KR101318891B1 - Power management system and operating method thereof - Google Patents

Abstract

PURPOSE: A power management system and an operating method thereof are provided to operate and manage a plurality of uninterruptible power supply units using renewable energy besides the utility power. CONSTITUTION: A central control server (600) analyzes the current amount information. The current amount information is transmitted from a plurality of uninterruptible power supply units. The central control server generates operation and management data according to each uninterruptible power supply unit and transmits the generated operation and management data to each uninterruptible power supply unit. Data is transmitted or received between each uninterruptible power supply unit and the central control server through the internet (500). [Reference numerals] (100) AC-DC inverter; (200) DC-DC converter; (400) Energy storage device; (500) Internet; (600) Central command center; (AA) Prevailing power source; (BB) AC generation power source; (CC) DC generation power source

Description

Power management system and its operation method {POWER MANAGEMENT SYSTEM AND OPERATING METHOD THEREOF}

The present invention relates to a power management system and a method of operating the same, and more particularly, to a power management system and a method for operating and managing a plurality of UPS (Uninterruptible Power Supply) using renewable energy in addition to the commercial power source It is about.

In general, a UPS is a device that prevents power abnormality caused by voltage fluctuations, frequency fluctuations, instantaneous power failures, transient voltages, etc. when using a general power supply or a backup power supply, and always supplies a stable power supply. Demand is soaring.

In addition, UPS is designed and manufactured for emergency power in the event of planned power outage and disaster, and it is suitable for nighttime indoor use because there is no noise and no exhaust gas compared to fuel equipment, etc. to be.

On the other hand, Korean Patent No. 10-1173134 discloses a power control device for a building using energy stored in an energy storage unit so that power can be stably supplied in addition to commercial power in a building. A commercial power AC-DC converter that receives commercial AC power and converts the DC into an integrated unit; A direct current conversion unit which receives power from at least one renewable energy and converts it into direct current that can be used in a load and outputs it to an integrated unit; Receives the converted DC power from the commercial power AC-DC converter and the DC converter, respectively, integrates the DC power, and converts the integrated DC power into DC power available from the load and outputs the load to the load side. An integrator comprising a buck convertor to make a buck converter; An energy storage unit for storing the power of the DC power input to the integrated unit under control of the controller; And a control unit for controlling the integrated unit to output the DC power stored in the energy storage unit to the load through the integrated unit when the power of the integrated DC power falls below a predetermined level, and the controller detects whether there is a load. And control the integrating unit to store the power of the DC power integrated in the integrating unit as it is before the buck convertor in the integrating unit stores the energy storage unit in the energy storage unit as long as the load is less than a predetermined reference. And a distribution unit for supplying DC power to the load and a DC-AC converter for supplying AC power to the load. The renewable energy includes solar or wind or At least one of tidal or hydraulic power is characterized in that. According to the disclosed technology, since power generated by using solar light, wind power, or flow rate is converted into DC power and stored, the efficiency of energy storage can be improved as compared to a UPS which previously stored AC power.

In addition, Korean Patent No. 10-1142595 discloses an energy management apparatus and system that can reduce the cost of using an electrical / electronic device. According to the disclosed technology, the power receiving unit receives power from the outside; A power supply for applying power applied through the power receiver to at least one electric / electronic device; Communication unit for transmitting and receiving a control parameter for controlling the operation of the electrical / electronic device; And a control unit which controls the power supply to apply the power to the electric / electronic device based on the property information of the electric / electronic device and the control parameter, wherein the property information of the electric / electronic device is Information on the priority given to the electronic device, wherein the control parameter is based on the cost that the power provider charges for the power consumption according to the ratio of power usage and power supply to the energy usage of the electrical / electronic device. And charging information, which is information about the controller, wherein the controller controls the application of power to the electric / electronic device based on the priority according to the degree of setting the cost.

However, the conventional UPS as described above was merely utilized as a device for supplying emergency power, and the existing energy storage and management device as described above is also generated using solar, wind, or flow rate separately from the UPS. The function was to store and consume energy and to simply manage the cost of power consumption.

Therefore, it is necessary to develop a device capable of performing energy storage and management functions in the existing UPS function, and furthermore, not only renewable energy generated by solar light, wind power or flow rate, but also storage and management functions for commercial power sources. It will be necessary to achieve a more stable power supply and to eliminate power consumption to realize power savings.

In addition, as systems requiring reliability such as finance, broadcasting, and industry increase, parallel operation UPS needs to be introduced, and as all systems are networked due to the rapid advancement into the information society, UPS also needs to be managed on the network. In addition to monitoring and controlling remotely, there is a growing need to enable remote diagnostics and follow-up.

Accordingly, by developing a UPS that performs energy storage and management functions as well as emergency power supply in addition to commercial power, it is simpler and cheaper to install in each factory or home. In addition, there is a need for a plurality of UPSs to be integrated and managed through a network.

Korea Patent Registration No. 10-1173134 Korea Patent Registration No. 10-1142595

An embodiment of the present invention is to provide a power management system and a method of operating the integrated management and management of a plurality of UPS using renewable energy in addition to commercial power.

An embodiment of the present invention is to provide a power management system and its operation method to manage a plurality of UPS using renewable energy in addition to the commercial power on the network.

An embodiment of the present invention is to provide a power management system and its operation method to perform an energy storage and management function as well as an emergency power supply function using renewable energy in addition to commercial power through a UPS.

Among the embodiments, the power management system is supplied with commercial power, provided to the AC load side, or converted to DC power to charge, converting the charged DC power to commercial power to supply to the AC load side or external, commercial power A plurality of UPSs that identify and transmit the amount of power used, the amount of charge power, the amount of discharge power, and the amount of power sold, and receives operation and management data to perform energy storage and management and uninterruptible power control; A central control server analyzing power information transmitted from a plurality of UPSs to generate operation and management data for each UPS group or each UPS group belonging to each region and transmitting the generated data to each UPS; And an Internet for transmitting and receiving data between the UPS and the central control server.

In one embodiment, the power management system, AC-DC inverter for converting into a DC power source that can receive and charge AC power generation; DC-DC converter for converting into a DC power source that can be charged and supplied with DC power; And an energy storage device for charging the DC power converted by the AC-DC inverter, the DC-DC converter, or the UPS, and discharging the DC power charged under the control of the UPS.

In one embodiment, the UPS may be supplied with a DC power supplied to the energy storage device converted to a DC power to be used for the DC load side.

According to an embodiment, the UPS may convert the commercial power into direct current power and charge the energy storage device according to the amount of power used for the commercial power, or during a predetermined time period.

In one embodiment, the UPS, by checking the case that the commercial power is not supplied to convert the DC power charged in the energy storage device to commercial power can be continuously supplied uninterrupted to the AC load side.

In one embodiment, the UPS may be supplied to the outside by converting the DC power charged in the energy storage device into commercial power according to the amount of charging power of the energy storage device.

In one embodiment, the UPS, according to the amount of power used by the commercial power, or during a predetermined time of high power consumption, converts the DC power charged in the energy storage device into commercial power in addition to the commercial power to the AC load side. Can be supplied additionally.

In one embodiment, the UPS, a commercial power input unit for receiving and supplying commercial power; A first switch unit for switching commercial power supplied through the commercial power input unit; An AC-DC converter converting commercial power switched through the first switch unit into DC power and charging the energy storage device; A DC-AC converter converting DC power charged in the energy storage device into commercial power; A second switch unit for switching the commercial power converted by the DC-AC converter; An AC load output unit for supplying commercial power switched through the first switch unit or the second switch unit to an AC load side; A commercial power output unit supplying and selling commercial power switched through the second switch unit to the outside; A DC-DC converter converting DC power charged in the energy storage device into DC power for use by the DC load side; A DC load output unit supplying the DC power converted by the DC-DC converter to a DC load side; The amount of commercial power charging power charged to the energy storage device through the first switch unit, the amount of commercial power used to be supplied to the AC load side through the first switch unit, and the commercial power discharge discharged to the AC load side through the second switch unit. Power amount, the amount of commercial power sold by the second switch unit, the amount of DC power discharged discharged to the DC load side through the DC-DC converter, the energy storage device through the AC-DC inverter or the DC-DC converter An amount of electricity measuring unit measuring an amount of renewable energy charging power charged in the; A control unit which collects information on the amount of power measured by the power amount measuring unit and controls the switching operation of the first switch unit or the second switch unit based on the collected power amount information or according to the operation and management data; A memory unit for storing a program and data necessary for the control of the controller; And a communication unit converting and transmitting power amount information collected by the control unit to convert transmission data that can be received by the central control server, and receiving and transmitting operation and management data from the central control server to the control unit.

In an embodiment, the control unit may determine whether the amount of commercial power use measured by the power measurement unit is smaller than a reference use power stored in the memory unit or whether the charging time is stored in the memory unit, and thus, the first switch unit. By controlling a portion of the commercial power supplied through the commercial power input unit to the AC-DC converter, and checking the case where the amount of power charged in the energy storage device is greater than the reference reserve power stored in the memory unit. The second switch unit controls the commercial power converted by the DC-AC converter to switch the commercial power output unit, and the amount of commercial power use measured by the power amount measuring unit is greater than the reference overload power used in the memory unit. Or check whether the discharge time is stored in the memory unit. By controlling the second switch unit, the commercial power converted by the DC-AC converter further switches to the AC load output unit, and checks whether the DC load is connected to the DC load output unit by the DC-DC converter. The control unit may check the case where there is no commercial power supplied through the commercial power input unit and control the second switch unit to switch the commercial power converted by the DC-AC converter to the AC load output unit uninterrupted. .

In an embodiment, the UPS may include a DC power input unit configured to receive a DC power source or a DC power source of another energy storage medium; And a direct current (DC) to direct current converter configured to convert the DC power input through the DC power input unit into DC power to be stored in the energy storage device.

According to an embodiment, the UPS may calculate a power sales amount and an electric charge based on the selling power amount and the commercial power use amount by using preset power-money conversion information and provide the same to a user or transmit the power rate to the central control server. have.

In one embodiment, the central control server, based on the power information received from the plurality of UPS, analyzes the power status for each UPS or each UPS group belonging to each region, or use the preset power-money conversion information Calculates power sales and electricity rates, and generates and transmits operation and management data for energy storage and management for each UPS or each UPS group in each region according to the analyzed power state. .

In one embodiment, the central control server, after distinguishing the UPS belonging to the first UPS group having a large amount of charging power but the amount of power used and the second UPS group belonging to the second UPS group with a small amount of charge power, Operation and management data for selling power remaining in the UPS belonging to the 1UPS group to the UPS belonging to the second UPS group may be generated and transmitted to each UPS.

Among the embodiments, the operating method of the power management system, in a power management system including a plurality of UPS and the central control server, each UPS is supplied with commercial power to the AC load side, or converted to DC power to charge, Converting the charged DC power into commercial power and supplying it to the AC load side or the outside; The UPS checks the amount of power used, the amount of charge power, the amount of discharge power and the amount of power sold by the commercial power supply to the central control server; Analyzing, by the central control server, the amount of power transmitted from each UPS, generating operation and management data for each UPS or each UPS group belonging to each region, and transmitting the generated data to each UPS; And receiving each operation and management data from the central control server to perform energy storage and management and uninterruptible power control.

In an embodiment, the operating method of the power management system may include converting and charging a DC power source to receive an alternating current power from an AC-DC inverter to charge an energy storage device; Receiving DC power from a DC-DC converter and converting the DC power into DC power to charge the energy storage device; And measuring the amount of renewable energy charging power charged to the energy storage device through the AC-DC inverter or the DC-DC converter.

In one embodiment, the operation method of the power management system may further include the step of measuring the amount of power used to the AC load side for commercial power when the commercial power supplied from the UPS to the AC load side. .

In one embodiment, the operation method of the power management system, by confirming whether the amount of power used to the AC load side measured by the UPS is enough power to charge a portion of the commercial power to the energy storage device, commercial power The method may further include charging a portion of the DC power by charging the energy storage device.

In an embodiment, the method of operating the power management system may include checking a case in which the power consumption preset by the UPS is low, and converting a part of commercial power into DC power to charge the energy storage device. It may further include.

In one embodiment, the operation method of the power management system, by measuring the amount of power used from the UPS to the energy storage device for commercial power, the total amount of power used for commercial power combined with the measured amount of power to the AC load side. Measuring; Calculating an electric charge based on the measured total amount of electric power using the power-money conversion information preset by the UPS; Measuring an amount of charging power from the UPS to an energy storage device for commercial power, and measuring the total amount of charging power charged to the energy storage device in combination with the measured amount of renewable energy charging power; And checking the amount of power charged to the energy storage device in the UPS.

In one embodiment, the operating method of the power management system, when the DC power charged in the energy storage device is converted to commercial power supply to the outside in accordance with the identified amount of charge power in the UPS to sell to commercial power Measuring a sales amount; And calculating, by the UPS, a power sales amount based on the measured sales power amount using preset power-money conversion information.

In one embodiment, the operation method of the power management system, by checking whether the amount of power used to the AC load side measured by the UPS is insufficient for the amount of power supplied to the AC load side, the direct current charged in the energy storage device The method may further include converting a power source into a commercial power source and additionally supplying the AC load to the AC load side.

In one embodiment, the operation method of the power management system, by checking the case of the time when the power consumption is set in advance in the UPS, by converting the DC power charged in the energy storage device to commercial power to the AC load side It may further comprise the step of supplying.

In one embodiment, the operation method of the power management system, by measuring the amount of discharge power from the UPS to the commercial power for the power charged in the energy storage device, the commercial power in combination with the measured sales power to the commercial power source Measuring the total amount of discharge power to the furnace; And re-confirming the amount of power charged to the energy storage device in the UPS.

In one embodiment, the operation method of the power management system, by checking the case that the commercial power is not supplied from the UPS, by converting the DC power charged in the energy storage device into commercial power uninterrupted to the AC load side uninterrupted Supplying; Re-measuring the amount of discharge power to commercial power for the power charged in the energy storage device in the UPS, and re-measuring the total amount of discharge power to commercial power in combination with the measured sales power to commercial power; And re-confirming the amount of power charged to the energy storage device in the UPS.

In one embodiment, the operation method of the power management system, by checking the connection state with the DC load side in the UPS, converting the DC power charged in the energy storage device to the DC power to be used by the DC load side to supply step; Measuring the amount of discharge power from the UPS to a DC power source, and measuring the total amount of discharge power of the energy storage device by adding the measured amount of power sold to the commercial power and the amount of discharge power to the commercial power; And re-confirming the amount of power charged to the energy storage device in the UPS.

In one embodiment, the step of transmitting to the central control server, the new renewable energy charging power, the amount of power used to the AC load side, the amount of power used to the energy storage device, the amount of power charged to the energy storage device in the UPS The information on the amount of power sold to the commercial power source, the amount of discharge power to the commercial power source, or the amount of discharge power to the DC power source may be collected and displayed to the user through an LCD or transmitted to the central control server.

In one embodiment, the step of transmitting to each UPS, based on the power information received from the UPS in the central control server, by analyzing the power status for each UPS or each UPS group belonging to each area to the control station Notification, or calculate power sales and electricity rates using preset power-money conversion information, and operate for energy storage and management by each UPS or each UPS group in each region according to the analyzed power status. Management data can be generated and sent to each of the UPSs.

In one embodiment, the transmitting to each UPS may include a UPS belonging to a first UPS group having a large amount of charging power but a small amount of power used in the central control server, and a second UPS group having a large amount of power used with a small amount of charge power. After the UPSs are identified, operation and management data for selling power remaining in the UPS belonging to the first UPS group to the UPS belonging to the second UPS group may be generated and transmitted to each UPS.

In an embodiment, the step of performing energy storage and management and uninterruptible power control may include direct current charged in the energy storage device according to operation and management data received from the central control server in a UPS belonging to the first UPS group. The power may be converted into commercial power to be supplied and sold to a UPS belonging to the second UPS group.

Among the embodiments, a method of operating a power management system, the method of operating a power management system including a plurality of UPS, comprising the steps of measuring the amount of power used commercial power to the AC load while receiving the commercial power to the AC load side; Checking whether the amount of commercial power used is less than a preset reference power, converting a part of commercial power into a DC power, charging the energy storage device, and measuring the amount of commercial power charging power; Measuring the amount of renewable energy charging power charged to the energy storage device from an AC-DC inverter or a DC-DC converter; Measuring the total amount of charging power charged by the energy storage device by combining the amount of the commercial power charging power and the amount of renewable energy charging power, and confirming the amount of power charged in the energy storage device; Measuring the total amount of power used for the commercial power source by measuring the amount of power used for the commercial power source to the energy storage device and adding the amount of commercial power source power to the AC load side; Checking whether the amount of power charged in the energy storage device is greater than a predetermined reference reserve power, converting the DC power charged in the energy storage device into commercial power, supplying the product to outside, and measuring the amount of commercial power selling power; And collecting information on the amount of power and displaying the collected amount of power information to the user or transmitting the collected amount of power information to a central control server.

According to an embodiment, the operation method of the power management system may include calculating an electric charge by corresponding to preset power-money conversion information based on the total amount of power used for the commercial power source; Calculating an electric power selling amount based on the corresponding electric power-money conversion information based on the electric power selling amount of commercial power; And providing information on the calculated electric charge and power sales amount to a user or transmitting the information to the central control server.

In one embodiment, the operation method of the power management system, by checking whether the amount of power used in the commercial power is greater than the preset overload reference power amount, and converts the DC power charged in the energy storage device to commercial power AC load side Supplying additionally and measuring the amount of commercial power discharge power; Checking whether the DC load is connected, converting the DC power charged in the energy storage device into the DC power to be used by the DC load side, and measuring the amount of DC power discharge power; Checking whether the time period is a preset charging time, converting a part of commercial power into DC power to charge the energy storage device, and measuring the amount of commercial power charging power; Checking whether the discharge time is a predetermined time period, converting the DC power charged in the energy storage device into commercial power to supply the AC power to the AC load side, and measuring the amount of commercial power discharge power; Checking a case in which there is no supply of commercial power, converting the DC power charged in the energy storage device into commercial power, continuously supplying uninterrupted power to an AC load, and measuring the amount of commercial power discharge power; Collecting information on the renewable energy charging power amount, the commercial power charging power amount, the commercial power supply power amount, the commercial power discharge power amount, the commercial power selling power amount, and the DC power discharge power amount; And displaying the collected power amount information through the LCD or transmitting the collected power amount information to the central control server.

The power management system and its operation method according to an embodiment of the present invention, by operating and managing a plurality of UPS using renewable energy in addition to the commercial power source to perform a UPS function and energy storage and management functions together, solar power In addition to the renewable energy generated using wind or flow rate, as well as the storage and management functions for commercial power can be performed, thereby more stable power supply and unnecessary power consumption can be removed to achieve power savings.

Power management system and its operation method according to an embodiment of the present invention, by managing a plurality of UPS using renewable energy in addition to the commercial power supply on the network, not only remotely monitor and control, but also remote diagnosis and follow-up management Can be done.

Power management system and its operation method according to an embodiment of the present invention, by using the UPS to perform the energy storage and management functions using renewable energy in addition to the commercial power supply at the same time as the emergency power supply function is also installed, It's simpler and cheaper so it can be installed in each factory or home.

1 is a block diagram illustrating a power management system according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a UPS in FIG. 1.
3 is a flowchart illustrating a method of operating a power management system according to an embodiment of the present invention.
4 is a flowchart illustrating a method of operating a power management system according to another embodiment of the present invention.

The description of the present invention is merely an example for structural or functional explanation, and the scope of the present invention should not be construed as being limited by the embodiments described in the text. That is, the embodiments may be variously modified and may have various forms, and thus, the scope of the present invention should be understood to include equivalents for realizing the technical idea.

Meanwhile, the meaning of the terms described in the present invention should be understood as follows.

The terms "first "," second ", and the like are intended to distinguish one element from another, and the scope of the right should not be limited by these terms. For example, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

It is to be understood that when an element is referred to as being "connected" to another element, it may be directly connected to the other element, but there may be other elements in between. On the other hand, when an element is referred to as being "directly connected" to another element, it should be understood that there are no other elements in between. On the other hand, other expressions describing the relationship between the components, such as "between" and "immediately between" or "neighboring to" and "directly neighboring to", should be interpreted as well.

It should be understood that the singular " include "or" have "are to be construed as including a stated feature, number, step, operation, component, It is to be understood that the combination is intended to specify that it does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

In each step, the identification code (e.g., a, b, c, etc.) is used for convenience of explanation, the identification code does not describe the order of each step, Unless otherwise stated, it may occur differently from the stated order. That is, each step may occur in the same order as described, may be performed substantially concurrently, or may be performed in reverse order.

The present invention can be embodied as computer-readable code on a computer-readable recording medium, and the computer-readable recording medium includes all kinds of recording devices for storing data that can be read by a computer system . Examples of the computer-readable recording medium include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device, and the like, and also implemented in the form of a carrier wave (for example, transmission over the Internet) . In addition, the computer-readable recording medium may be distributed over network-connected computer systems so that computer readable codes can be stored and executed in a distributed manner.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used predefined terms should be interpreted to be consistent with the meanings in the context of the related art and can not be interpreted as having ideal or overly formal meaning unless explicitly defined in the present invention.

1 is a block diagram illustrating a power management system according to an embodiment of the present invention.

As shown in FIG. 1, a power management system according to an embodiment of the present invention includes an AC-DC inverter 100, a DC-DC converter 200, and a UPS 300. And an energy storage device 400, the Internet 500, and a central control server 600. Here, any one or at least one of the AC-DC inverter 100, the DC-DC converter 200, and the energy storage device 400 may be provided in the UPS 300.

The AC-DC inverter 100 receives AC power from a device or facility that generates renewable energy (ie, AC power), such as a wind generator, and supplies the generated AC power to the energy storage device 400. It converts into a DC power source that can be stored in, and stores (ie, charges) the converted DC power source in the energy storage device 400.

The DC-DC converter 200 receives DC power from a device or facility that generates renewable energy (ie, DC power), such as a solar generator, and supplies the DC power supplied with the energy storage device 400. It converts into a DC power source that can be stored in, and stores (ie, charges) the converted DC power source in the energy storage device 400.

The UPS 300 may include the amount of renewable energy charged to the energy storage device 400 through the AC-DC inverter 100 or the DC-DC converter 200, the amount of charged power to the energy storage device 400 for commercial power, The amount of power used for the commercial power supply (that is, the amount of power used for the AC load side and the energy storage device 400), the amount of discharge power and sales power for the commercial power for the power stored in the energy storage device 400, and the energy storage device 400 Check the amount of discharge power to the DC power for the power stored in the), and transmits the information on the identified amount of power to the central control server 600 through the Internet 500, the information on the identified amount of power or central control The energy storage and management function for the energy storage device 400 is performed according to the operation and management data received through the Internet 500 from the server 600. In addition, the UPS 300 may calculate an electric power sales amount, an electric charge, and the like by using the information on the identified amount of power.

In one embodiment, the UPS 300 is supplied with commercial power of AC 220V or AC 330V, and provides the supplied commercial power to an AC load side such as a general household appliance such as a fan or a refrigerator, a factory machine, or the like. It converts the supplied commercial power into a direct current power that can be stored in the energy storage device 400 to store (ie, charge) the converted direct current power in the energy storage device 400, and also to the energy storage device 400. The stored DC power may be supplied to convert the supplied DC power into AC 220V or AC 330V commercial power, and the converted commercial power may be provided to another consumer (for example, sold to KEPCO).

In one embodiment, the UPS 300 receives the DC power stored in the energy storage device 400 and converts the supplied DC power into DC power that can be used on a DC load side such as a DC motor or an electric vehicle. The converted DC power supply may be provided.

In one embodiment, the UPS 300 normally provides a commercial power of AC 220V or AC 330V to an AC load side such as a general household appliance such as a fan or a refrigerator, a factory machine, etc. Depending on (or during periods of low power usage (e.g., 23:00 to 6 am, etc.)), the energy storage device 400 may be charged with AC 220V or AC 330V, and the planned power outage and disaster Even at the time, the power stored in the energy storage device 400 may be continuously provided to the AC load side.

In one embodiment, the UPS 300 converts the power stored in the energy storage device 400 into a commercial power source of AC 220V or AC 330V according to the amount of power stored in the identified energy storage device 400. For example, KEPCO, other UPS (300, etc.) can be sold to the side.

In one embodiment, the UPS 300 is a commercial power source of AC 220V or AC 330V, depending on the amount of utility power used (or during a high power usage period (eg, 11:00 to 16:00), etc.). In addition, it is possible to further supply a power stored in the energy storage device 400 to be a stable power supply.

The energy storage device 400 is a device that stores a DC power source such as a battery pack, and the like, in the DC power source converted from the AC-DC inverter 100 under the control of the UPS 300, or in the DC-DC converter 200. It receives the converted DC power or the converted DC power from the UPS 300 to store (ie, charge), and also stores the stored DC power under the control of the UPS 300 through the UPS 300. It serves to supply (ie discharge).

The internet 500 performs wired or wireless internet, and transmits and receives data between the UPS 300 and the central control server 600.

The central control server 600 receives power amount information from the plurality of UPSs 300 through the Internet 500, analyzes the received power amount information, and analyzes the plurality of UPSs 300 according to the analyzed power amount information. In this case, operation and management data is generated to enable energy storage and management of the energy storage device 400 for each UPS 300 or each UPS group in each region. And transmits to each UPS 300 through the Internet (500).

In one embodiment, the central control server 600, based on the amount of power information received from the plurality of UPS 300 via the Internet 500, the power for each UPS 300, or each UPS group belonging to each region Status (for example, the amount of power stored in the energy storage device 400, the amount of power used by commercial power, etc.) can be analyzed, and the amount of electricity sold by each UPS 300 or by each UPS group in each region. , Electric bills and the like can also be calculated.

In an embodiment, the central control server 600 may include a UPS 300 belonging to a first UPS group having a large amount of power stored in the energy storage device 400 but a small amount of power used, and a stored amount of power in the energy storage device 400. After classifying the UPS 300 belonging to the second UPS group having a small amount of power and using a small amount of power, the remaining power from the UPS 300 belonging to the first UPS group can be sold to the UPS 300 belonging to the second UPS group. It can generate and transmit the operation and management data to each UPS 300 through the Internet (500).

FIG. 2 is a diagram illustrating a UPS in FIG. 1.

As shown in FIG. 2, the UPS 300 includes a commercial power input unit 301, a first switch unit 302, an AC load output unit 303, an AC-DC converter 304, and a DC-AC conversion. The unit 305, the second switch unit 306, the commercial power output unit 307, the DC-DC converter 308, the DC load output unit 309, the power amount measuring unit 310, the control unit 311, The memory unit 312 and the communication unit 313 is included.

The commercial power input unit 301 serves to receive AC 220V or AC 330V commercial power and supply the same through the first switch unit 302.

The first switch unit 302 is connected to the AC load output unit 303 by switching the commercial power supplied through the commercial power input unit 301 under the control of the control unit 311 to the AC load output unit 303 side. Or switching to the AC-DC converter 304 to switch to the AC-DC converter 304. In this case, the first switch unit 302 may perform both switching operations simultaneously, only one of them, or none of them under the control of the controller 311.

The AC load output unit 303 may provide a commercial power source switched through the first switch unit 302 or the second switch unit 306 to an AC load side such as a general household appliance such as a fan or a refrigerator or a factory machine. Play a role.

The AC-DC converter 304 converts the commercial power switched through the first switch unit 302 into DC power that can be stored in the energy storage device 400 under the control of the controller 311. DC power is stored (ie, charged) in the energy storage device 400.

The DC-AC converter 305 converts the DC power provided from the energy storage device 400 into AC 220V or AC 330V commercial power under the control of the controller 311 and converts the converted commercial power into a second switch. Provided to section 306.

The second switch unit 306 is connected to the AC load output unit 303 by switching the commercial power provided from the DC-AC converter 305 under the control of the control unit 311 side of the AC load output unit 303 The switch is connected to the commercial power output unit 307 or switched to the commercial power output unit 307. In this case, the second switch unit 306 may perform both switching operations simultaneously, only one of them, or none of them under the control of the controller 311.

The commercial power output unit 307 may provide commercial power switched through the second switch unit 306 to another consumer (eg, KEPCO, another UPS 300, etc.) to be sold to another consumer.

The DC-DC converter 308 converts the DC power provided from the energy storage device 400 into a DC power source that can be used by a DC load side such as a DC motor or an electric vehicle under the control of the controller 311. The converted DC power is provided to the DC load output unit 309.

The DC load output unit 309 outputs the DC power provided from the DC-DC converter 308 to a DC load side such as a DC motor or an electric vehicle.

The power amount measurer 310 is a power meter that calculates the amount of power of an AC or DC power supply, a battery diagnostic device that detects an amount of electric charge charged in a battery, and the like. Measure the amount of power (i.e., the amount of commercial power charging power) for the DC power stored in the energy storage device 400 (i.e., charging) via the AC power supply unit, or the AC load output unit 303 through the first switch unit 302. Measure the amount of power for the commercial power provided to the AC load side such as general household appliances, factory machines, etc. (ie, the amount of commercial power used), or the AC load output unit 303 through the second switch unit 306. After measuring the amount of power (that is, the amount of commercial power discharge power) for commercial power provided to the AC load side (that is, discharged) such as general home appliances, factory machines, or the like, or through the second switch unit 306, the commercial power output unit Via (307) For example, KEPCO measures the amount of power (that is, the amount of power sold for commercial power) for commercial power provided to (i.e., sold) to another UPS (300, etc.), or outputs DC load from the DC-DC converter 308. The unit 309 measures the amount of power (that is, the amount of DC power discharge power) for the DC power output (that is, discharges) output to the DC load side, such as a DC motor, an electric vehicle, and notifies the control unit 311.

In addition, the amount of electricity measurement unit 310, the amount of power (that is, renewable energy) for the DC power supplied to the energy storage device 400 (ie, charging) from the AC-DC inverter 100 or the DC-DC converter 200. The amount of charging power) is measured and notified to the controller 311. In this case, the controller 300 may be provided in or outside the UPS 300 as a separate configuration for performing a corresponding function.

The control unit 311 receives information on the renewable energy charging power amount, commercial power charging power amount, commercial power supply power amount, commercial power supply power amount, commercial power supply power amount, commercial power supply power amount, and DC power discharge power amount that are notified from the power amount measuring unit 310. Collect and transmit information on the collected power amount to the communication unit 313, and transmit the information to the energy storage device 400 based on the information on the collected power amount or according to operation and management data received from the communication unit 313. The switching operation of the first switch unit 302 or the second switch unit 306 to perform the energy storage and management function for the control may be controlled.

In one embodiment, the control unit 311 calculates the power sales amount, the electric charge, etc. based on the information on the collected power amount using the power-money conversion information preset in the memory unit 312 to provide the user ( For example, the display information may be transmitted to the central control server 600 through the communication unit 313.

In one embodiment, the control unit 311 normally controls the switching operation of the first switch unit 302 to supply AC 220V or AC 330V commercial power supplied through the commercial power input unit 301 AC load output unit 303 may be supplied, or may be switched to the AC-DC converter 304. At this time, the control unit 311 checks the amount of commercial power use power notified from the power amount measuring unit 310, reads the reference power amount preset in the memory unit 312, and the corresponding commercial power use amount is read. When the reference power is smaller than the reference power, the switching operation of the first switch unit 302 is controlled to convert a part of the AC 220V or AC 330V commercial power supplied through the commercial power input unit 301 into the AC-DC converter 304 ) May be stored (ie, charged) in the energy storage device 400.

In one embodiment, the control unit 311 checks the amount of power stored in the energy storage device 400, reads the reference reserve power preset in the memory unit 312, and the identified power reserve reads the reference reserve power. In a larger case, the switching operation of the second switch unit 306 is controlled to output the AC 220V or AC 330V commercial power converted by the DC-AC converter 305 through the commercial power output unit 307 to perform another operation. It can be sold to the consumer (for example, KEPCO, other UPS 300, etc.).

In one embodiment, the controller 311 checks whether the charging time zone is set in the memory unit 312, and controls the switching operation of the first switch unit 302 in the charging time zone, the commercial power input unit 301. A portion of the commercial power of AC 220V or AC 330V supplied through the AC power may be switched to the AC-DC converter 304 to be stored (ie, charged) in the energy storage device 400.

In one embodiment, the controller 311 checks the amount of commercial power use power notified from the power amount measuring unit 310, reads the overload reference power amount preset in the memory unit 312, and uses the identified commercial power source. When the amount of power is larger than the read-out reference power used, the switching operation of the second switch unit 306 is controlled to output the AC load of AC 220V or AC 330V converted by the DC-AC converter 305. It can be additionally supplied to the unit 303 to be a stable power supply.

In one embodiment, the control unit 311 checks whether the discharge time period is set in the memory unit 312, and controls the switching operation of the second switch unit 306 in the case of the discharge time period AC 220V or AC 330V In addition to the commercial power of the, the AC-220V or AC 330V commercial power converted by the DC-AC converter 305 may be further supplied to the AC load output unit 303 to be a stable power supply.

In one embodiment, the controller 311 checks whether the DC load is connected to the DC load output unit 309 and controls the DC-DC converter 308 to control the DC power stored in the energy storage device 400. The DC load output unit 309 may be provided to a DC load side such as a DC motor or an electric vehicle.

In one embodiment, the control unit 311, the switching operation of the second switch unit 306 when there is no AC 220V or AC 330V commercial power supplied through the commercial power input unit 301 in the event of a planned power outage and disaster The control unit may continuously supply the AC 220V or AC 330V commercial power converted by the DC-AC converter 305 to the AC load output unit 303.

The memory unit 312 stores programs and data necessary for the control of the control unit 311 (that is, the uninterruptible power supply control function, the energy storage and management function, and the like). For example, power-money conversion information for converting electricity charges, power sales, etc., and a small amount of power used by commercial power supplied to the AC load output unit 303 may be stored in the energy storage device 400. The reference amount of power used to determine whether the amount of power used is enough, the amount of power stored in the energy storage device 400 may be provided to other consumers (for example, KEPCO, other UPS 300, etc.) and sold to other consumers. The reference reserve power for determining whether the amount of power is enough, and the amount of power used by the commercial power supplied to the AC load output unit 303 is small, so that part of the commercial power is stored in the energy storage field. Charge time period to determine whether the power consumption is low enough time (for example, from 23:00 to 6 am, etc.) that can be stored in the value 400, the use of commercial power supplied to the AC load output unit 303 The amount of electric power used for the overload reference used to determine whether to supply additional power stored in the energy storage device 400 to provide a stable power supply, the amount of commercial power supplied to the AC load output unit 303 to save energy The discharge time period for determining whether the power consumption is a large time period (for example, from 11:00 to 16:00) so as to supply additional power stored in the device 400 is stored in advance.

The communication unit 313 centrally controls information on the renewable energy charging power amount, the commercial power charging power amount, the commercial power supply power amount, the commercial power discharge power amount, the commercial power supply power amount, and the DC power discharge power amount delivered from the control unit 311. Converts the transmission data that can be received by the server 600, transmits the transmission data to the central control server 600 via the Internet 500, and also transmits the transmission data from the central control server 600 via the Internet 500. It receives and converts the operation and management data that can be recognized by the control unit 311, and transfers the converted operation and management data to the control unit 311.

Alternatively, although not shown in the drawing for convenience of description, the UPS 300 is a DC power input unit for receiving a DC power generated by a DC generator or the like, or a DC power source of another energy storage medium (for example, a battery), the corresponding DC power supply. It further includes a DC-DC converter for converting the DC power received through the input into a DC power that can be stored in the energy storage device 400 to store (ie, charge) the converted DC power in the energy storage device 400. can do.

3 is a flowchart illustrating a method of operating a power management system according to an embodiment of the present invention.

As shown in FIG. 3, in the case of an alternating current power supply supplied from a device or facility for generating renewable energy (that is, an alternating current power source), such as a wind generator, an energy storage device (eg, an AC-DC inverter 100) may be used. After being converted into a DC power source that can be stored in 400 is stored (that is, charged) in the energy storage device (400) (S301), and also a device for generating renewable energy (ie, DC power), such as a solar generator or In the case of the DC power supply supplied from the facility is converted into a DC power that can be stored in the energy storage device 400 in the DC-DC converter 200 and then stored (ie, charged) in the energy storage device 400 (S302). ).

In the case of commercial power of AC 220V or AC 330V, it is supplied from the UPS 300 and provided to an AC load side such as general household appliances such as a fan and a refrigerator, and a factory machine (S303).

At this time, the UPS 300 measures the amount of renewable energy charging power to the energy storage device 400 through the AC-DC inverter 100 or the DC-DC converter 200, and also to the AC load side for the supplied commercial power. The amount of power used is measured (S304).

The UPS 300 charges the energy storage device 400 by converting DC power into a part of commercial power other than the commercial power supplied to the AC load according to the amount of power to the AC load measured in step S304 described above. Part of the commercial power supply other than the commercial power supplied to the AC load when the amount of commercial power used in the above-described step S304 is small enough to charge the energy storage device 400 with a part of the commercial power supplied. To convert the DC power to charge the energy storage device 400 (S305).

Alternatively, the UPS 300 checks whether the preset power consumption is a low time period (for example, from 23 o'clock to 6 am), and commercially supplied to the AC load side when the power usage is low. Some of the commercial power other than the power source may be converted to DC power to charge the energy storage device 400.

Thus, the UPS 300 measures the amount of power used by the energy storage device 400 for the supplied commercial power, and thus the amount of power used by the measured energy storage device 400 to the AC load side measured in step S304 described above. The total amount of power used for the commercial power source is measured together with the amount of power used, and an electric charge may be calculated based on the measured total amount of power used (S306).

At the same time, the UPS 300 measures the amount of charging power to the energy storage device 400 for the supplied commercial power, thereby measuring the amount of charging power to the measured energy storage device 400 in step S304 described above. The total amount of charging power charged to the energy storage device 400 may be measured in combination with the amount of renewable energy charging power to the 400, and the amount of power charged to the energy storage device 400 may also be checked (S307).

Thereafter, the UPS 300 converts the DC power charged in the energy storage device 400 into AC 220V or AC 330V commercial power according to the amount of power charged in the energy storage device 400 identified in step S307. The other consumer (for example, KEPCO, other UPS 300, etc.) can be supplied and sold (S308).

In this case, the UPS 300 may measure the amount of power sold to commercial power for the power stored in the energy storage device 400, and may also calculate the amount of power sold based on the measured amount of sold power (S309).

On the other hand, the UPS 300 converts the DC power charged in the energy storage device 400 into a commercial power of AC 220V or AC 330V according to the amount of power to the AC load side measured in step S304 described above and adds it to the AC load side. In order to provide a stable power supply, when the amount of power used in the commercial power source measured in the above-mentioned step S304 is large, and the supplied commercial power is insufficient in the amount of power supplied to the AC load side, together with the supplied commercial power, The DC power charged in the energy storage device 400 is converted into AC 220V or AC 330V commercial power to be further supplied to the AC load (S310).

Alternatively, the UPS 300 checks whether the preset power consumption is a large time period (for example, from 11:00 to 16:00), and in addition to the commercial power supplied when the power usage is high, The DC power charged in the energy storage device 400 may be converted into a commercial power of AC 220V or AC 330V to be further supplied to the AC load side.

At this time, the UPS 300 measures the amount of discharge power to the commercial power for the power stored in the energy storage device 400, thereby selling the measured amount of discharge power to the commercial power measured by the commercial power measured in step S309. The total amount of discharged power to the commercial power source is measured together with the amount of power, and the amount of power charged to the energy storage device 400 may be checked again (S311).

On the other hand, the UPS 300 checks the case in which the AC 220V or AC 330V commercial power is not supplied in the above-described step S303 by the planned power outage and disaster (S312), and in this case, the energy storage device 400 The charged DC power is converted into AC 220V or AC 330V commercial power to continuously supply uninterrupted to the AC load (S313).

At this time, the UPS 300 again measures the amount of discharge power to the commercial power for the power stored in the energy storage device 400, thereby measuring the amount of discharge power to the commercial power measured again as the commercial power measured in step S309. The total amount of discharged power to the commercial power source is measured in combination with the sold amount of power (S314), and the amount of power charged to the energy storage device 400 may be checked again.

On the other hand, the UPS 300 checks the connection state with the DC load side, such as a DC motor, an electric vehicle, and corresponds to the DC power charged in the energy storage device 400 when connected to the DC load side. The connected DC load may be converted into a usable DC power source and provided to the connected DC load.

At this time, the UPS 300 measures the amount of discharge power to the DC power source for the power stored in the energy storage device 400, thereby selling the amount of discharge power to the measured DC power source to the commercial power source measured in step S309. The total amount of discharged power of the energy storage device 400 may be measured by combining the amount of power and the amount of discharged power to the commercial power source again measured in step S313, and the amount of power charged to the energy storage device 400 may be checked again.

Then, the UPS 300 measures the amount of renewable energy charging power to the energy storage device 400 measured in step S304 described above, the amount of power used for the commercial power supply (that is, the use to the AC load side measured in step S304 described above). The amount of power and the amount of used power to the energy storage device 400 measured in the above-described step S306), the amount of power charged to the energy storage device 400 for the commercial power source measured in the above-described step S307, the energy storage measured in the above-mentioned step S309 The amount of power sold to commercial power for the power stored in the device 400, the amount of discharge power to commercial power for the power stored in the energy storage device 400 measured in step S311 or step S314 described above (or energy storage). Information about the amount of discharged power to the DC power source for the power stored in the device 400, and the information on the collected power amount is sent to the user through the LCD. Jugeona to display, via the Internet 500 to be sent to the central control server (600) (S315).

At this time, the UPS 300 displays the information on the electric charges calculated in the above-described step S306 and the information on the electric power sales calculated in the above-mentioned step S309 together with the information on the collected power amount through the LCD to the user, It may be to transmit to the central control server 600 via the Internet (500).

Then, the central control server 600, receives the amount of power information from the plurality of UPS 300 via the Internet 500, respectively, and analyzes the received power amount information, each UPS 300 in accordance with the analyzed power amount information Generates operation and management data to perform energy storage and management functions for the energy storage device 400 for each UPS group belonging to each star or region and to each UPS 300 through the Internet 500. Send it.

In this case, the central control server 600 based on the power amount information received from the plurality of UPS 300 via the Internet 500, the power status for each UPS (300) or each UPS group belonging to each region (for example For example, the amount of power charged in the energy storage device 400, the amount of power used by the commercial power source, etc. may be analyzed, and the UPS may be notified to the analyzed power state, or each UPS may be configured according to the analyzed power state. Operation and management data can be generated by 300 or by each UPS group belonging to each region and transmitted to each UPS 300 through the Internet 500.

In addition, the central control server 600 based on the power amount information received from the plurality of UPS 300 via the Internet 500, the power sales amount, electricity bill for each UPS 300 or each UPS group belonging to each region It can be calculated, such as to inform the control office about the calculated electricity sales, electricity bills, or the like, or to manage the information on the calculated electricity sales, electricity bills, etc. It may be transmitted to each UPS 300 through.

For example, the central control server 600 may include a UPS 300 belonging to the first UPS group having a large amount of power stored in the energy storage device 400 but a small amount of used power, and a small amount of power stored in the energy storage device 400. After the UPS 300 belonging to the second UPS group having a large amount of power is used, the remaining power from the UPS 300 belonging to the first UPS group can be sold to the UPS 300 belonging to the second UPS group. Operation and management data can be generated and transmitted to each UPS 300 via the Internet 500.

Accordingly, the UPS 300 receives operation and management data (or information on electric power sales, electricity rates, etc.) from the central control server 600 through the Internet 500, and according to the received operation and management data. To perform the energy storage and management function for the energy storage device 400 as described above.

For example, the UPS 300 belonging to the first UPS group uses commercially available power of AC 220V or AC 330V based on DC power stored in the energy storage device 400 according to the operation and management data received from the central control server 600. The conversion may be supplied and sold to the UPS 300 belonging to the second UPS group.

4 is a flowchart illustrating a method of operating a power management system according to another embodiment of the present invention.

As shown in FIG. 4, when the commercial power input unit 301 receives commercial power of AC 220V or AC 330V and supplies it through the first switch unit 302, the first switch unit 302 may be a controller ( In accordance with the control of 311, the AC load output unit 303 is switched and connected to switch the commercial power supplied through the commercial power input unit 301 to the AC load output unit 303 side. That is, the controller 311 normally controls the switching operation of the first switch unit 302 to transfer AC 220V or AC 330V commercial power supplied through the commercial power input unit 301 to the AC load output unit 303. The AC load output unit 303 provides the commercial power switched through the first switch unit 302 to an AC load side such as a general household appliance such as a fan or a refrigerator, a factory machine, etc. (S401).

At this time, the electric power measuring unit 310 is the amount of power for the commercial power provided to the AC load side, such as general home appliances, factory machinery, etc. via the AC load output unit 303 through the first switch unit 302 (that is, commercial The amount of power used) and notifies the control unit 311 of the measured amount of commercial power used (S402).

Accordingly, the control unit 311 checks the amount of commercial power use power notified from the power amount measuring unit 310 and reads the reference power amount preset in the memory unit 312, and the determined amount of commercial power use power identified in the corresponding reference is read. Check whether it is smaller than the amount of power used (S403). Here, the reference power amount is a reference for determining whether the amount of power used by the commercial power supplied to the AC load output unit 303 is small enough to store a part of the commercial power in the energy storage device 400. Value.

If the amount of power used for commercial power is smaller than the reference power used in step S403 described above, the control unit 311 controls the switching operation of the first switch unit 302 to supply AC 220V supplied through the commercial power input unit 301. Alternatively, a part of the commercial power of 330 V AC is switched to the AC-DC converter 304 to store (ie, charge) the energy storage device 400 (S404).

In other words, the first switch unit 302 is connected to the AC-DC converter 304 under the control of the control unit 311 to switch the AC 220V or AC 330V commercial power supplied through the commercial power input unit 301. A part is switched to the side of the AC-DC converter 304, and the AC-DC converter 304 switches the commercial power that is switched through the first switch unit 302 under the control of the controller 311. It converts into a DC power source that can be stored at 400 and charges the converted DC power to the energy storage device 400.

In this case, the power amount measuring unit 310 is the amount of power (ie, charging) for the DC power stored in the energy storage device 400 (ie, charging) via the AC-DC converter 304 through the first switch unit 302. The amount of commercial power charging power) is measured and the control unit 311 is notified of the measured amount of commercial power charging power (S405).

In addition, the power measurement unit 310 measures the amount of power (ie, renewable energy charging power) for the DC power charged in the energy storage device 400 from the AC-DC inverter 100 or the DC-DC converter 200. In operation S406, the controller 311 notifies the measured amount of renewable energy charging power.

Accordingly, the control unit 311 combines the amount of commercial power charging power notified from the power amount measuring unit 310 in step S405 and the renewable energy charging power amount notified from the power amount measuring unit 310 in step S406. The total amount of charging power charged in 400 may be measured, and the amount of power charged in the energy storage device 400 may also be checked (S407).

At this time, the electric power measuring unit 310 measures the amount of power used to the AC load side for the AC 220V or AC 330V commercial power supplied through the commercial power input unit 301, and the amount of power used to the energy storage device 400, the control unit 311, the controller 311 may check the total amount of power used for the commercial power supply by combining the amount of power used for the AC load and the amount of power used for the energy storage device 400 (S408).

In addition, the control unit 311 reads the power-money conversion information preset in the memory unit 312, and corresponds to the read-out power-money conversion information based on the information on the confirmed total amount of power used, and thereby converts the electricity charges. In this case, information about the calculated electric charge may be provided to the user (for example, a display) or may be transmitted to the central control server 600 through the communication unit 313. Here, the power-money conversion information is a database of information for converting into money (for example, an electric bill) corresponding to the amount of power used and stored in the memory unit 312.

The controller 311 reads the reference reserve power preset in the memory unit 312, and checks whether the charge power amount checked in step S407 described above is greater than the read reference reserve power amount (S409). Here, the reference reserve power amount, whether the amount of power stored in the energy storage device 400 is enough to be sold to other consumers by providing to other consumers (for example, KEPCO, other UPS 300, etc.). The reference value for judging.

At this time, when the amount of power charged in the energy storage device 400 is greater than the reference reserve power in step S409 described above, the controller 311 controls the switching operation of the second switch unit 306 to convert the DC-AC converter ( The commercial power of AC 220V or AC 330V converted at 305 is output through the commercial power output unit 307 to be sold to another consumer (for example, KEPCO, another UPS 300, etc.) (S410).

In other words, the DC-AC converter 305 converts the DC power provided from the energy storage device 400 into AC 220V or AC 330V commercial power under the control of the controller 311 to remove the converted commercial power. 2 switch unit 306, the second switch unit 306 is connected to the commercial power output unit 307 switching the commercial power provided from the DC-AC converter 305 under the control of the control unit 311 The commercial power output unit 307 is switched to the commercial power output unit 307 side, and thus the commercial power output unit 307 switches the commercial power switched through the second switch unit 306 to another consumer (eg, KEPCO, another UPS ( 300, etc.) to be sold to other consumers.

In addition, the electricity amount measuring unit 310 is provided to the other consumer (eg, KEPCO, another UPS 300, etc.) via the commercial power output unit 307 through the second switch unit 306 (ie, sales). The amount of power for the commercial power supply (that is, the amount of commercial power sold) is measured, and the controller 311 is notified of the measured amount of commercial power sold (S411).

At this time, the control unit 311 reads the power-money conversion information previously set in the memory unit 312 and based on the information on the amount of commercial power sales power notified from the power amount measuring unit 310 in step S411 described above. The power sales amount may be calculated in correspondence with the read power-money conversion information, and information (eg, display) on the calculated power sales amount may be provided to the user, or the central control server may be provided through the communication unit 313. 600 may be sent. Here, the power-money conversion information is a database of information for converting into money (for example, power sales amount, etc.) corresponding to the sales power amount and stored in the memory unit 312.

On the other hand, when the amount of commercial power used power is not less than the reference power used in step S403 described above, the control unit 311 reads the overload reference power used in the memory unit 312, the corresponding amount of commercial power used confirmed It is checked whether the read overload reference power is greater than the amount of power used (S412). Here, the overload reference power amount is used to determine whether to supply additional power stored in the energy storage device 400 so that the power supply of the commercial power supplied to the AC load output unit 303 can be a stable power supply. Reference value.

In this case, when the amount of commercial power used is greater than the overload reference power in step S412 described above, the controller 311 controls the switching operation of the second switch unit 306 and is converted by the DC-AC converter 305. Commercial power of AC 220V or AC 330V is additionally supplied to the AC load output unit 303 to be a stable power supply (S413).

In other words, the DC-AC converter 305 converts the DC power provided from the energy storage device 400 into AC 220V or AC 330V commercial power under the control of the controller 311 to remove the converted commercial power. 2 switch unit 306, the second switch unit 306 is connected to the AC load output unit 303 by switching the commercial power provided from the DC-AC converter 305 under the control of the control unit 311 The AC load output unit 303 is switched to the AC load output unit 303, and the AC load output unit 303 switches the commercial power switched through the second switch unit 306, such as a general household appliance such as a fan or a refrigerator, or a factory machine. Provide additional on the load side.

In addition, the electric power measuring unit 310 passes through the AC load output unit 303 through the second switch unit 306, and the amount of electric power for the commercial power discharged to the AC load side such as general home appliances, factory machines, etc. The amount of discharge power) is measured, and the control unit 311 is notified of the measured amount of commercial power discharge power (S414).

Meanwhile, the controller 311 checks whether the DC load is connected to the DC load output unit 309 and controls the DC-DC converter 308 when the DC load is connected to the DC load output unit 309. The DC power stored in the energy storage device 400 may be provided to a DC load side such as a DC motor or an electric vehicle through the DC load output unit 309.

At this time, the DC-DC converter 308 converts the DC power provided from the energy storage device 400 into a DC power that can be used by a DC load side such as a DC motor or an electric vehicle under the control of the controller 311. In addition, the converted DC power is provided to the DC load output unit 309. Accordingly, the DC load output unit 309 outputs the DC power provided from the DC-DC converter 308 to the DC load side such as a DC motor or an electric vehicle.

In addition, the amount of electricity measuring unit 310 is the amount of power (eg, DC power discharge) for the DC power discharged from the DC-DC converter 308 to the DC load side, such as a DC motor, an electric vehicle, through the DC load output unit 309. Power amount) is measured and notified to the control unit 311.

Alternatively, the controller 311 checks whether the charging time zone is preset in the memory unit 312, and controls the switching operation of the first switch unit 302 when the current time is the charging time zone. Some of the AC 220V or AC 330V commercial power supplied through the 301 may be switched to the AC-DC converter 304 to charge the energy storage device 400. Here, the charging time period is a time when the power consumption is low enough to use a small amount of power of the commercial power supplied to the AC load output unit 303 to store a part of the commercial power in the energy storage device 400 (for example, 23:00 to 6 am, etc.) is set in advance and stored in the memory unit 312.

Alternatively, the controller 311 checks whether the discharge time period is set in the memory unit 312, and controls the switching operation of the second switch unit 306 when the current time is the discharge time period, thereby changing the AC 220V or the like. In addition to the AC 330V commercial power supply, AC 220V or AC 330V commercial power converted by the DC-AC converter 305 may be additionally supplied to the AC load output unit 303 to be a stable power supply. . Here, the discharge time period, the amount of power used by the commercial power supplied to the AC load output unit 303 has a large amount of power consumption enough to supply additional power stored in the energy storage device 400 (for example, 11 to 16:00, etc.) is set in advance and stored in the memory unit 312.

In addition, the controller 311 controls the switching operation of the second switch unit 306 even when there is no AC 220V or AC 330V commercial power supplied through the commercial power input unit 301 in the event of a planned power failure or disaster. Thus, the AC-220V or AC-330V commercial power converted by the DC-AC converter 305 may be continuously supplied to the AC load output unit 303.

Then, the control unit 311 is for the renewable energy charging power amount, commercial power charging power amount, commercial power supply power amount, commercial power discharge power amount, commercial power supply power amount, commercial power supply power amount, and DC power discharge power amount that is notified from the power measurement unit 310 The information is collected and information about the collected power amount is displayed to the user through the LCD or transmitted to the central control server 600 through the Internet 500 (S415).

In this case, the control unit 311 calculates an electric power sales amount, an electric charge, etc. based on the information on the collected power amount using the power-money conversion information preset in the memory unit 312 together with the collected power amount information. It may be displayed to the user via the LCD, or may be sent to the central control server 600 via the Internet (500).

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the present invention as defined by the following claims It can be understood that

100: AC-DC inverter
200: DC-DC converter
300: UPS
400: energy storage device
500: Internet
600: central control server
301: commercial power input unit
302: first switch
303: AC load output unit
304: AC-DC converter
305: DC-AC converter
306: second switch unit
307: commercial power output unit
308: DC-DC converter
309: DC load output unit
310: power measurement unit
311: control unit
312: memory
313: communication unit

Claims (32)

A plurality of UPSs;
A central control server for analyzing the amount of power transmitted from the plurality of UPSs, generating operation and management data for each UPS or each UPS group belonging to each region and transmitting the generated data to each UPS; And
Internet for transmitting and receiving data between each UPS and the central control server,
Each of the plurality of UPSs
Converting the commercial power received through the switching to a DC power, and charging the converted DC power and the new renewable energy (DC power) received in the internal energy storage device, and converts the charged DC power to commercial power Supplying the converted commercial power and bypassed commercial power by switching to the AC load side, supplying and selling the converted commercial power to the outside, and changing the charged DC power to DC power to the DC load side Measure the power amounts (the amounts of power for each of the input commercial power and renewable energy, charged DC power, converted commercial power, bypassed commercial power, and supplied commercial power), and measure the power. Collect information about the amount of power and transmit the information to the central control server and receive operation and management data from the central control server. Power management system, characterized in that.
delete The method of claim 1, wherein the UPS,
And receiving and supplying the DC power charged in the energy storage device to the DC power for use on the DC load side.
The method of claim 1, wherein the UPS,
The power management system, characterized in that for charging the energy storage device by converting commercial power into direct current power in association with the amount of power used for the commercial power or a predetermined charging time period.
The method of claim 1, wherein the UPS,
Checking the case that the commercial power is not supplied to the power management system, characterized in that by converting the DC power charged in the energy storage device into commercial power supply uninterrupted continuous supply to the AC load side.
The method of claim 1, wherein the UPS,
The power management system according to claim 1, wherein the DC power charged in the energy storage device is converted into commercial power according to the amount of charging power of the energy storage device.
The method of claim 1, wherein the UPS,
According to the amount of power used by the commercial power, or in association with a predetermined discharge time period, the power management system, characterized in that for converting the DC power charged in the energy storage device into commercial power to supply additionally to the AC load side.
The method of claim 1, wherein the UPS,
A commercial power input unit for receiving and supplying commercial power;
A first switch unit for switching commercial power supplied through the commercial power input unit;
An AC-DC converter converting commercial power switched through the first switch unit into DC power and charging the energy storage device;
A DC-AC converter converting DC power charged in the energy storage device into commercial power;
A second switch unit for switching the commercial power converted by the DC-AC converter;
An AC load output unit for supplying commercial power switched through the first switch unit or the second switch unit to an AC load side;
A commercial power output unit supplying and selling commercial power switched through the second switch unit to the outside;
A DC-DC converter converting DC power charged in the energy storage device into DC power for use by the DC load side;
A DC load output unit supplying the DC power converted by the DC-DC converter to a DC load side;
The amount of commercial power charging power charged to the energy storage device through the first switch unit, the amount of commercial power used to be supplied to the AC load side through the first switch unit, and the commercial power discharge discharged to the AC load side through the second switch unit. Power amount, the amount of commercial power sold by the second switch unit, the amount of DC power discharged discharged to the DC load side through the DC-DC converter, the energy storage device through the AC-DC inverter or the DC-DC converter An amount of electricity measuring unit measuring an amount of renewable energy charging power charged in the;
A control unit which collects information on the amount of power measured by the power amount measuring unit and controls the switching operation of the first switch unit or the second switch unit based on the collected power amount information or according to the operation and management data;
A memory unit for storing a program and data necessary for the control of the controller; And
And a communication unit converting and transmitting the amount of power information collected by the control unit to the transmission data that can be received by the central control server, and receiving and transmitting operation and management data from the central control server to the control unit. system.
The method of claim 8, wherein the control unit,
When the amount of commercial power use measured by the power amount measuring unit is smaller than the reference use power stored in the memory unit or whether the charging time is stored in the memory unit, the first switch unit is controlled and supplied through the commercial power input unit. A part of the commercial power source to be switched to the AC-DC converter, and checks a case where the amount of power charged in the energy storage device is greater than a reference reserve power stored in the memory unit, and controls the second switch unit to control the DC- Switching the commercial power converted by the AC converter to the commercial power output unit, when the amount of commercial power used power measured by the power amount measuring unit is greater than the overload reference power amount stored in the memory unit or discharge time period stored in the memory unit Check whether the second switch unit The commercial power converted by the DC-AC converter further switches to the AC load output unit, and checks whether the DC load is connected to the DC load output unit to control the DC-DC converter, and through the commercial power input unit. Checking that there is no commercial power supplied to the power control system characterized in that by controlling the second switch unit to switch the commercial power converted in the DC-AC converter uninterrupted to the AC load output unit.
The method of claim 8, wherein the UPS,
A DC power input unit configured to receive a DC power source or a DC power source of another energy storage medium; And
And a DC-DC converter converting DC power input through the DC power input unit into DC power to be stored in the energy storage device and charging the DC power.
The method of claim 1, wherein the UPS,
The power management system, characterized in that for calculating the power sales amount, the electricity bill based on the sales power amount, the commercial power use power amount using the predetermined power-money conversion information to provide to the user or transmit to the central control server.
According to claim 1, wherein the central control server,
Based on the amount of power received from a plurality of UPSs, the power status is analyzed for each UPS or each UPS group in each region, or the power sales and electricity rates are calculated using preset power-money conversion information. According to the analyzed power status, each UPS, or each UPS group belonging to each region generates and transmits the operation and management data for energy storage and management to each UPS.
The method of claim 12, wherein the central control server,
After distinguishing a UPS belonging to the first UPS group with a larger amount of charge power than the power used and a UPS belonging to a second UPS group with a lower amount of charge power, the remaining power from the UPS belonging to the first UPS group is assigned to the second UPS group. Power management system, characterized in that for generating and transmitting the operation and management data for sale to the UPS belonging to each UPS.
In a power management system including a plurality of UPS and a central control server,
Each UPS is supplied with commercial power and provided to the AC load side, or converted to DC power to charge, and converting the charged DC power to commercial power to supply to the AC load side or outside;
The UPS checks the amount of power used, the amount of charge power, the amount of discharge power and the amount of power sold by the commercial power supply to the central control server;
Analyzing, by the central control server, the amount of power transmitted from each UPS, generating operation and management data for each UPS or each UPS group belonging to each region, and transmitting the generated data to each UPS;
Each UPS receiving operation and management data from the central control server to perform energy storage and management and uninterruptible power control;
Receiving alternating current power from an AC-DC inverter and converting the DC power to a DC power source for charging the energy storage device;
Receiving DC power from a DC-DC converter and converting the DC power into DC power to charge the energy storage device;
Measuring an amount of renewable energy charging power charged to the energy storage device through the AC-DC inverter or the DC-DC converter;
Measuring the amount of power used by the UPS to the AC load side when the commercial power is supplied to the AC load side;
Checking whether the amount of power used by the UPS to the AC load side is sufficient to charge a part of commercial power to the energy storage device, and converts a part of commercial power into DC power to charge the energy storage device. step;
Measuring an amount of power used by the UPS to an energy storage device for commercial power, and measuring the total amount of power used for commercial power in combination with the measured amount of power used for the AC load;
Calculating an electric charge based on the measured total amount of electric power using the power-money conversion information preset by the UPS;
Measuring the amount of charging power from the UPS to the energy storage device for commercial power, and measuring the total amount of charging power charged to the energy storage device in combination with the measured renewable energy charging power; And
Confirming the amount of power charged to the energy storage device in the UPS.
delete delete delete 15. The method of claim 14,
Determining whether the UPS corresponds to a predetermined charging time period, and converting a part of commercial power into direct current power to charge the energy storage device.
delete 15. The method of claim 14,
Measuring, by the UPS, the amount of power sold to commercial power when the DC power charged to the energy storage device is converted into commercial power and sold to the outside according to the identified amount of charged power; And
And calculating, by the UPS, a power sales amount based on the measured sales power amount by using preset power-money conversion information.
21. The method of claim 20,
Check whether the amount of power used by the UPS to the AC load side measured by the UPS is insufficient in the amount of power supplied to the AC load side, and convert the DC power charged in the energy storage device into commercial power to supply the AC load side additionally. Operation method of a power management system, characterized in that it further comprises the step.
21. The method of claim 20,
Determining whether the UPS corresponds to a preset charging time period, and converting the DC power charged in the energy storage device into commercial power and supplying additional power to an AC load side. How the system works.
The method of claim 22,
Measuring, by the UPS, the amount of discharge power to commercial power for the power charged to the energy storage device, and measuring the total amount of discharge power to commercial power in combination with the measured sales power to commercial power; And
And re-confirming the amount of power charged to the energy storage device in the UPS.
24. The method of claim 23,
Identifying a case where commercial power is not supplied from the UPS, converting direct current power charged in the energy storage device into commercial power, and continuously supplying uninterrupted power to an AC load side;
Re-measuring the amount of discharge power to commercial power for the power charged in the energy storage device in the UPS, and re-measuring the total amount of discharge power to commercial power in combination with the measured sales power to commercial power; And
And re-confirming the amount of power charged to the energy storage device in the UPS.
25. The method of claim 24,
Checking a connection state with a DC load side in the UPS and converting the DC power charged in the energy storage device into a DC power for use by the DC load side;
Measuring the amount of discharge power from the UPS to a DC power source, and measuring the total amount of discharge power of the energy storage device by adding the measured amount of power sold to the commercial power and the amount of discharge power to the commercial power; And
And re-confirming the amount of power charged to the energy storage device in the UPS.
The method of claim 25, wherein the transmitting to the central control server,
The renewable energy charging power amount from the UPS, the amount of power used to the AC load side, the amount of power used to the energy storage device, the amount of power charged to the energy storage device, the amount of power sold to the commercial power source, the discharge to the commercial power source Collecting information on the amount of electricity or the amount of discharged power to the DC power supply, the user to display on the LCD or to transmit to the central control server, characterized in that the operation method of the power management system.
15. The method of claim 14, wherein transmitting to each UPS,
The central control server analyzes the power status for each UPS or each UPS group belonging to each region based on the amount of power received from each UPS, and notifies the control center, or uses the preset power-money conversion information. It calculates the sales amount, the electric charge, and generates and transmits operation and management data for energy storage and management for each UPS group or each UPS group belonging to each region according to the analyzed power state, and transmits the data to each UPS. Operation method of power management system to do.
28. The method of claim 27, wherein transmitting to each UPS,
The remaining power from the UPS belonging to the first UPS group after distinguishing the UPS belonging to the first UPS group having a larger amount of charging power than the used power and the UPS belonging to the second UPS group having a smaller amount of charging power than the used power in the central control server Generating and transmitting operation and management data for sale to a UPS belonging to a second UPS group, and transmitting the same to each UPS.
29. The method of claim 28, wherein performing energy storage and management and uninterruptible power control:
In the UPS belonging to the first UPS group, the DC power charged in the energy storage device is converted into commercial power and supplied to the UPS belonging to the second UPS group according to the operation and management data received from the central control server. A method of operating a power management system.
In the operation method of a power management system including a plurality of UPS,
Measuring the amount of power used by the commercial power to the AC load while receiving the commercial power and providing the AC load to the AC load side;
Checking whether the amount of commercial power used is less than a preset reference power, converting a part of commercial power into a DC power, charging the energy storage device, and measuring the amount of commercial power charging power;
Measuring the amount of renewable energy charging power charged to the energy storage device from an AC-DC inverter or a DC-DC converter;
Measuring the total amount of charging power charged by the energy storage device by combining the amount of the commercial power charging power and the amount of renewable energy charging power, and confirming the amount of power charged in the energy storage device;
Measuring the total amount of power used for the commercial power source by measuring the amount of power used for the commercial power source to the energy storage device and adding the amount of commercial power source power to the AC load side;
Checking whether the amount of power charged in the energy storage device is greater than a predetermined reference reserve power, converting the DC power charged in the energy storage device into commercial power, supplying the product to outside, and measuring the amount of commercial power selling power;
Collecting information on the amount of power and displaying the collected amount of power information to the user or transmitting the collected amount of power information to a central control server;
Calculating an electric charge in correspondence with preset power-money conversion information based on the total amount of power used for the commercial power source;
Calculating an electric power selling amount based on the corresponding electric power-money conversion information based on the electric power selling amount of commercial power; And
And providing information on the calculated electric charge and electric power sales amount to a user or transmitting the information to the central control server.
delete 31. The method of claim 30,
Checking whether the amount of commercial power used is greater than a preset overload reference power, converting direct current power charged in the energy storage device into commercial power, and supplying additional power to an AC load and measuring the amount of commercial power discharge power;
Checking whether the DC load is connected, converting the DC power charged in the energy storage device into the DC power to be used by the DC load side, and measuring the amount of DC power discharge power;
Checking whether the time period is a preset charging time, converting a part of commercial power into DC power to charge the energy storage device, and measuring the amount of commercial power charging power;
Checking whether the discharge time is a predetermined time period, converting the DC power charged in the energy storage device into commercial power to supply the AC power to the AC load side, and measuring the amount of commercial power discharge power;
Checking a case in which there is no supply of commercial power, converting the DC power charged in the energy storage device into commercial power, continuously supplying uninterrupted power to an AC load, and measuring the amount of commercial power discharge power;
Collecting information on the renewable energy charging power amount, the commercial power charging power amount, the commercial power supply power amount, the commercial power discharge power amount, the commercial power selling power amount, and the DC power discharge power amount; And
And displaying the collected power amount information through a LCD or transmitting the collected power amount information to the central control server.

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