JP6659296B2 - Substation equipment operation support system - Google Patents

Description

  An embodiment of the present invention relates to a substation facility operation support system that supports operation of a substation facility including a plurality of switches and a plurality of voltage detection devices.

  Conventionally, power receiving and transforming equipment has a function of distributing electric power to each load equipment. There are many switches, such as a circuit breaker, a disconnecting switch, and a load switch, as devices constituting a substation facility. Generally, a switch is installed at a location that becomes a branch in the system. In addition to automatic shutoff in the event of an accident, on / off operations of these switches are performed during maintenance or the like. When maintenance is started, the switch is turned off to bring the system circuits and equipment into a power outage state, and when maintenance is completed, the switch is turned on to lead to the live state. .

  Some switches have a draw-out mechanism. The pull-out mechanism is a mechanism that allows the switch body to be easily separated from the circuit, and is generally employed to facilitate inspection, testing, and equipment replacement. In the extracted position, the switch is electrically disconnected from the main circuit, but the control mechanism of the switch can be kept connected for testing. For this reason, when the switch is in the drawn-out position, there is a case where the circuit is turned off and the switch itself is turned on.

  Devices for detecting the presence or absence of a voltage in a circuit include an instrument transformer (VT), a grounded instrument transformer (EVT), and a voltage detector (VD). These voltage detection devices generally detect the presence or absence of a circuit voltage, and the presence or absence of the detected circuit voltage is used as a trigger signal for switching systems or activating a generator.

JP-A-11-273538

  On the other hand, from the viewpoint of facility maintenance, it is preferable that a device for detecting voltage is provided for each circuit divided by the switch. However, in many cases, only some circuits are applied in terms of cost. Therefore, the maintenance person attempts to determine the hot-line state or the power failure state in an arbitrary circuit or to operate the information from the information on the presence or absence of the voltage of the voltage detection device installed on the system and the information on the ON / OFF of the switch. An estimation of the state of the circuit must be made. However, if the system is complicated, the state of the circuit of the system may be erroneously estimated. When the system becomes complicated, this aspect becomes remarkable, and it becomes difficult to predict the presence or absence of the voltage of each circuit after the switching operation of the switch. Further, when the switch is in the drawn-out position, there is a case where the circuit is turned off and the switch itself is turned on. For this reason, at the pull-out position, the switch is disconnected from the system irrespective of the ON / OFF state of the switch, which makes the determination more difficult.

  Embodiments of the present invention have been proposed to solve the above-described problems of the related art. An object of the present invention is to provide a power receiving and transforming facility operation support system that can easily grasp the circuit status of the power receiving and transforming facility during maintenance.

A power receiving and transforming facility operation support system according to an embodiment for achieving the above object includes a power receiving and transforming facility operation system that supports operation of a power receiving and transforming facility including a plurality of switches and a plurality of voltage detection devices by a central monitoring facility. In the support system, apart from the central monitoring equipment, a mobile terminal capable of being transported or a site monitoring device installed near the switch is provided, and the mobile terminal or the site monitoring device is provided on the substation equipment. from the switch and the voltage detection device, on-off state of the switch, and obtains the parameter of whether the drawer state the switch is pulled out from the housing for housing the switch Based on those parameters and the circuit on the substation equipment, the switch is connected when the switch is at the connection position with respect to the housing and the switch is in the on state. Determines that the state, if the switch is the near-out position relative to the housing is, and the switch is Ru ON state der as well as the switch is in the connected position with respect to the housing, And when the switch is in the OFF state, it is determined that the switch is in the non-connected state, and an operation is performed to determine the presence or absence of a voltage of a circuit unit divided by the plurality of switches on the power receiving and transforming facility. And a display unit for displaying the presence or absence of a voltage of each circuit unit separated by the switch on the power receiving and transforming equipment determined by the arithmetic unit.

It is a lineblock diagram of a substation equipment to which the substation equipment operation support system of a first embodiment is applied. 1 is a partial configuration diagram of a power receiving and transforming equipment operation support system according to a first embodiment. It is a figure which shows the example of a display of the presence or absence of the voltage of a switch in the substation equipment operation support system of 1st Embodiment. It is a figure showing the example of a display of the substation equipment operation support system of a 1st embodiment. FIG. 3 is a diagram illustrating a display example of power failure control of a power receiving and transforming facility in the power receiving and transforming facility operation support system according to the first embodiment. FIG. 3 is a diagram illustrating a display example of power failure control of a power receiving and transforming facility in the power receiving and transforming facility operation support system according to the first embodiment. FIG. 3 is a diagram illustrating a display example of power failure control of a power receiving and transforming facility in the power receiving and transforming facility operation support system according to the first embodiment. FIG. 3 is a diagram illustrating a display example of power failure control of a power receiving and transforming facility in the power receiving and transforming facility operation support system according to the first embodiment. FIG. 6 is a diagram illustrating a display example of power recovery control before opening a main transformer secondary CB of the power receiving and transforming facility in the power receiving and transforming facility operation support system of the first embodiment. FIG. 6 is a diagram illustrating a display example of power recovery control before opening a main transformer secondary CB of the power receiving and transforming facility in the power receiving and transforming facility operation support system of the first embodiment. FIG. 6 is a diagram illustrating a display example of power recovery control after the main transformer secondary CB of the power receiving and transforming facility is opened in the power receiving and transforming facility operation support system of the first embodiment. FIG. 6 is a diagram illustrating a display example of power recovery control after the main transformer secondary CB of the power receiving and transforming facility is opened in the power receiving and transforming facility operation support system of the first embodiment.

[First Embodiment]
[1. Constitution]
(Overall configuration of the system)
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a configuration diagram of an example of a power receiving and transforming facility 2 to which the power receiving and transforming facility operation support system 1 of the present embodiment is applied. FIG. 2 is a configuration diagram of the substation equipment operation support system 1 of the present embodiment. The substation equipment operation support system 1 of the present embodiment mainly supports the operation of the substation equipment 2 including a plurality of switches 3 and a plurality of voltage detection devices 4 with a central monitoring facility 5.

  The substation equipment operation support system 1 has a site monitoring device 6 connected to an interface arranged near the switch 3 separately from the central monitoring equipment 2. The site monitoring device 6 is connected to the central monitoring facility 5 via a remote station panel 7 (RS panel) by a control line. A plurality of site monitoring devices 6 are installed in each part of the circuit on the substation facility 2. That is, the power receiving and transforming equipment 2 is configured by combining a plurality of circuits separated by a plurality of switches 3, and each circuit includes a switch, a transformer, a transformer current transformer, a voltage detection device, and the like. Devices are provided. The on-site monitoring device 6 is provided in each circuit of the power receiving and transforming facility 2, and determines a live state of each circuit based on a signal from the voltage detection device 4 of each circuit.

  Hereinafter, a configuration example of such a circuit will be described. In the power receiving and transforming facility 2, main systems 10-1 and 10-2 to which power is supplied from a power company are arranged in parallel. The main system 10-1 includes, from the upstream to the downstream, a switch 3-1-1, a voltage transformer / current transformer 11, a switch 3-2-1, a transformer 12-1, and a transformer voltage detector 13-1 ( Undervoltage relay) and switch 3-3-1 are sequentially arranged. In the main system 10-2, a switch 3-1-2, disconnectors 18-1 to 18-11, a switch 3-2-2, a transformer 12-2, and a voltage detector of a transformer are provided from upstream to downstream. 13-2 (undervoltage relay) and switch 3-3-1 are arranged in order. The main systems 10-1 and 10-2 are connected downstream via switches 3-4-1 and 3-4-2.

  Downstream of the main systems 10-1 and 10-2, the high-voltage buses 14-1 and 14-2 are branched, and each branch of the high-voltage bus 14-1 is a switch 3-5-1 to 3-5- 11, and each branch of the high-voltage bus 14-2 includes switches 3-6-1 to 3-6-11. The high-voltage bus 14-2 is connected to the generators 17-1 and 17-2, and the generators 17-1 and 17-2 are connected between the high-voltage buses 14-1 and 14-2 by a switch 3-. 7-1 to 3-7-5, 3-8-1, and 3-8-2 are arranged. Further, the voltage detectors 19-1 and 19-2 of the grounding type instrument transformers are installed at the most downstream of the main systems 10-1 and 10-2, respectively.

  The switch 3 in FIG. 1B is a vacuum circuit breaker (VCB), a disconnecting switch (DS), a high-voltage AC load switch (LBS), a circuit breaker (MCCB), or the like. The vacuum circuit breaker (VCB) has a structure in which electrodes are housed in a high vacuum container, and cuts off current in a high vacuum. The disconnecting switch (DS) is a switch incorporated in a high-voltage or extra-high-voltage electric circuit, and opens a circuit in a no-load state to a no-voltage state. A high-voltage AC load switch (LBS) is a switch that can open and close a load current that is normally used, such as an air switch. The circuit breaker (MCCB) opens the circuit when an abnormal overcurrent flows in the secondary circuit due to factors such as overload or short circuit, and cuts off the power supply from the primary circuit to load circuit. And wires from damage. These are all referred to herein as switches.

  The switch 3 has a draw-out mechanism to the housing, and a plurality of switches are used by being inserted into the housing. When a maintenance person or the like wants to maintain the switch, the switch 3 is pulled out of the housing, pulled out to the draw-out position, and is maintained in a state where it is disconnected from the circuit on the substation 5. Done. Then, when the maintenance is completed, the switch 3 is inserted into the housing and inserted to the connection position, and the switch 3 is connected to the circuit on the power receiving and transforming facility 5.

  The switch 3 is a parameter that determines whether the switch 3 is turned on or off and a parameter indicating whether the switch 3 is on or off in the cabinet. And, it transmits to the central monitoring equipment 5. The switch 3 can be connected to a control line in a state where the switch 3 is at the drawn-out position, and maintenance or the like is performed in that state.

  The parameter indicating whether or not the switch 3 is at the withdrawal position may be determined by detecting the position of the switch 3 itself with a switch or a sensor, or by a maintenance person who has moved the switch 3 to the withdrawal position. The information may be manually input to the site monitoring device 6 to which the switch is connected. When the on-site monitoring device 6 is connected to the central monitoring facility 2 via a control line, the information on whether or not the central monitoring facility 2 is at the drawing position received from each switch 3 is transmitted to the central monitoring facility 2. May be transmitted to the on-site monitoring device 6.

  FIG. 3 is a diagram illustrating a display example of the presence / absence of the voltage of the switch in the power receiving and substation equipment operation support system of the present embodiment. As shown in FIG. 3, the switch 3 is provided with a display unit such as a liquid crystal display or an indicator lamp at a door portion thereof, and the display unit displays on / off information of the switch 3, primary voltage and secondary voltage. Is displayed.

  The voltage detector 4 is an instrument transformer (VT), a grounded instrument transformer (EVT), a voltage detector (VD), or the like. An instrument transformer (VT) is used to determine whether a power outage has occurred. It is also used to measure relatively small voltages. A grounded instrument transformer (EVT) is basically the same as an instrument transformer, but is used for special applications such as zero-phase voltage detection. The voltage detector (VD) detects the presence or absence of the transmission voltage from the power company, and transmits it to each site monitoring device 6, the remote station panel 7, and the central monitoring facility 5, and the transmitted data is used for system switching and the like. Used for Note that all of these voltage detection devices 4 are similarly described in the present embodiment.

  In the voltage detector 4, a voltage detector (VD) transmits an ON signal as a parameter when detecting a voltage, and transmits an OFF signal when not detecting a voltage. The instrument transformer (VT) and the grounded instrument transformer (EVT) transmit an ON signal as voltage detection “Yes” when an undervoltage relay that detects a secondary voltage detects OFF information, and transmits an ON signal. When the voltage relay detects the ON information, the OFF signal is transmitted as voltage detection “absent”.

  The central monitoring facility 5 obtains information from each section of the power receiving and transforming facility 2 and provides the information obtained by adding the information to a maintenance person or the like by using an output device such as a display provided by itself. The central monitoring facility 5 controls the entire power receiving and transforming facility 2 according to a command of a maintenance person or the like received using an input device owned by the central monitoring facility 5 or a predetermined algorithm.

  The plurality of remote station boards 7 (RS boards) are devices installed at locations that serve as relay points of wiring to the central monitoring facility 5, and include a site monitoring device 6 and a central monitoring facility 5 at each part of the substation facility 2. To transmit and receive various data such as information on the presence or absence of a voltage detected by the voltage detection device 4, on / off information of the switch 3, information on the extraction / connection position, and information on the circuit of the entire power receiving and transforming facility 2.

(Configuration of the site monitoring device 6)
The site monitoring device 6 includes a storage unit 61, an operation unit 62, a display unit 63, and a calculation unit 64.

  The calculation unit 64 is a PLC (programmable controller) or the like, and performs a display screen control process 641, a circuit state determination process 642, and a training / normal mode selection process 643 as processes. The arithmetic unit 64 obtains, from the switch 3 and the voltage detection device 4 on the power receiving and transforming equipment 5, parameters of a connection state and an extraction state of the switch 3 and a voltage detection state of the voltage detection device 4 as a circuit state determination process 642. Then, based on the parameters of the controller, it is determined whether or not there is a voltage for each circuit unit separated by the switch 3 on the power receiving and transforming facility 5. The parameters include information on the presence or absence of a voltage by the voltage detection device 4, on / off information on the switch 3, and information on the connection / extraction position of the extraction mechanism. The arithmetic unit 64 calculates the presence / absence of the voltage of the circuit divided by the switch 3 using a sequencer or the like from the following parameters, thereby enabling the presence / absence display of the voltage of each circuit divided by the switch 3. The calculation unit 64 determines the connection state of the switch 3 according to Table 1 below. Specifically, when the switch 3 is at the connection position with respect to the housing and the switch 3 is turned on, the switch 3 is determined to be on, and the switch 3 is turned on. , Or the switch 3 is turned off, the switch is determined to be off. In addition, the arithmetic unit 64 determines that there is a voltage in the circuit separated by the two switches 3 from which the voltage is detected by the voltage detection device 4 and the circuit connected to the circuit by the switch 3 in the ON state.

  In addition, the calculation unit 64 determines whether or not there is a voltage on both or one of the primary side and the secondary side of the switch 3. More specifically, the arithmetic unit 64 sets the circuit of the portion, which is connected to the voltage detecting device 4 that has received the signal indicating that the voltage is present, divided by the switch 3 to have a voltage (hot line). The operation unit 64 determines that the state of the switch 3 is ON, and when there is a voltage upstream of a circuit connected to the switch 3, the primary side and the secondary side connected to the switch 3 Circuit is determined to have voltage (hot line). When determining that the state of the switch 3 is off, the calculation unit 64 determines that the secondary-side circuit connected to the switch 3 has no voltage.

  The arithmetic unit 64 calculates and estimates the circuit state of the power receiving and transforming facility 2 after the operation as the display screen control processing 641 after the switch 3 receives the operation command regarding the ON / OFF of the switch 3 before executing the command, The estimation result is displayed on the display unit 63. Then, after displaying a confirmation screen as to whether the received operation command can be executed on the display unit 63, the calculation unit 64 prompts the user to select whether or not to execute the command. If it does, execute the instruction.

  The arithmetic unit 64 selects the training mode or the normal mode as the training / normal mode selection processing 643 according to the operation of the user via the operation unit 62. In the training mode, the user virtually operates the power receiving and transforming equipment, and the user can select the training mode by using the operation unit 62. The normal mode is a mode in which the substation equipment 2 is actually operated by an operation. The confirmation screen displayed by the arithmetic unit 64 is used to confirm the accuracy of the user's operation in the normal mode before performing the operation in the normal mode, and is a means for improving safety in the normal mode. .

  When the training mode is selected, the calculation unit 64 simulates a transition of the state of the power receiving and transforming equipment 2 according to the continuous operation of the switch 3 for maintenance, and displays the transition of the state. It is displayed on the section 63.

  The display unit 63 is configured by a liquid crystal display or the like, and is separated by the switch 3 on the power receiving and transforming equipment 2 determined by the arithmetic unit 64 in order to provide information to maintenance personnel and the like based on the control of the arithmetic unit 64. Displays the presence or absence of a voltage for each circuit. The display unit 63 displays the presence or absence of a voltage on both or one of the primary side and the secondary side of the switch 3 determined by the calculation unit 64. The voltage presence / absence display for each circuit separated by the switch 3 is displayed in a bold line, a thin line, or color-coded so as to be easily understood by maintenance personnel and the like. For example, a circuit in a portion where a voltage is present is displayed as a thick line, and a circuit in a portion where no voltage is present is displayed as a thin line. This display is performed according to the display screen control processing 641.

  The storage unit 61 is a hard disk device or the like, and stores programs and data for operating the site monitoring device 6. Specifically, the storage unit 61 stores a program and data for causing the calculation unit 64 to execute the display screen control processing 641, the circuit state determination processing 642, and the training / normal mode selection processing 643. The storage unit 61 stores a circuit diagram of the entire power receiving and transforming facility 2 acquired from the central monitoring facility 5 or a circuit diagram of the entire power receiving and transforming facility 2 in advance.

  The operation unit 62 is a keyboard or a touch panel, receives a user operation, and transmits an operation command or the like to the calculation unit 64. Specifically, the user performs an operation of selecting a training mode and a normal mode and displaying a circuit diagram required for maintenance via the operation unit 62.

  FIG. 4 is a diagram illustrating a display example of the power receiving and transforming facility operation support system of the present embodiment. FIG. 4 is a diagram illustrating a display example of the presence / absence of the voltage of the switch in the power receiving and transforming equipment operation support system of the present embodiment. Under the control of the calculation unit 64, the display unit 63 displays a circuit diagram with a bold line for a live line circuit and a thin line for a power failure circuit, as shown in FIG. In addition, the display unit 63 displays “Yes” when the voltage is detected and displays “No” when the voltage is not detected for the voltage detection device 4 that has detected the voltage.

[2. Action]
(Normal mode)
FIG. 5 and FIG. 6 are diagrams illustrating display examples of the power outage control of the power receiving and transforming equipment in the power receiving and transforming equipment operation support system of the present embodiment. First, power is supplied from the power company to the main system 10-1, and the switch 3-1-1 is turned on and the switch 3-1-2 is turned off to the high voltage buses 14-1 and 14-2. Power is being supplied. The calculation unit 64 acquires voltage presence / absence information from each switch 3 and each voltage detection device 4 and displays a circuit diagram as shown in FIG. The maintenance staff and the like perform operations such as opening and closing each switch 3 while looking at the display unit 63. The circuit of the live line is indicated by a bold line, and the circuit of the power failure is indicated by a thin line. The opened switch is displayed in white, and the opened switch is displayed in black. In the switch, an operation of disconnecting a circuit is referred to as opening, and an operation of connecting the circuit is referred to as closing. The display on the display unit 63 in the following series of controls may be in the training mode. These operations can be performed by the central monitoring equipment 5 or the on-site monitoring device 6.

  Here, a situation occurs in which the power supplied to the main system 10-1 is not supplied. In that case, power is not supplied to all circuits. Then, the on-site monitoring device 6 connected to each circuit determines the voltage and the live state of each part of the circuit by the arithmetic unit 64 based on the parameters from the switch and the voltage detection device constituting the circuit, The result is displayed on the display unit 63. In this case, since power is not supplied to all circuits, all circuits are displayed as thin lines on the display unit 63 as shown in FIG. 5B. Therefore, the central monitoring equipment 5 operates to open the switches 3-5-1 to 3-5-11 and 3-6-1 to 3-6-11 and to operate the main transformers 13-1 and 13-2. Operation to be performed.

  Next, the central monitoring equipment 5 operates the generators 17-1 and 17-2, opens the switch 3-1-1 on the main system 10-1 side, and can receive power on the main system 10-2 side. If so, the operation of closing the switch 3-1-2 is performed. The display 63 displays a circuit as shown in FIG. If the switching to the main system 10-2 is completed within 15 seconds after the power failure, a circuit as shown in FIG. 6A is displayed on the display unit 63. Then, since the switching of the main system is successful, an operation of stopping the generators 17-1 and 17-2 is performed.

  Thereafter, the central monitoring facility 5 performs an operation of turning on the switches 3-5-1 to 3-5-11 and 3-6-1 to 3-6-11, and the switching of the power supply at the time of the power failure is completed. The display 63 displays a circuit as shown in FIG.

  On the other hand, a case will be described in which both the main systems 10-1 and 10-2 are out of power and switching to the main system 10-2 is impossible. FIG. 7 and FIG. 8 are diagrams illustrating display examples of the power outage control of the power receiving and transforming facility in the power receiving and transforming facility operation support system of the present embodiment.

  First, similarly to the above, the central monitoring equipment 5 opens the switches 3-5-1 to 3-5-11, 3-6-1 to 3-6-11 and opens the main transformers 13-1 and 13-1. -2 is operated, and the generators 17-1 and 17-2 are operated. After a lapse of 15 seconds from the operation of the main transformers 13-1 and 13-2, the central monitoring facility 5 opens the switches 3-3-1 and 3-3-2. The time of 15 seconds takes into account the power receiving interruption switching control and the retransmission time on the power supply side.

  Next, the central monitoring equipment 5 turns on the switches 3-7-1, 3-7-2, 3-8-1, and 3-8-2, and turns on the generators 17-1 and 17-2. , The high-voltage buses 14-1 and 14-2 return. At this time, a circuit diagram as shown in FIG.

  Then, the central monitoring equipment 5 turns on the switches 3-5-2 to 3-5-11, 3-6-1 to 3-6-10, the power outage control is completed, and power is supplied to the generator.

  Here, the power restoration control before the opening of the secondary CB of the main transformer of the power receiving and transforming equipment will be described. FIG. 9 and FIG. 10 are diagrams showing display examples of the power restoration control before opening the main transformer secondary CB of the power receiving and transforming facility in the power receiving and transforming facility operation support system of the present embodiment.

  First, in a circuit as shown in FIG. 9A, a power outage occurs in a state where power is supplied to the main system 10-1 from the power company, and power is supplied to both the main systems 10-1 and 10-2. An unsupplied situation occurs. In this case, the central monitoring equipment 5 operates the high voltage buses 14-1 and 14-2, and two seconds after the operation, the switches 3-5-1 to 3-5-11 and 3-6-1 to 3-6-1. Release 3-6-11. After that, the central monitoring facility 5 operates the generators 17-1 and 17-2. Then, before 15 seconds have elapsed since the operation of the main transformers 13-1 and 13-2, that is, before the switches 3-3-1 and 3-3-2 are opened, the main system 10-1 is opened. , 10-2, the display 63 displays a circuit diagram as shown in FIG. 9D. Thereafter, as shown in FIG. 10A, the generators 14-1 and 14-2 are stopped, and as shown in FIG. 10B, the switches 3-5-1 to 3-5-11, 3-6-1 to 3-6-11 are turned on, and the power recovery control is completed.

  Here, the power restoration control after the main transformer secondary CB of the power receiving and transformation equipment is opened will be described. FIG. 11 and FIG. 12 are diagrams illustrating display examples of the power recovery control after the opening of the main transformer secondary CB of the power receiving and transforming facility in the power receiving and transforming facility operation support system of the present embodiment.

  First, as shown in FIG. 11A, the power to the main systems 10-1 and 10-2 has stopped, and the power is being supplied from the generators 14-1 and 14-2. In this state, the power to the main systems 10-1 and 10-2 is restored, the main transformers 13-1 and 13-2 are restored, and the display unit 63 displays as shown in FIG. The circuit diagram is displayed. Thereafter, the switches 3-8-1 and 3-8-2 are opened, and the high-voltage buses 14-1 and 14-2 operate. The switches 3-5-2 to 3-5-11, 3-6-1 to 3-6-10 are opened, the switches 3-3-1 and 3-3-2 are turned on, and the high-voltage bus 14- is opened. 1 and 14-2 are restored, and a circuit diagram as shown in FIG. The generators 17-1 and 17-2 are stopped, and the switches 3-5-1 to 3-5-11 and 3-6-1 to 3-6-11 are turned on to complete the power recovery control. The display 63 displays a circuit diagram as shown in FIG.

(Training mode)
The user can select the normal mode or the training mode by operating the operation unit 62 of the site monitoring device 6, and when the training mode is selected, the site monitoring device 6 virtually switches the power receiving and substation equipment 2 according to the user's operation. Run the training mode to operate. When the training mode is executed, the on-site monitoring device 6 displays the entire circuit diagram of the power receiving and transforming equipment 2, calculates a circuit corresponding to the virtual ON / OFF operation of the switch 3 of the user, and converts the circuit diagram. And a virtual overall circuit diagram is displayed in response to a further user operation. The operation performed by the site monitoring device 6 in the training mode is basically the same as the normal mode, and has basically the same configuration. However, unlike the normal mode, the power receiving and transforming equipment 2 is not actually operated.

[3. effect]
The effects of the present embodiment as described above will be described. The substation equipment operation support system 1 has a site monitoring device 6 connected to an interface disposed near the switch 3 separately from the central monitoring equipment 5. The on-site monitoring device 6 obtains and calculates parameters of a connection state and an extraction state of the switch 3 and a voltage detection state of the voltage detection device 4 from the switch 3 and the voltage detection device 4 on the power receiving and transforming facility 2. An operation unit 64 that determines the presence or absence of a voltage in a circuit unit separated by the switch 3 on the facility 2, and the presence or absence of a voltage in the circuit unit separated by the switch 3 on the power receiving and substation facility 2 determined by the operation unit 64 And a display unit 63 for displaying

  Therefore, apart from the central monitoring equipment 5, a plurality of site monitoring devices 6 are provided in each part of the power receiving and transforming equipment 2, and the maintenance staff and the like can see the site monitoring device 6 and check the circuit status of the power receiving and transforming equipment 2. Can be grasped, it is possible to perform work such as maintenance after knowing whether or not electricity is flowing to the target circuit, and safety is improved. Based on the pulled-out state of the switch 3, the on / off state of the switch 3, and the presence / absence of a voltage detected by each voltage detection device 4, the presence / absence of the voltage of the circuit divided by the two switches 3 is determined. Since the information is provided to maintenance personnel and the like, the maintenance personnel and the like can work after familiarizing the presence or absence of the voltage of the circuit of the switch 3 to be maintained.

  The calculation unit 64 determines whether or not there is a voltage on one or both of the primary side and the secondary side of the switch 3, and the display unit 63 displays whether or not there is a voltage on both or one of the primary side and the secondary side of the switch 3. Is displayed. Therefore, when performing maintenance of the switch 3, a maintenance person or the like can easily know the voltage state of the primary side and the secondary side of the switch 3 to be maintained, so that the maintenance person or the like is alerted. Things become possible.

  Since the on-site monitoring device 6 is installed near the operation unit of the switch 3, the user can see the on-site monitoring device 6 and grasp the circuit state of the substation equipment 2 when operating the switch 3. This has the advantage of increased safety.

  The computing unit 64 computes and estimates the state of the substation facility 2 after the operation before the switch 3 is operated, and displays it on the display unit 63. Therefore, before the operation of the switch 3 is performed, the circuit state of the power receiving and transforming equipment 2 after execution is estimated and displayed, so that an unexpected state due to an operation error or the like can be prevented.

  When the training mode is selected, the calculation unit 64 simulates a transition of the state of the power receiving and transforming equipment 2 according to the continuous operation of the switch 3 for maintenance, and displays the transition of the state. It is displayed on the section 63. Therefore, by simulating the continuous operation of an arbitrary switch such as maintenance switching, it is possible to perform a simulated state check and training in maintenance operation and the like, and to increase the skill of maintenance personnel and the like.

[Second embodiment]
[1. Configuration operation]
The configuration of the substation facility operation support system 1 of the second embodiment is basically the same as that of the first embodiment. The mobile terminal 20 is used instead of or in addition to the site monitoring device 6. By bringing the mobile terminal 20 to the site and connecting it to the interface near the switch 3, the mobile terminal 20 is configured to perform the same function as the site monitoring device 6.

[2. Effect]
The operation and effect of the present embodiment as described above will be described. The substation equipment operation support system 1 has a mobile terminal connected to an interface arranged near the switch 3 separately from the central monitoring equipment 5. The mobile terminal obtains and calculates parameters of the connection state and the extraction state of the switch 3 and the voltage detection state of the voltage detection device 4 from the switch 3 and the voltage detection device 4 on the power reception and transformation equipment 2, and calculates the parameters. An arithmetic unit for determining the presence or absence of a voltage in a circuit unit separated by the switch 3 above, and the presence or absence of a voltage in a circuit unit separated by the switch 3 on the substation equipment 2 determined by the arithmetic unit is displayed. A display unit.

  Therefore, even if the site monitoring device 6 is not provided in each part of the power receiving and transforming facility 2, the mobile terminal can be brought in and connected to function as the site monitoring device 6 in the same manner. This eliminates the need for installation in each section of the second embodiment, and can reduce costs. In addition, since the mobile terminal can be brought into a place where the site monitoring device 6 is not installed to perform its function, convenience is improved.

  Although several embodiments of the present invention have been described, these embodiments are provided by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in other various forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Transmission and transformation equipment operation support system 2 ... Transmission and transformation equipment 3 ... Switch 4 ... Voltage detection device 5 ... Central monitoring equipment 6 ... Site monitoring device 64 ... Calculation unit

Claims (6)

In a substation equipment operation support system that supports the operation of substation equipment including a plurality of switches and a plurality of voltage detection devices with a central monitoring facility,
Apart from the central monitoring equipment, having a site monitoring device installed near the mobile terminal or the switch that can be transported,
The mobile terminal or the site monitoring device,
From the switch and the voltage detection device on the power receiving and transforming equipment, the switch of on-off state, and the switches from the housing for accommodating whether the switch is pulled out of the drawer state to obtain the parameters, based on the circuit on the parameters and the power receiving and transforming equipment, the switch is in the connected position with respect to the housing, and when the switch is in oN state, the on-off vessel was determined to be in the connected state, if the switch is the near-out position relative to the housing is, and the switch is Ru oN state that is as well as the connection position the switch is to the housing And when the switch is in the off state, the switch is determined to be in the non-connected state, and the presence or absence of the voltage of the circuit unit divided by the plurality of switches on the power receiving and transforming equipment is determined. An arithmetic unit for determining,
Having a display unit for displaying the presence or absence of a voltage of a circuit unit separated by the switch on the power receiving and transformation equipment determined by the arithmetic unit,
Substation equipment operation support system characterized by the following. The arithmetic unit acquires a parameter of a voltage detection state of the voltage detection device, and is connected by a circuit separated by the two switches and a switch in an on state with the circuit , the voltage detection device detecting a voltage. The power receiving and transforming equipment support system according to claim 1, wherein the circuit is determined to have a voltage.   The arithmetic unit determines whether or not there is a voltage on both or one of the primary side and the secondary side of the switch, and the display unit determines both the primary side and the secondary side of the switch determined by the arithmetic unit. 3. The system according to claim 1, wherein the presence or absence of one of the voltages is displayed.   The substation equipment operation support system according to any one of claims 1 to 3, wherein the on-site monitoring device is installed near an operation mechanism of the switch.   After the switch receives the operation command and before executing the operation, the arithmetic unit performs an on / off state of the switch and a withdrawn state of the switch, and a voltage detection of the voltage detection device. Based on a parameter of a state and a parameter after the operation of the switch that receives an operation, a state of the substation equipment after the operation is calculated and estimated, and displayed on the display unit. Item 5. The substation equipment operation support system according to any one of Items 1 to 4.   The arithmetic unit simulates a transition of a state of the power receiving and transforming equipment according to a continuous operation of the switch for maintenance switching when a training mode for virtually operating the power receiving and transforming equipment is selected. The substation equipment operation support system according to any one of claims 1 to 5, wherein a transition of the state is displayed on the display unit by performing an arithmetic operation.