JP2019009997A - Power management system and apparatus mounted with storage battery, ems controller, and power management server - Google Patents

Abstract

To provide an apparatus mounted with a storage battery that can reduce a process load at a server side of a power management system and can be stably operated even when a communication failure occurs.SOLUTION: In a power management system in which a loading device connected to a power system 10 and an apparatus 20 mounted with a storage battery, equipped with a charging/discharging control device 26 that controls a storage battery 23 connected to the power system 10 and charging and discharging of the storage battery 23 according to predetermined charging/discharging algorithm, are connected to an EMS controller 31 through a network, the EMS controller 31 transmits the charging/discharging algorithm for the apparatus 20 mounted with the storage battery to the charging/discharging control device 26 through the network. The charging/discharging control device 26 holds the transmitted charging/discharging algorithm and performs charging/discharging operation of the storage battery 23 according to the algorithm.SELECTED DRAWING: Figure 2

Description

  The invention disclosed by this specification is related with an electric power management system and the storage battery mounting apparatus linked with this.

  In recent years, an energy management system (EMS) that optimally controls power supply and demand using information processing technology has been rapidly developed. In this power management system, storage battery-equipped devices equipped with high-performance storage batteries such as lithium ion batteries can play an important role. An example of the storage battery-equipped device is an uninterruptible power supply, which is designed to function as a backup power supply that supplies AC power from the storage battery to the load device when a power failure occurs in the power system. This uninterruptible power supply can be incorporated into a power management system and linked. For example, for the load device group managed by the power management system by discharging the surplus power of the storage battery excluding the backup time of the specific load device that the uninterruptible power supply has, for example, at the peak of the daytime power usage The power peak supplied from the power system can be leveled. Such a power management system is disclosed in, for example, JP-T-2008-544735.

  On the other hand, the control device of the uninterruptible power supply device performs a charging operation so as to maintain a predetermined power capacity in the storage battery during normal operation, and discharges from the storage battery and supplies AC power to the load when a power failure occurs. A predetermined charging / discharging algorithm is provided. Even if a conventional uninterruptible power supply is connected to a network, it was mainly intended for operation monitoring. For example, current / voltage measurement information, power failure detection information, storage battery charging information, etc. are stored on the uninterruptible power supply side, for example, set in the control device of the uninterruptible power supply from the web browser of the administrator's management computer When the state of the uninterruptible power supply is checked by accessing a web server that is connected or when the state of the uninterruptible power supply changes, an e-mail function is used to send an e-mail to the administrator.

  For this reason, when trying to link an uninterruptible power supply to a power management system as in the technology described in the above publication, it is necessary to control the operation of the uninterruptible power supply from the server side of the power management system.

Special table 2008-544735 gazette

  It is also appropriate for the server of the power management system to determine the charge / discharge algorithm of the storage battery-equipped device such as the uninterruptible power supply that cooperates with it. Since the server of the power management system knows the status of each load device and the status of the power system, depending on the load device type / capacity, day / night / season usage conditions or power control purpose, This is because it is possible to determine how the charge / discharge algorithm is to achieve optimal control of the entire management range of the power management system.

  However, since the EMS controller must inherently execute a task for finely controlling the load device such as air conditioner and lighting, when charge / discharge control of the storage battery mounted device is added, the server of the power management system The processing burden is extremely large. This is particularly noticeable when the power management system is linked with a large number of storage battery mounted devices within the management range.

  Moreover, when the power management system controls the charging / discharging of the storage battery-equipped device, if a failure occurs in the network, the charging / discharging control fails, and as a result, there is a risk that the power control is not performed.

  Therefore, the present specification discloses a technique related to a control device for a storage battery-equipped device that can reduce the processing load on the power management system side as much as possible and cooperates with the power management system that is resistant to communication failures.

  The technology disclosed in this specification includes a load device connected to an electric power system, a storage battery connected to the electric power system, and a charge / discharge control device that controls charging / discharging of the storage battery according to a predetermined charge / discharge algorithm. In a power management system in which storage battery-equipped devices are connected to an EMS controller via a network, the power management system includes a FEMS that manages the power load of the entire factory, a HEMS that manages power devices in the home, and city and local power. It is at least one of a CEMS that manages equipment and a BEMS that manages power equipment of the entire building or a commercial facility, and the EMS controller sends the charge / discharge algorithm of the storage battery-equipped equipment to the charge / discharge control device via the network. The charge / discharge control device holds the transmitted charge / discharge algorithm, and the power storage according to the hold algorithm. This is a power management system that performs charging / discharging operation of a pond.

The storage battery is equipped with a storage battery connected to the power system and a charge / discharge control device that controls charging / discharging of the storage battery according to the charging / discharging algorithm stored in the algorithm storage unit, and the power charged by the midnight power The storage battery-equipped device for peak shift that discharges in the daytime to level the power demand, and the storage battery-equipped device for solar cell that is charged by the solar cell output in the daytime and discharged at night, A network interface for connecting to a network of a power management system for controlling a plurality of load devices connected to the power system, and a charge / discharge algorithm transmitted from the power management system via the network as the algorithm storage When the algorithm update unit to record in the copy and the predetermined condition is not met Battery-equipped device and a algorithm modification request unit that transmits a signal that requests the charging and discharging algorithm for the power management system are also disclosed herein.
In addition, a load device connected to the power system, and a storage battery-equipped device including a storage battery connected to the power system and a charge / discharge control device that controls charging / discharging of the storage battery according to a predetermined charging / discharging algorithm are connected via a network. In the EMS controller connected to the storage battery, the charging / discharging algorithm of the storage battery mounted device is transmitted to the charging / discharging control device via the network, and the charging / discharging control device holds the transmitted charging / discharging algorithm, When the charging / discharging operation of the storage battery is performed according to this and a predetermined condition is not satisfied, a signal requesting the charging / discharging algorithm is transmitted by the charge / discharge control device, and when the predetermined condition is satisfied An EMS controller that transmits the charge / discharge algorithm to the charge / discharge control device is also disclosed herein. There.
Further, in a power management system in which a charge / discharge control device for controlling charge / discharge of a storage battery according to a predetermined charge / discharge algorithm is connected to an EMS controller via a network, the EMS controller transmits the charge / discharge algorithm via the network. Electric power transmitted to a charge / discharge control device, the charge / discharge control device performs charge / discharge operation of the storage battery according to the transmitted charge / discharge algorithm, and the charge / discharge control device determines whether or not a predetermined condition is satisfied A management system is also disclosed herein.

  According to the technology disclosed in the present specification, it is possible to reduce the processing load on the server side of the power management system, and to strengthen against the occurrence of a communication failure.

Block diagram showing the configuration of the power management system Block diagram showing the configuration of the uninterruptible power supply Block diagram showing the configuration of the network unit Flow chart showing charge / discharge algorithm distribution routine Flowchart showing charge / discharge algorithm update routine

  An embodiment will be described with reference to FIGS. 1 to 5.

  A plurality of load devices 11 to 14 are connected to the AC power system 10. Examples of the load devices 11 and 12 include server devices that require power backup in response to a power failure of the power system 10, and examples of the load devices 13 and 14 include general load devices such as air conditioners and lighting devices. . The load devices 11 and 12 are connected to the power system 10 via uninterruptible power supply devices 20 (hereinafter referred to as “UPS 20”) corresponding to storage battery mounted devices for power backup.

  The two UPSs 20 and the load devices 13 and 14 are connected to the EMS controller 31 via the network 30 and their operations are controlled by the EMS controller 31 controlled by the power management server 32 as described in detail later. The power management server 32 has a database of information related to the operation of each of the load devices 11 to 14 and the UPS 20, and based on this database, analyzes the optimum operation mode of the load device according to the actual power supply and demand state. Based on the analysis result, the EMS controller 31 outputs an operation command to the UPS 20 and the load devices 13 and 14.

  As shown in FIG. 2, the UPS 20 rectifies alternating current from the power system 10 by a rectifier 21 and charges a storage battery 23 such as a lithium ion battery via a bidirectional converter 22. The electric power stored in the storage battery 23 is given to the inverter 24 via the bidirectional converter 22, converted into alternating current power, and given to the load devices 11 and 12 via the inverter bypass switch 25.

  The rectifier 21, the bidirectional converter 22, the inverter 24, and the inverter bypass switch 25 which are components in the UPS 20 are controlled by the UPS control circuit 26. When the electric power system 10 is normally supplying electric power, the storage battery 23 is charged so as to maintain a predetermined capacity, and AC power from the inverter 24 is supplied to the load devices 11 and 12. The capacity of the storage battery 23 is calculated by the UPS control device 26 from information such as the voltage and internal resistance of the storage battery 23, for example. Accordingly, the UPS control device 26 functions as a charge capacity acquisition unit that acquires the charge capacity of the storage battery 23. In the UPS control device 26, the voltage, current, and temperature are acquired at predetermined time intervals for all unit cells constituting the storage battery 23, and recorded in a memory (not shown) together with the operation status of the UPS 20.

  On the other hand, when a power failure of the power system 10 is detected, the UPS control device 26 supplies the AC power to the load device 11 by supplying the DC power charged in the storage battery 23 to the inverter 24 via the bidirectional converter 22. , 12 continuously. As described above, the UPS control device 26 has a function of controlling charging / discharging of the storage battery 23 according to a predetermined charging / discharging algorithm. The charge / discharge algorithm is recorded in a memory 41 corresponding to an algorithm memory provided in the memory of the UPS control device 26 and the network unit 40 described later. Note that the inverter bypass switch 25 is switched so that the power of the power system 10 is directly supplied to the load devices 11 and 12 when the inverter 24 is stopped, for example, when the UPS 20 is inspected.

  The UPS 20 is provided with a network unit 40 for connecting the UPS 20 to the network 30 described above. The network unit 40 has the configuration shown in FIG. 3 in detail, and includes the storage unit 41, the network interface 42, the main calculation unit 43, and the expansion interface 44 described above. The network interface 42 has a connector (not shown) for wired connection to the network 30 to which the EMS controller 31 is connected.

  The extension interface 44 is an interface for a wireless communication line such as Wi-Fi (registered trademark) or Bluetooth (registered trademark) and / or a wired communication line such as USB or RS232C. The extended interface 44 is for connecting a portable information terminal 50 for maintenance and inspection, for example, and establishes an independent communication line separated from the network 30.

  The storage unit 41 stores not only an area for storing the charge / discharge algorithm of the UPS control device 26 described above, but also a program for executing various functions of the main calculation unit 43. For example, in order to provide a program for transferring the operation status of each cell of the storage battery 23 acquired in the UPS control device 26 to the storage unit 41, a log file program for managing the information, and operation information as an HTTP / HTTPS-based user interface. WEB server program, SNMP (Simple Network Management Protocol) program for remote monitoring, communication control program that communicates with the portable information terminal 50 via the extended interface 44, when UPS 20 detects an abnormality or power failure A mail transmission program for transmitting an electronic mail or the like is recorded in the storage unit 41.

  Now, in the UPS 20, the UPS control device 26 controls charging and discharging of the storage battery 23 in accordance with a charging / discharging algorithm stored in advance in the storage unit 41.

The power management server 32 executes the distribution routine of the charge / discharge algorithm shown in FIG. 4 and first verifies whether or not a predetermined condition is satisfied (S100). Whether or not the predetermined condition is satisfied is determined, for example, by whether or not the power demand has changed due to a change in the operation of the air conditioner due to a change in season. For example, when the power demand decreases or the power demand does not change and the predetermined condition is not satisfied (No), the verification returns to verify whether the predetermined condition is satisfied, and the power demand increases. When the predetermined condition is satisfied (in the case of Yes), the power management server 32 generates a new charge / discharge algorithm (S101). As a new charging / discharging algorithm, for example, a difference between the amount of power that can be taken out from the storage battery 23 of the UPS 20 (that is, the remaining capacity) and the amount of power required for backup of the load device 11 connected to the UPS 20 (surplus power amount) is used. The operation procedure for supplying to 11 is illustrated.
Whether or not the predetermined condition is satisfied is not only the verification of whether or not the power demand has changed, but also, for example, whether or not a new UPS has been newly installed, and the electricity billing system such as the electricity bill will be changed. Whether there is a power control condition that is more efficient than the current situation, whether there is a request for a power outage such as a planned power outage, whether there is a request for so-called demand control that controls so as not to exceed the target value of power consumption, The determination is made based on whether or not various conditions are satisfied, such as whether or not the conditions for purchasing power (negative wattage transaction) by the power company have been changed. When the predetermined condition is satisfied (in the case of Yes), for example, a new UPS charge / discharge algorithm stored in advance in the management server 32, a new charge system, a charge / discharge algorithm adapted to a planned power outage, etc. are new. It is generated as a charge / discharge algorithm (S101).

  Then, the power management server 32 transmits the generated new charge / discharge algorithm to the EMS controller 31 (S102), and transmits the charge / discharge algorithm from the EMS controller 31 to the network unit 40 of the UPS 20 via the network 30 (S103). ).

  Then, in the network unit 40, the main calculation unit 43 stores the new charge / discharge algorithm in the storage unit 41, and then executes a charge / discharge algorithm update routine shown in FIG. That is, the main calculation unit 43 also functions as an algorithm update unit that records the charge / discharge algorithm in the storage unit 41. First, the main arithmetic unit 43 verifies whether or not a new charge / discharge algorithm can be executed by determining whether or not a predetermined condition is satisfied (S201). Whether or not the predetermined condition is satisfied is determined based on, for example, whether or not the above-described surplus power amount charged in the storage battery 23 exceeds the power amount necessary for continuing the operation of the load device 11. As described above, the main calculation unit 43 refers to the remaining capacity of the storage battery 23 acquired by the charge capacity acquisition unit by referring to the new charge / discharge algorithm transmitted from the EMS controller 31 that is the power management system via the network 30. It also functions as an algorithm verification unit that determines whether or not to execute.

  In step S201, when it is determined that the surplus power amount of the storage battery 23 exceeds the power amount necessary for continuing the operation of the load device 11 to satisfy the predetermined condition, a new charge / discharge algorithm can be executed. The process proceeds to step S202, and the charge / discharge algorithm is executed.

However, in step S201, for example, the surplus power amount of the storage battery 23 is less than the power amount necessary for continuing the operation of the load device 11, and the predetermined condition is not satisfied, and it is determined that a new charge / discharge algorithm cannot be executed. In the case, the process proceeds to step S203. The main arithmetic unit 43 returns a reason why the execution is impossible via the network 30 to the EMS controller 31 and requests correction of the charge / discharge algorithm (S203). That is, the main calculation unit 43 also functions as an algorithm correction request unit that requests correction of the charge / discharge algorithm. Then, the EMS controller 31 transmits the signal to the power management server 32 (S204), and returns to the charge / discharge algorithm distribution routine (FIG. 4) in the power management server 32.
The determination as to whether or not the predetermined condition for requesting the correction of the charge / discharge algorithm is satisfied is only the determination as to whether or not the surplus power amount of the storage battery 23 exceeds the power amount necessary for continuing the operation of the load device 11. Instead, for example, it is determined based on various conditions such as whether or not the charging / discharging algorithm of the storage unit 41 such as failure replacement or expansion of the UPS has been updated, and whether or not the number of cycle discharges has exceeded the reference value. When the predetermined condition is not satisfied, the main calculation unit 43 as the algorithm correction request unit transmits a signal requesting the EMS controller 31 to correct the charge / discharge algorithm.

  For this reason, the power management server 32 generates a new charge / discharge algorithm with reference to the reason that it cannot be executed (S101). Since the process goes through steps S102 and S103, the generated new charge / discharge algorithm is sent to the network unit 40, and the network unit 40 executes the algorithm update routine again. As a result, the UPS 20 is operated based on a new executable charge / discharge algorithm generated by the power management server 32.

  Thus, according to this embodiment, since the power management server 32 grasps the status of each load device 11-14 and the status of the power system 10, the type / capacity of the load devices 11-14, day / night / season, A charge / discharge algorithm that optimizes the entire management range of the power management system can be generated according to usage conditions such as failure / update, usage environment, or power control purpose. Moreover, once the power management server 32 generates the charging / discharging algorithm, the power management server 32 does not directly control the UPS 20 via the network 30, but sends a new charging / discharging algorithm to the storage unit 41 of the network unit 40, so Since it can be left to the control, the processing load on the EMS controller 31 side becomes extremely small. Further, after a new charging / discharging algorithm is sent to the network unit 40, even if a failure occurs in the network 30, the UPS 20 can continue to maintain a power control system capable of power control.

  Furthermore, in this embodiment, the validity of the new charge / discharge algorithm generated in the power management server 32 is verified in the network unit 40 that sufficiently grasps the operation status of the UPS 20, and the charge / discharge algorithm cannot be executed. In some cases, the main calculation unit 43, which is an algorithm correction request unit, outputs an algorithm correction request to the EMS controller 31 to recreate a new charge / discharge algorithm. Can achieve stable operation.

<Other embodiments>
(1) In the above embodiment, the uninterruptible power supply device is exemplified as the storage battery-equipped device. However, the present invention is not limited to this. It may be a storage battery mounted device or a storage battery mounted device for a solar battery that is charged by solar cell output during the day and discharged at night.

  (2) In the said embodiment, although the storage battery showed the example which consists of a lithium ion battery, it is needless to say that not only this but various secondary batteries, such as a lead storage battery and a nickel metal hydride battery, can be utilized. When a lead storage battery is used, for example, management information such as battery voltage, current, and temperature can be acquired for each battery module.

  (3) In the above embodiment, the configuration in which the power management system manages the four load devices 11 to 14 is illustrated for the sake of simplification. However, the power management system is not limited to this, and the power load of the entire factory is not limited thereto. FEMS (Factory Energy Management System) for managing power, HEMS (Home Energy Management System) for managing power equipment in the home, CEMS (Community Energy Management System) for managing power equipment in towns and regions, building and commercial facilities Of course, it can be applied to BEMS (Building Energy Management System) that manages electric power equipment.

  (4) In the above embodiment, the configuration example in which the power management server 32 is provided separately from the EMS controller 31 is shown. However, the present invention is not limited to this, and the EMS controller 31 is provided with the data processing function of the power management server 32 to It is good also as an integrated structure. Alternatively, a plurality of EMS controllers may be applied to a large-scale power management system connected to a power management server via a network.

  (5) In the above embodiment, the UPS 20 is of the type that always supplies power to the load device from the inverter 24. However, in normal times, the power is supplied from the power system to the load device, and the inverter is used when the power system fails. Of course, it is possible to use a type that switches so that the power from the power source is supplied to the load device.

10: Power systems 11-14: Load device 20: Uninterruptible power supply (storage battery mounted device)
23: Storage battery 26: UPS control device (charge capacity acquisition unit)
30: Network 31: EMS controller 32: Power management server 40: Network unit 41: Storage unit (algorithm storage unit)
42: Network interface 43: Main operation unit (algorithm update unit, algorithm verification unit, algorithm correction request unit)

Claims (9)

An EMS via a network includes a load device connected to an electric power system, and a storage battery-equipped device including a storage battery connected to the electric power system and a charge / discharge control device that controls charging / discharging of the storage battery according to a predetermined charging / discharging algorithm. In the power management system connected to the controller,
The power management system manages FEMS that manages the power load of the entire factory, HEMS that manages power equipment in the home, CEMS that manages power equipment in the city or region, and power equipment in the entire building or commercial facility. One of BEMS,
The EMS controller transmits the charging / discharging algorithm of the storage battery-equipped device to the charging / discharging control device via the network, and the charging / discharging control device holds the transmitted charging / discharging algorithm, and accordingly the storage battery Charge / discharge operation,
The charge / discharge control device is a power management system that transmits a signal requesting the charge / discharge algorithm to the EMS controller when a predetermined condition is not satisfied. A storage battery-equipped device including a storage battery connected to an electric power system and a charge / discharge control device that controls charging / discharging of the storage battery according to a charge / discharge algorithm stored in an algorithm storage unit,
The storage battery-equipped device is for peak shift that discharges power charged by midnight power in the daytime to equalize power demand, or for solar cells that are charged by solar cell output in the daytime and discharged at night,
A network interface for connecting to a network of a power management system for controlling a plurality of load devices connected to the power system;
An algorithm updating unit that records the charging / discharging algorithm transmitted from the power management system via the network in the algorithm storage unit;
A storage battery-equipped device comprising: an algorithm correction requesting unit that transmits a signal requesting the charge / discharge algorithm to the power management system when a predetermined condition is not satisfied. A load device connected to an electric power system and a storage battery-equipped device including a storage battery connected to the electric power system and a charge / discharge control device that controls charging / discharging of the storage battery according to a predetermined charging / discharging algorithm are connected via a network. In the EMS controller
The charging / discharging algorithm of the storage battery mounted device is transmitted to the charge / discharge control device via the network,
The EMS controller which receives the signal which requests | requires the said charging / discharging algorithm from the said charging / discharging control apparatus, when predetermined conditions are not satisfy | filled. A power management server for controlling the EMS controller according to claim 3,
A power management server that generates the charge / discharge algorithm and transmits the generated charge / discharge algorithm to the EMS controller. The power management server according to claim 4, wherein the power management server verifies whether or not a predetermined condition is satisfied, and generates the charge / discharge algorithm when the predetermined condition is satisfied. In a power management system in which a charge / discharge control device that controls charge / discharge of a storage battery according to a predetermined charge / discharge algorithm is connected to an EMS controller via a network,
The EMS controller transmits the charge / discharge algorithm to the charge / discharge control device via the network,
The charge / discharge control device determines whether the transmitted charge / discharge algorithm satisfies a first predetermined condition,
The charge / discharge control device is a power management system that performs a charge / discharge operation of the storage battery according to the transmitted charge / discharge algorithm. The power management system according to claim 6, wherein the charge / discharge control device requests the charge / discharge algorithm from the EMS controller when the first predetermined condition is not satisfied. The power management system according to claim 6 or 7, wherein the EMS controller transmits the charge / discharge algorithm to the charge / discharge control device when a second predetermined condition is satisfied. system. 9. The power management system according to claim 6, wherein whether or not the first predetermined condition is satisfied is determined by whether a surplus power amount charged in the storage battery is a load device or not. A power management system that includes whether or not it exceeds the amount of power required to continue operation.

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