, 40 Electricity station, 11A, 11B, 21A, 21B, 31A, 31B, 41A, 41B Circuit breaker, 12A , 12B, 22A, 22B, 32A, 32B, 42A, 42B Current transformer for instrument, 13A, 13B, 23A, 23B, 33A, 33B, 43A, 43B Protection control device, 14, 24, 34, 44 Bus, 100A Protection Arithmetic device, 100B, 100C, 100D, 100E Relay device, 110A, 110B, 110C, 110D, 110E Transmission device, 120A Arithmetic device, 130A-130E Time information, 140B-140E Detailed information, 211, 212, 213, 221, 222 , 223, 224 Sampling timing.

Claims (5)

A protection control system associated with a power system,
A first device;
One or a plurality of second devices connected to the first device via a transmission line,
Each of the second devices includes sending means for sending information collected from the power system at a predetermined transmission period using a pre-assigned channel,
The first device includes a calculation unit that executes a protection control calculation using information transmitted from the one or more second devices,
The sending means adds specific information collected from the power system to the first channel, and sends each using a second channel,
The computing means uses the information sent on the second channel instead of the information sent on the first channel when a transmission error occurs in the information sent on the first channel. A protection control system that executes protection control calculations.   The protection control system according to claim 1, wherein the sending unit sends specific information collected from the power system using a plurality of the second channels. The second device further includes storage means for storing detailed information including information collected from the power system when a predetermined condition is satisfied,
The protection control system according to claim 1, wherein the first device further includes an acquisition unit that acquires necessary information among detailed information stored in the second device via the transmission path. Each of the first device and the second device further includes a clock for controlling a timing related to data transmission via the transmission path,
The protection control system further comprises means for synchronizing between the clock of the first device and the clock of the second device,
The storage means of the second device is synchronized with the detailed information to be stored between the information contained in the clock included in the second device and the clock of the first device and the clock of the second device. The protection control system according to claim 3, wherein time information is provided based on information for taking   The protection control system according to claim 3 or 4, wherein the sending unit of the second device sends the detailed information using a channel assigned to the second device.

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