JP2016032346A - Control system of power receiving and distributing system using emergency prompt report - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce unnecessary start-up of an emergency generator, in a control system for starting up the emergency generator upon receiving an emergency prompt report (e.g., emergency earthquake prompt report).SOLUTION: Upon receiving an emergency prompt report, an impact calculation unit 313 determines a supply stop total power value Z of power generation and transmission facilities, that are stopping or expected to stop, with reference to the emergency prompt report and a power generation and transmission facility database 314, sections th control level areas based thereon, determines whether or not start-up of an emergency generator 321 is required based on which control level area a power receiving and distributing facility 32 is located, thus controlling the power receiving and distributing facility 32 including the emergency generator 321.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a control system for power receiving / distributing equipment that uses emergency external news (for example, earthquake, lightning, flooding, tsunami, etc.).

  When a power outage occurs due to a disaster such as an earthquake, the emergency generator is activated to supply power to certain important loads (fire hydrants, automatic fire alarms, sprinklers, emergency lighting, equipment that cannot be stopped, etc.) A system to reduce the number is in practical use. However, the emergency generator takes time to start up, and the voltage and frequency are not stable immediately after starting up, and a short-time power failure cannot be avoided. As a countermeasure against power outages due to earthquakes, there is a control system for power distribution facilities that uses emergency earthquake alerts. Earthquake early warning is information that predicts the arrival time and seismic intensity of strong shaking in each place immediately after the occurrence of an earthquake and informs it as quickly as possible. In this type of control system, an emergency generator is started immediately when an emergency warning (for example, an earthquake early warning) is received, regardless of whether or not a power failure has occurred. The power generator can reach a stable operating state, and it can be switched to the power supply state from the emergency generator before a power outage occurs for important equipment. The influence can be reduced. (Patent Document 1 page 4). Further, when a power failure does not occur after a lapse of time since the operation of the emergency generator is started, energy consumption can be suppressed by stopping the emergency generator (Patent Document 1, page 3).

JP 2009-95073 A

  Conventional control systems for power distribution facilities start emergency power generators when emergency earthquake warnings are received, and take measures to prepare for power outages. Regardless of the expected earthquake intensity and location, Run. However, even when an earthquake early warning is received, the magnitude and location of an earthquake that actually occurs vary, and the possibility of a power outage due to an earthquake depends on the location of the power transmission equipment and the power distribution equipment of the customer. It may be affected by the installation location. In addition, after a large-scale earthquake occurs, aftershocks occur frequently and many emergency earthquake bulletins may be announced. Therefore, if the emergency generator is activated every time an earthquake early warning is received as in the past, the emergency generator is forced to repeatedly start unnecessary use, and the emergency generator is likely to fail. There was a problem that the cost increased. The present invention has been made to solve the above-described problems, and provides a control system for power distribution / distribution equipment that uses emergency warnings to reduce unnecessary activation of an emergency generator.

The control system of the power distribution facility using the emergency bulletin according to the present invention includes a receiving unit that receives emergency bulletin information including the type, occurrence time, occurrence location, and scale of an emergency through the network, and the output and installation of the shipping power facility. A power transmission facility database that stores locations, an influence degree calculation unit that calculates the degree of influence due to a stoppage of the transmission power facility, a control processing unit, and an emergency generator, and receiving and distributing power to be controlled by the control processing unit And when the emergency early warning information is received, the influence calculation unit refers to the emergency early warning information and the dispatched power facility database. The power supply stop power total value of the dispatched power equipment that is stopped or is expected to stop is obtained, and the influence calculation unit demarcates the control level range based on the total power supply stop power value. And determining whether or not the emergency generator needs to be activated depending on which of the divided control level areas the installation location of the power distribution facility is located, and through the control processing unit The power distribution facility including the generator is controlled.

  According to the control system for the power distribution facility using the emergency warning of the present invention, the emergency generator is started according to the degree of the influence of disaster such as earthquake, lightning, flood, tsunami, etc. Startup can be reduced.

It is a system diagram which shows the whole structure of the control system of the power distribution equipment which uses the emergency alert in Embodiment 1 of this invention. FIG. 4 is a sequence diagram showing a processing procedure in the first embodiment. FIG. 4 is an explanatory diagram showing the contents of emergency earthquake bulletin in the first embodiment. It is explanatory drawing which shows the process performed with respect to the power receiving / distribution equipment and load equipment corresponding to the classification and the prediction level of the emergency early warning in Embodiment 1. FIG. It is explanatory drawing which defines the dispatch electric power equipment automatic stop influence index and influence degree in Embodiment 1. FIG. It is explanatory drawing which shows the example of the dispatch electric power equipment automatic stop influence index and influence degree in Embodiment 1. FIG. FIG. 3 is an explanatory diagram illustrating concepts of a safety priority area, a power failure preparation area, and an information collection area in the first embodiment. 4 is a flowchart illustrating the contents of processing performed on a power receiving / distributing facility after receiving an earthquake early warning in the first embodiment.

Embodiment 1 FIG.
In FIG. 1, an emergency bulletin system 1 is a public system that is outside the customer facility 3 and transmits an emergency bulletin to each receiver via a network 2 such as an artificial satellite or the Internet. Specific examples of emergency warnings include earthquake information, tsunami information, volcano information, weather information, and emergency related information transmitted by the nationwide instantaneous warning system.

  The following explanation will be made mainly based on the earthquake early warning, but the same applies to other emergency information. The earthquake early warning is one of the earthquake information. The contents consist of the time of occurrence, the epicenter, the predicted maximum seismic intensity, the area name and seismic intensity with a predicted seismic intensity of less than 5 and the predicted arrival time of the main motion at the registration point. The contents of the earthquake early warning are sequentially updated at intervals of several seconds to several tens of seconds. The earthquake early warning is announced several times (about 5 to 10 times) within a few seconds to 1 minute after the earthquake is detected. The first report gives priority to promptness, and the accuracy of information provided thereafter gradually increases. The final report is announced when the accuracy is considered to be stable, and the provision of emergency earthquake bulletins for the earthquake ends. After sending the earthquake early warning based on the processing result of only one observation point, if the second observation point is not processed even after a predetermined time has passed, it is judged as a shake other than an earthquake (noise) such as thunder. Then, a cancellation report is sent within a few seconds to a few seconds after the announcement.

  In FIG. 1, a customer facility 3 is a facility of a customer who purchases electric power from a commercial power source 4 such as a power company such as a building, a station, a hospital, a factory, or a facility. It consists of equipment 32 and load equipment 33. The power reception / distribution monitoring control device 31 is a device that receives information related to the power reception / distribution facility 32, that is, device status, protection information, measurement values, and the like via a transmission network in the customer facility 3, and monitors and controls the facility. Further, the power reception and distribution monitoring control device 31 includes a reception unit 311, a stop determination unit 312, an influence degree calculation unit 313, a shipping power facility database 314, a control target database 315, a control processing unit 316, and a failure detection unit 317. The stop determination unit 312 performs a process of determining whether or not to stop the emergency generator 321 in preparation for a case where a power failure does not actually occur after the emergency generator 321 is activated.

  The influence degree calculation unit 313 calculates the supply stop power total value Z of the sending power equipment group that is expected to automatically stop with reference to the sending power equipment database 314 based on the level information (for example, seismic intensity) and the epicenter information included in the warning. In addition, a safety priority area d1, a power failure preparation area d2, and an information collection area d3, which will be described later, are set. The control processing unit 316 receives the output of the influence calculation unit 313 and controls each device of the power distribution facility 32 including the emergency generator 321. The failure detection unit 317 detects an abnormality in the commercial power supply. The dispatching power facility database 314 records all the dispatching power plant installation points, supply power, and positions on the power system to which the control system of the power receiving / distribution facility using the emergency alert according to the present invention refers in operation. .

The control target database 315 stores information on the power receiving / distribution equipment 32 and the load equipment 33, for example, power consumption of the load to be controlled, time required for activation, usage, priority within a plurality of loads, and loads to be controlled at the time of receiving an emergency early warning. The process to be executed is stored. FIG. 4 is an explanatory diagram showing the processing contents stored in the control target database 315, and shows the processing to be performed on the power receiving / distributing equipment 32 and the load equipment 33 in accordance with the type of emergency early warning and its predicted level.

  The power distribution facility 32 includes an emergency generator 321, a circuit breaker 322, a transformer 323, and circuit breakers 324 to 326. The circuit breaker 322 is a device that opens and closes a normal load current or an accident current at the time of an accident. The transformer 323 is a device that transforms the system voltage. The load facility 33 is a facility that is a load operated by a customer, and includes an emergency load 331, an air conditioner 332, a lighting facility 333, a load A334, a load B335, and a load C336. The emergency load 331 is, for example, a fire fighting facility (fire hydrant, automatic fire alarm, sprinkler, emergency lighting, etc.). The emergency generator 321 serves as an emergency load 331, a power distribution monitoring control device 31, and other important loads. The commercial power supply 4 supplies power supplied by a power company or the like to the customer facility 3 through the power line 41 during normal times.

  FIG. 3 is an explanatory diagram showing the contents of the earthquake early warning, item No. 1 is the prediction level (for example, seismic intensity), item No. 2 is the occurrence time, and item No. 3 is the epicenter. Item No. 4 is an alarm type, for example, first report, second report, final report, cancel report, and power recovery prediction.

  In normal use in FIG. 1, the power distribution facility 32 receives power from the commercial power supply 4 and supplies power to the load facility 33 for operation. The power distribution / monitoring control device 31 transmits information on the power distribution / distribution facility 32 to the control processing unit 316 to monitor and control the facility. The receiving unit 311 receives the earthquake early warning from the emergency breaking system 1 through the communication lines 21 a and 21 b and the network 2.

  When an emergency earthquake bulletin is issued from the emergency bulletin system 1, for example, when the prediction level included in the emergency earthquake bulletin is Lv5, the impact calculation unit 313 determines whether the dispatched electrical equipment is in accordance with the definition of FIG. The degree of influence in the case of the automatic stop is calculated, and in response to this, the control processing unit 316 activates the emergency generator 321 before the power failure and supplies the emergency load 331 and the power distribution monitoring control device 31 with the emergency generator 321. Decide whether to switch to. Here, the earthquake prediction level Lv may be equivalent to the seismic intensity of the earthquake. Also, magnitude may be used. Moreover, the height of a tsunami may be sufficient. The failure detection unit 317 detects a voltage shortage or frequency abnormality at a power receiving point from the commercial power supply 4 and recognizes the occurrence of a power failure.

  When the emergency generator 321 is activated, the stop determination unit 312 receives the power failure recovery information from the failure detection unit 317, receives the emergency earthquake warning cancellation report, or receives the emergency earthquake warning that is not the cancellation report. When the power failure information is not obtained from the failure detection unit 317 even though a predetermined time has elapsed since the last reception, it is determined that there is no risk of power failure, and the control processing unit 316 determines the emergency load 331 based on the result. And after returning the power supply of the power distribution monitoring control device 31 from the emergency generator 321 to the commercial power supply 4, the emergency generator 321 is stopped.

  FIG. 2 is a sequence diagram showing the processing procedure, and the vertical axis shows the time axis. Each state of the sequence is represented by symbols Stg1 to StgN. It is assumed that power is being supplied from the commercial power source 4 to the load facility 33 through the power distribution facility 32 in the initial state Stg1. Next, it is assumed that the receiving unit 311 receives the emergency earthquake bulletin from the emergency bulletin system 1 at Stg2. The influence degree calculation unit 313 calculates the supply stop power total value Z of the power transmission facility group expected to be automatically stopped by referring to the power transmission facility database 314 based on the level information included in the alarm and the epicenter information, and will be described later. Set the safety priority area and the power outage preparation area. In Stg2.1, the influence calculation unit 313 included in the power distribution monitoring control device 31 activates the emergency generator 321 based on the information from the emergency warning system 1. From Stg3 to Stg3.1, the emergency generator 321 is started, and the voltage of the emergency generator 321 is established at Stg3.2. When the emergency generator 321 is activated, the power distribution / monitoring control device 31 switches its power source to power supply from the emergency generator 321 and inputs the emergency load 331 to the load of the emergency generator 321.

  After starting the emergency generator 321, when power failure recovery information is obtained from the failure detection unit 317, when an emergency earthquake bulletin cancellation report is received, or when an emergency earthquake bulletin that is not a cancellation report is received last When the power failure information is not obtained from the failure detection unit 317 even though the predetermined time has elapsed, the emergency generator 321 operates in accordance with Stg4, Stg5, Stg5.1, Stg5.2 included in the stop determination process 318 of FIG. Stopped.

  FIG. 7 is an explanatory diagram showing the concept of a safety priority area, a warning area, and an information collection area. When the earthquake early warning is received, the impact calculation unit 313 sets a circular safety priority area d1 centered on the epicenter 701 as shown in FIG. 7 if there is an epicenter with a prediction level Lv of 5 or more, for example. . Or it is good also considering the circular area | region centering on the point whose prediction level Lv is 5 or more, for example as the safety priority area d1. Safety priority area d1 is an area where seismic intensity is expected to be 5 or more, and at the points included in safety priority area d1, it is assumed that the shipping power facility will automatically stop the shipping power when each facility receives the earthquake early warning To do. The radius of the safety priority area d1 is determined in consideration of safety, but may be 50 km, for example. If it is determined from the contents of the emergency earthquake bulletin that there are a plurality of epicenters having Lv of 5 or more, a plurality of safety priority areas d1 may be set. In this case, an area belonging to any of the plurality of safety priority areas d1 is set as a composite safety priority area. The shape of the synthetic safety priority area is not limited to a circle.

  FIG. 5 is an explanatory diagram for defining the degree X of the automatic stoppage of the shipping power facility. Z is the safety priority area d1 shown in FIG. 7, that is, the total power supply stop power value of the power transmission equipment group that is supposed to be automatically stopped, that is, the power supply power that is expected to be lost due to the situation shown in the emergency early warning information. Show. The dispatch power facility automatic stop influence degree X is determined by the value of Z. A1 to A3 are threshold values. The threshold values A1 to A3 and the X values X1 to X3 corresponding to the threshold values may be determined based on the stoppage state of the shipping power facility that has occurred in the past disaster.

  FIG. 6 shows an example of the dispatch power facility automatic stop influence degree X. If the expected power stoppage power supply total value Z of the dispatch power facility is less than 5 million kW, the dispatch power facility automatic stop influence degree X is 100. It becomes. When Z is 5 million kW or more and less than 10 million kW, X is 300, and when Z is 10 million kW or more and less than 15 million kW, X is 500.

  In FIG. 7 again, d2 is a power failure preparation area, which is set outside the safety priority area d1 and is extended by [X * Y] km from the outer periphery of the safety priority area d1. X is the power transmission facility automatic stop influence degree shown in FIG. Y is a proportionality constant, and may be determined based on the status of stoppage of shipping power facilities that occurred in past disasters. Y may be 1, for example. For example, when an earthquake with a seismic intensity of 5 or more occurs in the disaster occurrence area and the total supply stop power value Z of the power station that automatically stops is Z = 13 million kW, X = 500 km. Accordingly, d2 is a region that is expanded by [500 km * 1] from the boundary line of the outer periphery of d1.

  d3 is an information collection area, which includes the safety priority area d1 and the area including all the installation locations of the dispatch power equipment included in the dispatch power equipment database 314 and the area including the installation locations included in the control target database. This is the remaining area excluding the power failure preparation area d2. The impact calculation unit 313 sets the safety priority area d1, the power failure preparation area d2, and the information collection area d3 each time an emergency earthquake warning is received. It is desirable that the time required for the influence degree calculation unit 313 to set the safety priority area d1 and the power failure preparation area d2 is shorter than the time during which a strong shake is expected from the time when the earthquake early warning is received. 702A to 702C are power receiving / distributing facilities, 703-1 to 703-n are shipping power facilities, and 704-1 to 704-3 are boundaries.

FIG. 8 is a flowchart from the reception of the earthquake early warning to the setting of the content of the processing to be performed on the power receiving / distributing equipment, which is composed of stages S1 to S12. When the receiving unit 311 receives the earthquake early warning in S2, the influence calculation unit 313 determines in S3 whether there is a point having a seismic intensity of 5 or more in the emergency earthquake warning, and if there is, the seismic intensity is 5 or higher in S4 and S5. Get seismic intensity and coordinates of N points. Here, N may be 1. In S6, N circular safety priority areas d1 centering on the epicenter 701 are set from the seismic intensity and coordinate information of N points. The radius and center coordinates of each safety priority area d1 are obtained, and a composite safety priority area is obtained by superimposing the safety priority areas for N points. In S7, the outputs of all the dispatching power facilities existing within the combined safety priority area are totaled to obtain the supply stop power total value Z. The power transmission equipment automatic stop influence degree X is calculated from the supply stop power total value Z.
In S <b> 8, the influence degree calculation unit 313 sets the next region from the dispatch power facility automatic stop influence degree X and the parameter Y. That is, the area where seismic intensity 5 or more is expected is designated as the safety priority area d1, the area extended by [X * Y] km from the outer circumference of d1 is designated as the power outage preparation area d2, and An area obtained by removing d1 and d2 from the area including the installation point is defined as an information collection area d3.

  In S <b> 9, the influence calculation unit 313 determines whether the power distribution monitoring control device 31 including itself is in d <b> 1, d <b> 2, or d <b> 3. When it is in d1 or d2, the influence calculation unit 313 activates the emergency generator 321 in S10 or S11, and switches the power supply of the power distribution monitoring control device 31 including the emergency load 331 and itself to the emergency generator 321. In preparation for a power failure, the loads other than the emergency load 331 are cut off. If the influence calculation unit 313 determines in S9 that the power distribution monitoring control device 31 including itself is in the information collection area d3, the emergency generator 321 is not activated in S12. In either case, the process returns to S2 and the receiving unit 311 continues to stand by to prepare for the emergency earthquake warning.

  After starting the emergency generator 321 in S10 or S11, when the power failure recovery information is obtained from the failure detection unit 317, or when the emergency earthquake warning cancellation report is received, or the emergency earthquake warning that is not the cancellation report When power failure information is not obtained from the failure detection unit 317 even after a predetermined time has elapsed since the reception, the emergency generator 321 is stopped, and all of the outputs including the emergency load 331 and the power distribution monitoring control device 31 are included. Is connected to the commercial power source 4.

  In the first embodiment, the power distribution / monitoring control device 31 including the influence calculation unit 313, the power distribution / distribution facility 32, and the load facility 33 are in the same place, but the influence calculation unit 313 is not limited to this. The power reception / distribution monitoring control device 31 may be located in a place different from the power distribution / distribution facility 32 and the load facility 33. In this case, when the power distribution / monitoring control device 31 is in the information collection area d <b> 3, the power distribution / monitoring control device 31 does not need to receive power from the emergency generator 321.

  Further, in the first embodiment, one set of the power reception / distribution monitoring control device 31 including the influence calculation unit 313, the power distribution / distribution equipment 32, and the load equipment 33 is provided. The control device 31 and a plurality of sets of power receiving / distributing equipment 32 and load equipment 33 may be provided correspondingly. In this case, one set of the power distribution / monitoring control device 31 is included in any of the safety priority area d1, the power failure preparation area d2, and the information collection area d3 with respect to a plurality of power distribution facilities 32 and load facilities 33. The emergency generator 321 and the load of each set are controlled on the basis of whether or not they are connected.

  In the first embodiment, the power distribution / monitoring control device 31, the power distribution / distribution facility 32, and the load facility 33 constitute the customer facility 3 and are under the same organization, that is, the customer's management. The power reception / distribution monitoring and control device 31 may be operated by an organization other than the consumer such as an electric power company.

  The control system of the power distribution facility using the emergency bulletin according to the present invention includes a receiving unit that receives emergency bulletin information including the type, occurrence time, occurrence location, and scale of an emergency through the network, and the output and installation of the shipping power facility. A power transmission facility database that stores locations, an influence degree calculation unit that calculates the degree of influence due to a stoppage of the transmission power facility, a control processing unit, and an emergency generator, and receiving and distributing power to be controlled by the control processing unit And when the emergency early warning information is received, the influence calculation unit refers to the emergency early warning information and the dispatched power facility database. The power supply stop power total value of the dispatched power equipment that is stopped or is expected to stop is obtained, and the influence calculation unit demarcates the control level range based on the total power supply stop power value. And determining whether or not the emergency generator needs to be activated depending on which of the divided control level areas the installation location of the power distribution facility is located, and through the control processing unit Since the power distribution facility including the generator is controlled, maintenance costs are reduced by reducing unnecessary activation of the emergency generator. In the present invention, the embodiments can be appropriately modified and omitted within the scope of the invention.

1 Emergency warning system,
2 network, 21a-21d communication line,
3 customer facilities, 31 power distribution and monitoring equipment,
311 reception unit, 312 stop determination unit,
313 Influence calculation unit, 314 Shipping power equipment database,
315 control target database, 316 control processing unit,
317 failure detection unit, 318 stop determination process,
32 power distribution facilities, 321 emergency generators,
322 circuit breaker, 323 transformer,
324-326 circuit breaker, 33 load equipment,
331 emergency load, 332 air conditioner,
333 lighting equipment, 334 load A,
335 Load B, 336 Load C,
4 commercial power supply, 41 power line,
701 epicenter, 702A power distribution facility,
702B Power distribution facility, 702C Power distribution facility,
703-1 Shipping power equipment, 703-2 Shipping power equipment,
703-3 shipping power equipment, 703-n shipping power equipment,
704-1 boundary 704-2 boundary 704-3 boundary d1 safety priority area, d2 power outage preparation area d3 information collection area

Claims (5)

A receiving unit for receiving emergency breaking information including the type, occurrence time, occurrence location, and scale of an emergency through a network;
A dispatch power facility database for storing the output and installation location of the dispatch power facility;
An impact calculation unit that calculates the impact due to the suspension of the dispatched electrical equipment;
A control processing unit;
Power receiving and distribution equipment including an emergency generator, which is a control target of the control processing unit,
A load facility that receives power from the power distribution facility;
Have
When the emergency early warning information is received, the influence calculation unit refers to the emergency early warning information and the shipping power facility database, and is the total power supply stop power value of the shipping power facility that is stopped or expected to stop Seeking
The influence calculation unit divides a control level area based on the total supply stop power value, and the installation location of the power distribution facility depends on which of the divided control level areas the control level area is the control level area. A control system for power receiving and distribution equipment using emergency alerts, which determines whether or not an emergency generator needs to be started and controls the power receiving and distribution equipment including the emergency generator through the control processing unit. The control level area has a safety priority area, a power outage preparation area, and an information collection area,
The safety priority area is an area in which the power transmission equipment in the area is stopped and the emergency generator is started,
The power outage preparation area is an area where the emergency generator is started without stopping the power transmission equipment in the area,
2. The control system for power distribution / distribution equipment using emergency warning according to claim 1, wherein the information collection area is an area in which the emergency power generator is not started without stopping the power transmission equipment in the area. .   The power outage preparation area is outside the boundary of the safety priority area, the information collection area is outside the boundary of the power outage preparation area, and the distance of the power outage preparation area from the boundary of the safety priority area is The control system for receiving and distributing equipment using the emergency warning using the emergency warning according to claim 2, wherein the control system is determined based on a total supply stop power value of the equipment.   The distance of the power outage preparation area from the boundary of the safety priority area increases as the total power supply stoppage value of the dispatching power facility increases. Control system.   The control system for power distribution and distribution equipment using emergency early warning according to any one of claims 1 to 4, wherein the type of emergency is earthquake or tsunami.