JP2014033511A - Power distribution management system and method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent voltage reduction in a power distribution network which is caused by connection of an apparatus (e.g. quick charger) having high system load.SOLUTION: When a new quick charger is added at a charge station (charge ST), addition of the quick charger is notified to a power distribution management system through a charge ST management center. Thereby, the power distribution management system can detect the installation of the quick charger. The power distribution management system calculates the maximum power which can be supplied to the new quick charger after checking a power supply state in each section of the power distribution network. By transmitting the maximum power through a charge management system, the maximum power can be notified to the charge ST. Moreover, by observing the value, instability of the power distribution network due to charge of the quick charger can be prevented. When facility of the power distribution network is updated and connection of the power distribution network is changed on the power distribution management system side, to each charge ST, the maximum power in a path to the charge ST from a power distributing substation is investigated, and, when the maximum power is changed, the update of the maximum power is notified to the charge ST side according to the change.

Description

  The present invention relates to a local power distribution management system and a local power distribution management method.

  A power distribution system is a system that supplies electric power received from a power transmission network to a consumer such as a house or a building after the voltage is once lowered at a substation. This system is composed of a large number of devices and subsystems, and is largely a distribution network composed of power lines, changeover switches, transformers, etc. that actually supply power, a distribution management system that controls the flow of power, and It consists of an equipment management system that manages equipment such as distribution lines. Since the power distribution network widely supplies power to all customers in the region, the power line extending from the substation branches several times along the way and extends the branch line in the region. Moreover, in order to prevent a power outage widely in units of power lines, not only simply branches but also spreads sometimes connecting with other power lines. Several tens to thousands of customers are connected to one distribution line extending from the substation. In some cases, the capacity of the distribution network has been designed and maintained up to some percent of the maximum power consumption of all consumers so far (this is called the demand rate). This is because, from experience, all customers do not use the upper limit of the power reception contract at the same time, and there are purposes to reduce the capital investment cost of the distribution network. In addition, power receiving facilities (meters, breakers), etc., of consumers are connected to the branch destinations of the distribution network, and thus consumers are supplied with electricity. A breaker, which is one of power receiving facilities of a customer, determines a rated capacity based on an electricity supply contract. For example, in the case of Japan, ordinary households choose one of the rated capacities set for each 10A from 20A to 60A.

  The power consumption used by customers under the distribution network has been changed in rated capacity due to the moving of customers. Patent Document 1 is characterized in that the rated capacity of these breakers can be changed remotely without the person in charge of the facility of the power company going to the site. In Patent Document 2, an apartment house is assumed, and the rated capacity can be changed remotely with respect to the breakers of each house after collectively receiving power in units of the apartment house.

Japanese Laid-Open Patent Publication No. 2002-159138 JP 2004-153963 PR

  However, in the prior art, the upper limit of power consumption is changed only by changing the breaker of the power receiving equipment, without considering the capacity of the distribution network. This is because there is usually a premise that the change in consumer power consumption is negligibly small compared to the capacity of the distribution network. For example, changing the rated power of a house from 20A to 60A will only change about three times at most, and the impact will be negligible for a distribution network with hundreds of consumers connected.

  However, with the advent of electric vehicles (EVs) in recent years, quick chargers that consume more than tens of houses in one house have appeared. Rapid chargers are currently planning to build a charging station (hereinafter referred to as “charging ST”) in the city and place several rapid chargers to enable rapid charging of multiple EVs at the same time. When such a charging ST appears, the impact on the power distribution network will not be negligible. Especially when the demand rate of the power distribution network is designed to be low, charging will be performed below the rated capacity of the charging ST. However, depending on the power consumption situation under the distribution network, power exceeding the designed demand rate is required, and in the worst case, it may lead to a power failure of the entire distribution network. To solve this problem, it is necessary to make an inquiry to the power distribution management system by using IT before the quick charger operates to determine whether or not the connection is possible. It is also necessary to be able to comply with the judgment results using IT.

  The present invention is for solving the above-mentioned problems. A new charging ST management system is prepared between the charging ST and the distribution management system, and the device information of the charger from the charging ST is automatically transmitted to the distribution management system. To determine if there is any impact on the distribution network. In addition, the charging ST management system is used to automatically notify the charging ST of the maximum usable power from the power distribution management system.

  According to the present invention, power destabilization of the distribution network can be quickly prevented by rapid charging of the charging ST.

The figure which shows the cooperation structure of the power distribution management system and charge ST management system of this invention Diagram showing device configuration and functional configuration of charging ST Diagram showing the functional configuration of the charging ST management system Diagram showing the functional configuration of the power distribution management system Sequence diagram when transmitting device information from the charging ST to the power distribution management system Sequence diagram when sending instruction information from the power distribution management system to the charging ST management system Sequence diagram when sending instruction information from charging ST management system to charging ST Sequence diagram when operating the quick charger in charging ST Figure showing an overview of the distribution network Sequence diagram when the status of the distribution network changes

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The parts denoted by the same reference numerals represent the same items, and the basic configuration and operation are the same.

  FIG. 1 is a diagram showing a cooperative configuration between a power distribution management system and a charging ST management system according to the present invention. In the figure, the solid line indicates the power line, and the dotted line indicates the information line.

  The cooperative configuration of the present invention mainly includes a charging ST 104, a charging ST management system 110, and a power distribution management system 109. As peripheral equipment and facilities, there are a distribution substation 101, a distribution network 102, a customer 103, a breaker 105, a quick charger 106, a new quick charger 107, a network 108, a power sensor 111, and a transformer 112.

  The distribution substation 101 is a facility for supplying electricity to the distribution network 102. The distribution substation 101 supplies power under the control of the distribution management system 109.

  The power distribution network 102 is a line for supplying power. A distribution network 102 extends from the distribution substation 101, and is connected to the customer 103 and the charging ST 104 via the transformer 112. Thereby, electric power is sent from the distribution substation 101 and supplied to the customer 103 and the charging ST 104.

  The customer 103 and the charging ST 104 are consumers that are moved by the electric power supplied from the distribution network 102 (the charging ST is also a customer, but in this specification, the charging ST is explicitly divided for easy explanation. ). A breaker 105 is provided at a connection point between the customer 103 and the charging ST 104. When power exceeding the rated capacity is used on the customer side, the breaker 105 is cut off. A quick charger 106 is installed in the charging ST 104. Also, a new quick charger 107 may be newly installed depending on the usage status of the charging ST 104. The present invention aims to stabilize the distribution network 102 against the sudden increase in power consumption caused by the installation of such a new quick charger. As another example of the embodiment of the present invention, it is aimed to stabilize the power distribution network 102 when an EV having a very large charge amount with respect to the quick charger tries to perform quick charge. The charging ST 104 is connected to the charging ST management system 110 via the network 108 and provides information to the charging ST management system 110, and conversely receives information from the charging ST management system 110.

  The distribution management system 109 performs control in order to stabilize the voltage of the distribution network after grasping the status of the distribution substation 101 and the distribution network 102. The power distribution management system 109 manages information on facilities and devices in the power distribution network. For example, when the equipment of the power distribution network is updated, the equipment update information can be grasped by the power distribution management system.

  The charging ST management system 110 is linked to the power distribution management system 109 via the network 108. Thereby, the status of the charging ST is transmitted to the power distribution management 109 system. Conversely, the instruction information from the power distribution management system 109 is received. In addition, the charge management system 110 is connected to the network 108 as well as the charge ST 104. The flow of this information is as already described in charging ST104.

  FIG. 2 is a diagram illustrating a device configuration and a functional configuration of the charging ST. The power sent from the distribution network 102 is sent to the PCS 202 via the breaker 105 and the distribution board 201. The PCS 202 is connected to the quick charger 106 and the new quick charger 107 by controlling the start and stop of power supply by a charge ST 104 described later. PCS 202 sends PCS status information to charging ST 104 via device network 203. Conversely, a device command is transmitted from the charging ST 104 to the PCS 202. Hereinafter, the function of the charging ST 104 will be described.

  The device communication processing unit 204 is a function for performing communication with the PCS 202. Communication between the PCS 202 and the charging ST 104 is performed by the device communication processing unit 204.

  The device DB 205 is a DB that accumulates PCS status information. The breakdown of PCS status information includes device information indicating the characteristics of the device itself and device operation information. In the device DB 205, device information is registered, and device operation information is registered as a device operation history. In addition, the device information may be registered in the device registration unit 206 as additional information that does not come from the device (eg, installation location, administrator).

  The charging ST information creation unit 207 has a function of converting information in the device DB 205 into a communication message. The information in the power status DB 210 is also converted into a communication message.

  Server communication processing unit 208 communicates with charging ST management system 110. Server communication processing unit 208 also receives a communication message transmitted from charging ST management system 110.

  The power registration confirmation unit 209 registers the maximum power instructed from the charging ST or confirms the registered maximum power. Also, register or check the power consumption currently used by the quick charger.

  The power status DB 210 registers the maximum power that can be used in the charging ST and the power consumption currently in use.

  The charge determination unit 211 is a function that determines the power control content for each PCS. The charging determination unit 211 makes a determination based on the contents of the power status DB 210, the charger operation plan DB 214, and the charging instruction unit 215.

  The device control command creation unit 212 creates a device command based on the charging determination result. The device command is transmitted from the device communication processing unit 204 to the PCS.

  The charging instruction unit 215 is a function that receives a charging instruction from the user and manager of the charging ST and causes the charging determination unit 211 to make a charging determination.

  FIG. 3 is a diagram illustrating a functional configuration of the charging ST management system 110. The charge ST management system is a system for grasping the status of each charge ST and instructing each charge ST in some cases. The charging ST management system 110 includes a charging ST communication processing unit 301, a charging ST information analysis unit 302, a supplementary information addition unit 303, a device DB 304, a power system communication processing unit 305, a power system instruction analysis unit 306, and a power system instruction creation unit 307. The application unit 308 is configured.

  Charging ST communication processing unit 301 communicates with charging ST 104. The information flow is as described in the server communication processing unit 208.

  Charging ST information analysis unit 302 has a function of analyzing a communication message from charging ST 104. Here, when the communication message includes update information of the device information of the charging ST, the device information is transmitted to the supplementary information adding unit 303.

  The supplementary information adding unit 303 attaches additional information to be transmitted to the power distribution management system 109 to the device information sent from the charging ST. For example, since it is necessary for the power distribution management system 109 to grasp the device location information, the device location information is acquired from the device DB 304 and added.

  The device DB 304 manages information on devices under charge ST management as a charge ST management system. For example, device location information as described above, maintenance information such as the device installation date and device component replacement date is registered, and device management and the like are performed by an application unit described later.

  The power system communication processing unit 305 is a function for communicating with the power distribution management system 109. The power system instruction analysis unit 306 has a function of receiving a communication message from the power distribution management system 109 and analyzing the contents. If an instruction is necessary for the charging ST as a result of the analysis, instruction information is sent to the power system instruction creating unit 307.

  The power system instruction creating unit 307 converts the instruction content to be transmitted to the charging ST 104 into a communication message. The converted communication message is communicated by the charging ST communication processing unit 301.

  The application unit 308 indicates various applications of the charging ST management system. For example, a maintenance application is applicable.

  FIG. 4 is a diagram showing a functional configuration of functions necessary for the present invention in the power distribution management system. As has been clarified in the problem to be solved by the invention, there are many existing power distribution management systems, and in order to minimize the modification of the existing system, the conventional function is linked with the DB. ing. The charge ST management corresponding unit 400 is the main functional configuration of the present invention. The charging ST management correspondence unit 400 includes a charging ST communication processing unit 401, a charging ST management information analysis unit 402, a distribution network position estimation unit 403, a distribution route setting unit 406, a maximum power calculation unit 407, a charging ST instruction creation unit 410, a maximum The power DB 414 is configured. In addition, the power distribution management system 109 according to the present invention includes a power distribution application 405, a power distribution network connection information analysis unit 412 and a power grasping unit 409, which are existing functions, and a power distribution network information DB 404, power distribution network power history information, which are functions of the present invention. A DB 408, a distribution network connection information DB 411, and a charging ST management corresponding unit 400 are configured.

  The charging ST management communication processing unit 401 has a function of receiving information from the charging ST management system 110 and conversely transmitting information to the charging ST management system 110.

  Charging ST management information analysis unit 402 has a function of analyzing a communication message sent from charging ST management system 110.

  The distribution network position estimation unit 403 has a function of estimating a position in the distribution network when device information of the charging ST is transmitted from the charging ST management system 110. The device information includes the position information of the charging ST, and the position information and the information of the distribution network information DB 404 are added together.

  The distribution route estimation unit 406 has a function of estimating the connection route between the charging ST and the distribution substation 101 based on the current distribution network connection information obtained from the distribution network connection information DB 411. For example, as to the shape of the distribution network, as shown in FIG. 9, when there are a plurality of distribution substations 901 and 902, the current state of the SWs 906 and 912 is acquired from the distribution network connection information DB 411, and the charging ST 104 It is determined whether or not the power supply is received (in FIG. 9, the power supply is received from the distribution substation 903).

  The maximum power calculation unit 407 calculates the maximum power that can be supplied by each power line of each route based on the estimated distribution route and the distribution network power history information DB 408. The calculation result is registered in the maximum power DB 414.

  The power grasping unit 409 is a function for grasping the power supply status on the distribution network from various distribution devices 413 in the distribution network form. The grasp result is registered in the distribution network power history information DB 408.

  The charging ST instruction creating unit 410 has a function of creating a communication message of instruction information based on the maximum power calculated by the maximum power calculating unit 407 and transmitting it to the charging ST management communication processing unit 401.

  The distribution network connection information update unit 412 updates the connection status based on the status of the devices on the distribution network transmitted from the power distribution device 413. For example, in FIG. 9, the connection status of the SWs 906 and 912 is grasped and the connection status of the distribution network is registered.

  A power distribution device 413 indicates a device under management of power distribution. For example, SW on the distribution line, power sensor, etc. are applicable.

  The various systems described in FIGS. 2 to 4 are linked as shown in FIG. 1 to stabilize the power distribution network 102. FIG. 5 to FIG. 8 and FIG. 10 show the processing sequence, and the sequence will be described below.

  FIG. 5 is a sequence diagram when device information is transmitted from the charging ST to the power distribution management system. When the new quick charger 107 is connected in the charging ST 104 (step 501), the new quick charger is connected (step 502).

  Specifically, device information received from the device communication processing unit 204 and device information registered by the device registration unit 206 are registered in the device DB 205. Next, the charging ST information creation unit 207 and the server communication processing unit 208 are used to convert the device information into a communication message and transmit the device information (step 503).

  When the communication message is received by charging ST management system 110 (step 504), information analysis is performed by the charging ST information analysis unit (step 505). If the content of the communication message is device information update information, supplemental information for transmission to the power distribution management system 109 is added (step 506). The supplemental information corresponds to device location information. Then, device information is transmitted using the power system communication processing unit 305 (steps 507 and 601). Here, as soon as it is detected that the device information has been updated, supplementary information is added and notified to the power distribution management system. Usually, the details of the device information are registered before notification, but time distribution is prioritized and only the information necessary for the minimum processing is added and transmitted. Thereafter, the device information is registered in the storage unit (step 508).

  FIG. 6 is a sequence diagram when instruction information is transmitted from the power distribution management system to the charge ST management system. When a communication message is received from the charging ST management system to the power distribution management system 109 (step 601), it is analyzed whether the content of the communication message includes device information (step 602). If the device information is included, the position of the charging ST on the distribution network is estimated based on the distribution network information DB 404 based on the position information in the device information (step 603).

  Then, the distribution route from the current distribution substation is estimated based on the position on the distribution network and the distribution network connection information in the distribution network connection information DB 411 (step 604). Based on the distribution route, the maximum power that can be supplied from the substation to the charging ST is calculated (step 605). In the example of FIG. 9, for example, each power line between the power sensors 909-910, 910-913, 913-914, and 914-908 can be said to be a power line related to this distribution route. The maximum power that can be supplied is calculated from the information of each power line. Specifically, the smallest power among these power lines, that is, the power at the neck portion is set as the maximum power. The calculation result is registered in the maximum power DB 414.

  When future demand prediction is possible, when the distribution network power history information DB has history information as a function of time axis as well as a specific time, or after switching the distribution network section switch after a predetermined time When it can be predicted that a certain part will change, the maximum power can be calculated by specifying the time width. Here, the fact that the maximum power has a time width means that the calculated maximum power is effective in the time width. You can set the time width to specify the start time and end time, such as “from 13:00 to 15:00”, or set the time width to “2 hours from now”. May be.

  Based on the calculated maximum power, the maximum power that can be quickly charged with respect to the charging ST is used as instruction information, which is converted into a communication message (step 606). Then, the communication message is transmitted as instruction information (steps 607 and 608).

  FIG. 7 is a sequence diagram when instruction information is transmitted from the charge ST management system to the charge ST. When a communication message is received by the charging ST management system (step 608), the communication message is analyzed to analyze the instruction information (step 701). If the instruction content is the maximum power for the charging ST, instruction information is generated for the charging ST and a communication message is created (step 702).

  The completed communication message is transmitted to charging ST 104 (step 703). In charging ST, a communication message is received (step 704), and when the content of the communication message is maximum power, it is updated and registered as the maximum power used in charging ST (step 705). Specifically, when the communication message is received by the server communication processing unit 208 and the power is the maximum power, the power registration DB 209 updates the power status DB 210. In addition, when there is a time width designation regarding the setting of the maximum power in the communication message content, it is transmitted to the charging plan planning unit 213 to review the charging plan.

FIG. 8 is a sequence diagram when the quick charger is operated in the charging ST. If the new quick charger 107 needs to be quickly charged, a charge request is transmitted from the new quick charger (step 801). As a transmission method, there are a case where transmission is performed from the PCS 202 and a case where the transmission is supported from the charging instruction unit 215. When a charge request is received in charge ST 104 (step 802), confirmation of maximum power is confirmed by the power registration confirmation unit 209 (step 803), actual power consumption is determined, and registration is performed (step 804). Information to be registered is also registered in the power status DB 210 by the power registration confirmation unit 209. Then, a device command to be transmitted to the new quick charger 107 is created (step 805), and the device command is transmitted (step 806). The new quick charger 107 receives the device command and performs quick charging with the specified power.
When charging is completed, the charging end is notified to the charging ST (step 808). When the end of charging is received (step 809), the current used power is registered by subtracting the used power for the amount of charge used (step 810). The current power consumption may be registered based on the measurement information with a separate sensor installed on the distribution board.

  FIG. 9 is a diagram showing an outline of the distribution network. In this figure, there are two distribution lines for the charging ST 104, and one of them is switched and used. Distribution is composed of consumers such as distribution substations 901, 902, distribution networks 902, 904, power sensors 905, 907, 908, 909, 910, 911, 913, 914, SW 906, 912, and charging ST104. Among these, the state of each power sensor and SW is managed by the power distribution management system, and a request for power suppression is made to the charging ST management system or the like as necessary for power tightness. By grasping from which distribution substation the supply is received as shown in this figure, the maximum power additionally received from the supply can be calculated. In this embodiment, the upper limit of the quick charging power of the charging ST is determined by the power, but there are other cases where it is determined by the current. Even in such a case, stabilization of the distribution network can be realized by calculating the maximum current in the same procedure as in the present embodiment and keeping the maximum current under the maximum current.

  FIG. 10 shows a sequence for updating the maximum power of the charging ST when the equipment on the distribution network is updated or when the SW on the distribution line is switched to change the distribution network route. First, the distribution connection information is updated by the distribution application 405, the distribution device 413, the distribution facility management system 415, and the like (step 1001). Next, the distribution route is estimated again how the distribution route has changed (step 604). If there is a change in the power distribution route, processing similar to that in step 605 in FIG. 6 is performed, and notification of maximum power is performed on the charging ST side.

101 Distribution Substation 102 Distribution Network 103 Customer 104 Charging ST
105 Breaker 106 Quick Charger 107 New Fast Charger 108 Network 109 Power Distribution Management System 110 Charging ST Management System 111 Power Sensor 112 Transformer 201 Distribution Board 202 PCS
204 Device communication processing unit 205 Device DB
206 Device registration unit 207 Charging ST information creation unit 208 Server communication processing unit 209 Power registration confirmation unit 210 Power status DB
211 Charging determination unit 212 Device control command creation unit 213 Power generation plan planning unit 214 Charger operation plan 301 Charging ST communication processing unit 302 Charging ST information analysis unit 303 Supplementary information adding unit 304 Device DB
305 Electric power system communication processing unit 306 Electric power system instruction analysis unit 307 Electric power system instruction creation unit 308 Application unit 400 Charging ST management correspondence unit 401 Charging ST management communication processing unit 402 Charging ST management information analysis unit 403 Distribution network position estimation unit 404 Distribution network Information DB
405 Distribution application 406 Distribution route estimation unit 407 Maximum power calculation unit 408 Distribution network power history information DB
409 Power grasping unit 410 Charging ST instruction creating unit 411 Distribution network connection information DB
412 Distribution Network Connection Information Update Unit 413 Distribution Equipment 414 Maximum Power DB
901 Distribution substation 902 Distribution network 903 Distribution substation 904 Distribution network 905 Power sensor 906 SW (switch, hereinafter referred to as SW)
907 Power sensor 908 Power sensor 909 Power sensor 910 Power sensor 911 Power sensor 912 SW
913 Power sensor 914 Power sensor

Claims (12)

A power distribution management system for determining a maximum power consumption at a charging station to which a plurality of chargers are connected,
A charging station communication processing unit that receives position information of the charging station and information of the charger connected to the charging station or information of an electric vehicle connected to the charger from the charging station;
A distribution network position estimation unit that estimates a position of the distribution network of the charging station based on the received information;
A distribution route estimation unit for estimating a distribution route from the estimated distribution network position;
A maximum power calculator that calculates the maximum power consumption at the charging station based on the power distribution route;
A power distribution management system comprising: In the power distribution management system according to claim 1,
The charging station communication processing unit transmits information on the calculated maximum power consumption to the charging station. In the power distribution management system according to claim 2,
The power distribution management system, wherein the maximum power calculation unit calculates the maximum power consumption based on a power distribution route from a substation to the charging station. In the power distribution management system according to claim 3,
The maximum power calculation unit calculates the maximum power consumption of the distribution route based on a power value indicated by a power sensor installed in the distribution network. The power distribution management system according to claim 4, comprising a plurality of the power sensors,
The maximum power calculation unit calculates a maximum power consumption based on a smallest value among power values indicated by power sensors related to the distribution route among the plurality of power sensors. system. The power distribution management system according to claim 3 includes history information of a value of power flowing through the section for each section constituting the power distribution network,
The power distribution management system, wherein the maximum power calculation unit calculates the maximum power consumption from history information of a section related to the power distribution route. In the power distribution management system according to any one of claims 2 to 6,
The maximum power calculation unit calculates a time during which the value of the maximum used power is valid,
The power distribution management system, wherein the charging station communication processing unit transmits a time during which the value of the maximum power consumption is valid to the charging station. A power distribution management method for determining a maximum power consumption in a charger station to which a plurality of chargers are connected,
Information receiving step for receiving, from the charging station, position information of the charging station, information on the charger connected to the charging station or information on an electric vehicle connected to the charger,
A distribution network position estimating step for estimating a position of the distribution network of the charging station based on the received information;
A distribution route estimation step of estimating a distribution route from the estimated position of the distribution network;
A maximum power calculating step for calculating a maximum power consumption at the charging station based on the power distribution route;
A transmission step of transmitting information on the calculated maximum power consumption to the charging station;
A power distribution management method comprising: The power distribution management method according to claim 8,
The maximum power calculation step calculates the maximum power consumption based on a distribution route from a substation to the charging station. In the power distribution management method according to claim 9,
The maximum power calculating step includes the maximum power consumption of the power distribution route based on the power value indicated by a power sensor installed in the power distribution network or the history information of the power value flowing through each section constituting the power distribution network. A power distribution management method characterized in that The power distribution management method according to claim 10,
When there are a plurality of the power sensors,
The maximum power calculation step calculates the maximum power consumption based on a smallest value among power values indicated by power sensors related to the distribution route among the plurality of power sensors. Management method. In the power distribution management method according to any one of claims 8 to 11,
The maximum power calculating step calculates a time during which the value of the maximum used power is valid,
In the power transmission management method, the transmission step transmits a time when the value of the maximum power consumption is valid to the charging station.

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