KR102590224B1 - Power management system using shared-energy storage system - Google Patents

Abstract

A power management system according to an embodiment of the present invention includes an energy storage device (ESS) including a battery that stores power, and a control device (EMS) that controls the power stored in the energy storage device to be supplied to a plurality of clients. Including, a plurality of clients may receive power stored in the energy storage device.

Description

Power management system {POWER MANAGEMENT SYSTEM USING SHARED-ENERGY STORAGE SYSTEM}

The present invention relates to a power management system including an ESS capable of supplying power to each of a plurality of clients.

A power management system refers to a system for efficiently managing power use of an installation target (eg, home, building, etc.). This power management system can manage the charging and discharging of batteries included in an Energy Storage System (ESS), or monitor the power consumption status of power consumption devices installed in the installation target. Alternatively, the power management system can control the overall operation of power management, such as supplying, storing, and selling power produced by renewable energy generation such as solar power generation.

As the spread of new and renewable energy generation such as solar power generation increases, the spread of power management systems is also expanding. In particular, the spread of small power management systems installed in homes, such as HEMS (home energy management system), is increasing.

In the case of such a power management system, a certain amount of installation area is required due to the capacity of the battery, etc. However, in Korea's residential environment, which is mainly composed of apartments, villas, and officetels, it may be difficult for each household (client) to secure the installation area of the power management system. In this case, the power management system may not be equipped with a large capacity battery, and if the battery capacity is low, the efficiency of the power management system may rapidly decrease.

The problem to be solved by the present invention is to provide a power management system that includes an ESS that is connected to a plurality of clients and supplies power to the loads of each of the plurality of clients.

A power management system according to an embodiment of the present invention includes an energy storage device (ESS) including a battery that stores power, and a control device (EMS) that controls the power stored in the energy storage device to be supplied to a plurality of clients. Including, a plurality of clients may receive power stored in the energy storage device.

According to an embodiment of the present invention, the power management system is implemented so that a plurality of clients can receive power from the ESS, making it possible to implement more effective power management facilities in apartments and other apartment complexes. That is, compared to a separate power management system implemented for each of a plurality of clients, a large-capacity battery can be provided, so the efficiency of power management can be improved.

Additionally, the power management system enables easy power trading between clients based on the power consumption of each of the plurality of clients. Accordingly, each client can effectively reduce electricity bills through trading power stored in the ESS battery.

1 is a schematic block diagram of a power management system according to an embodiment of the present invention.
FIG. 2 is a block diagram showing an embodiment of the power management system shown in FIG. 1.
Figure 3 is a diagram showing an example of an operation in which a power management system manages renewable energy generated power.
Figure 4 is a diagram showing an example of an operation in which a power management system receives late-night power from the power system.
Figure 5 is a diagram showing an example of an operation in which a power management system supplies power stored in a battery to clients.
Figure 6 is an example diagram showing an operation in which a power management system performs power trading between clients.
7 to 10 are exemplary diagrams illustrating the operation of a power management system providing various power management data to a client.

Hereinafter, embodiments disclosed in this specification will be described in detail with reference to the attached drawings. The attached drawings are only for easy understanding of the embodiments disclosed in this specification, and the technical idea disclosed in this specification is not limited by the attached drawings, and all changes, equivalents, and changes included in the spirit and technical scope of the present invention are not limited. It should be understood to include water or substitutes.

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

Referring to FIG. 1 , the power management system 10 may include an energy storage device 100 (eg, an energy storage system (ESS)) and an energy management device 200 (eg, an energy management system (EMS)).

The ESS 100 can convert and store power supplied from the renewable energy generation device 300 or the power system 500. The ESS 100 will be described in more detail later with reference to FIG. 2.

The EMS 200 may control the power conversion operation of the ESS 100 or control the power supplied from the renewable energy generation device 300 or the power system 500 to be stored in the ESS 100. Alternatively, the EMS 200 may control the operation of supplying power stored in the ESS 100 to a plurality of clients 400a to 400N or selling it to the power system 500.

In addition, the EMS 200 may obtain information related to the power consumption status (power consumption, etc.) of each of the plurality of clients 400a to 400N, and control power supply to the plurality of clients 400a to 400N. You may.

The renewable energy power generation device 300 may be implemented as a solar power generation device or a wind power generation device. The EMS 200 may store the power generated by the renewable energy generation device 300 in the ESS 100, provide it to a plurality of clients 400a to 400N, or sell it to the power system 500.

Each of the plurality of clients 400a to 400N may receive power from the ESS 100, the renewable energy generation device 300, or the power system 500 to drive various power consumption devices. For example, when the power management system 10 is installed in an apartment complex, a plurality of clients may correspond to homes or public facilities in the apartment complex.

Hereinafter, an example of a specific configuration of the power management system 10 will be described with reference to FIG. 2.

FIG. 2 is a block diagram showing an embodiment of the power management system shown in FIG. 1.

In the following drawings, it is assumed that the renewable energy power generation device 300 is implemented as a solar power generation device. The solar power generation device may include a solar panel 301 and a PV inverter 302 that converts direct current power supplied from the solar panel 301 into alternating current power. Although not shown, the power management system 10 may further include a meter that measures the amount of power output from the PV inverter 302.

Additionally, depending on the embodiment, the power conversion device 110 and the PV inverter 302 of the ESS 100 may be implemented as an integrated power conversion device. In this case, the direct current power output from the solar panel 301 may be input to the power conversion device, converted by the power conversion device, and stored in the battery 130. The amount of power output from the solar panel 301 can be measured separately inside the power conversion device 110.

Referring to FIG. 2, the ESS 100 may include a power conversion device 110 and a battery 130. Depending on the embodiment, the ESS (100) may further include a meter 120, but the meter 120 may be provided between the ESS (100) and the power system 500.

The power conversion device 110 may include a plurality of inverters and converters. For example, the power conversion device 110 may convert direct current power stored in the battery 130 into alternating current power and provide it to a client (eg, the first client 400a) or the power system 500. Additionally, the power conversion device 110 may convert the power produced and provided by the solar panel 301 and store it in the battery 130. In addition, the power conversion device 110 may convert alternating current power supplied from the power system 500 into direct current power and store it in the battery 130.

The meter 120 can measure the amount of power discharged from the ESS (100). The amount of power discharged from the ESS (100) includes the amount of power supplied (sold) from the ESS (100) to the power system 500, and the amount of power supplied from the ESS (100) to a plurality of clients (400a to 400N). You can.

The battery 130 may store power supplied from the solar panel 301 or the power system 500. According to an embodiment of the present invention, the battery 130 may be implemented to have a larger capacity compared to a power management system implemented separately for each of the plurality of clients 400a to 400N. This is because, when the power management system 10 is implemented in an apartment, the ESS 100 can be installed on the roof of the apartment, in the basement, or in other common facilities, making it possible to secure a larger area compared to the ESS being installed within each home. Because.

The power management system 10 may distribute power stored in the battery 130 to each of the plurality of clients 400a to 400N. The power management system 10 may allocate the amount of power stored in the battery 130 to each client (400a to 400N) and provide the allocated amount of power to each client (400a to 400N). For example, if the capacity of the battery 130 is 500 kWh and the number of clients is 50 households, the amount of power of the battery 130 allocated to each client may correspond to 10 kWh. Accordingly, the EMS 200 can calculate the electricity bill for each client by considering that among the daily power consumption of each client, 10 kWh of power is provided from the battery 130 and the remaining power is provided from the power system 500. there is.

Meanwhile, the daily power consumption for each client (400a to 400N) may be different. For example, the first client 400a may consume an amount of power that exceeds the allocated amount of power, and the second client 400b may consume an amount of power that is less than the allocated amount of power. In this case, the power management system 10 may control the ESS 100 to provide surplus power for the second client 400b to the first client 400a. That is, the first client 400a can purchase the surplus power from the second client 400b. The surplus power may be cheaper than the power of the power system 500. Accordingly, the first client 400a can effectively reduce electricity bills by purchasing surplus power at a low price. Additionally, the second client 400b can earn profit by selling the surplus power to other clients. This will be described later through FIGS. 6 and 9.

EMS 200 may control the overall operation of the power management system 10. For example, the EMS (200) may be implemented in the form of a server that is connected (wired or wirelessly) to the ESS (100), the clients (400a to 400N), and the power system (500), respectively. However, the form of the EMS (200) is It is not limited to this.

The EMS 200 calculates the amount of power measured by the meter 120 (the amount of power discharged from the ESS 100) and the amount of power supplied (purchased) from the power system through the power system 500 (not shown). You can measure the amount of power supplied (sold) and obtain the amount of power supplied (consumed) to each client.

Additionally, based on the obtained information on each amount of electricity, the EMS 200 may calculate the electricity bill for each of the clients 400a to 400N. The EMS (200) calculates the power consumption of each of the clients (400a - 400N) based on the amount of power of the battery 130 allocated to each of the clients (400a - 400N) by dividing the power consumption by the amount of power supplied from the battery 130 and the power system ( 500) can be classified by the amount of power supplied. The EMS 200 may calculate the electricity bill for each of the clients 400a to 400N based on the classification result. For example, if the power consumption of the first client 400a is 15 kWh and the power amount of the battery 130 allocated to the first client 400a is 10 kWh, the EMS 200 consumes the power of the first client 400a Consumption can be divided into 10 kWh of power supplied from the battery 130 and 5 kWh of power supplied from the power system 500. The EMS 200 may calculate the electricity bill of the first client 400a based on the classification result.

Each of the clients 400a to 400N may receive the electricity bill information through an application installed on a terminal capable of communicating with the EMS 200.

Meanwhile, the EMS 200 may detect the operating status or abnormality of the ESS 100, the renewable energy power generation device 300, and the clients 400a to 400N and notify the manager, etc.

Each of the clients 400a to 400N may include a meter, a load, and a gateway. In Figure 2, for convenience of explanation, only the first client 400a and the meter 410a, load 420a, and gateway 430a included therein are shown, but other clients also have a similar configuration to the first client 400a. It can be implemented to include.

The meter 410a can measure the amount of power supplied to the load of the first client 400a. The load 420a may include various devices that are driven by receiving power from the ESS 100 or the power system 500. The gateway 430a may acquire information about the amount of power measured by the meter 410a or information about the operating state or presence of an abnormality of the load 420a, and transmit the obtained information to the EMS 200.

Hereinafter, various operations performed by the power management system according to an embodiment of the present invention will be described with reference to FIGS. 3 to 10.

Figure 3 is a diagram showing an example of an operation in which a power management system manages renewable energy generated power.

Referring to FIG. 3, the solar panel 301 can produce power by converting solar energy into electrical energy. The PV inverter 302 can convert the produced direct current power into alternating current power and output it. The power output from the PV inverter 302 may be supplied to the clients' loads (e.g., the load 420a of the first client 400a), stored in the battery 130, or sold to the power system 500. there is.

For example, when the power supplied to the loads of the clients 400a to 400N is lower than the power output from the PV inverter 302, the first power PVE1 corresponding to a portion of the power output from the PV inverter 302 can be stored in the battery 130. At this time, the power conversion device 110 may convert the first power PVE1 in the form of alternating current into direct current power and store it in the battery 130 .

Depending on the embodiment, when the power supplied to the loads of the clients 400a to 400N is lower than the power output from the PV inverter 302 and the battery 130 is fully charged, the EMS 200 The second power (PVE2), which corresponds to a portion of the power output from the inverter 302, can be sold to the power system 500. The EMS 200 may obtain information about the amount of sold second power PVE2 from the power system 500 or a meter (not shown) connected to the power system 500. The operator of the power management system obtains compensation (e.g., REP (renewable energy point)) corresponding to the amount of power produced by the solar panel 301 from the power company and provides (sells) it to the power system 500. Compensation corresponding to the amount of second power (PVE2) can be obtained from the power company.

Figure 4 is a diagram showing an example of an operation in which a power management system receives late-night power from the power system.

Referring to FIG. 4, the price of power provided from the power system 500 may vary depending on time. Rates during times when demand for electricity is relatively high (e.g., 2 to 5 p.m.) may be higher than rates during times when demand for electricity is relatively low (e.g., 2 to 5 a.m.).

Accordingly, the power management system 10 can purchase power from the power system 500 during times when rates are low and store it in the battery 130 of the ESS 100. For example, if the late-night rate (2:00 to 5:00 a.m.) is the lowest daily rate, the power management system 10 receives late-night power (LNE) from the power system 500 and supplies it to the battery. It can be saved at (130). That is, the battery 130 may be capable of storing power twice a day (storing late-night power (LNE) and renewable energy generated power (PVE1)).

The power management system 10 may control the ESS 100 to discharge the power stored in the battery 130 during the time when the charge is at its maximum. Accordingly, a plurality of clients (400a to 400N) can drive the load by receiving power stored in the battery 130 during the time when the charge is maximum, and thus can use power at a cheaper price.

Figure 5 is a diagram showing an example of an operation in which a power management system supplies power stored in a battery to clients.

Referring to FIG. 5 , the power management system 10 may supply power stored in the battery 130 to each of the clients 400a and 400b. For example, the first client 400a may provide the first power E1 supplied from the ESS 100 to the load 420a. The second client 400b may provide the second power E2 supplied from the ESS 100 to the load 420b.

According to the embodiment, the power management system 10 supplies power from the battery 130 to the clients 400a and 400b during a time period (peak time) when the price of power supplied from the power system 500 is relatively high. You can control it as much as possible. Accordingly, clients 400a and 400b can inexpensively use power charged late at night or power charged by renewable energy generation. In addition, the EMS 200 minimizes the purchase of power from the power system 500 at peak times, thereby receiving compensation (incentives, points, rate discounts) from the power system 500 according to the demand response (DR) market. etc.) can also be obtained.

Figure 6 is an example diagram showing an operation in which a power management system performs power trading between clients.

In the embodiment of Figure 5, the first client 400a and the second client 400b may use only the allocated power among the power stored in the battery 130. However, the amount of power used by each client may be different.

Referring to FIG. 6, 1 kWh of the power charged in the battery 130 may be allocated to the first client 400a and the second client 400b, respectively. For example, the first client 400a can use only 800Wh out of the allocated 1kWh, and the second client 400b can use 1.2kWh, which is more than 1kWh. The same power may be allocated to each client (400a to 400N), but different powers may be allocated depending on the embodiment (for example, different powers are allocated based on the balance of each household, etc.).

In this case, the EMS 200 may control the ESS 100 to provide the second client 400b with 200 Wh of power corresponding to surplus power among the power allocated to the first client 400a. That is, the first client 400a can earn profit by selling surplus power to the second client 400b, and the second client 400b can sell the surplus power of the first client 400a to the power system 500. You can save on electricity bills by purchasing electricity cheaper than electricity.

7 to 10 are exemplary diagrams illustrating the operation of a power management system providing various power management data to a client.

The EMS 200 may provide power information for each of the clients 400a to 400N based on the results of power supply, purchase, and sale according to the various embodiments described above. For example, the power information includes information related to charging, discharging, and usage of the battery 130 (see FIG. 7), power consumption information for each client (see FIG. 8), power transaction information for each client (see FIG. 9), and/ Alternatively, it may include promotions, events, compensation-related information (see FIG. 10), etc.

The EMS 200 may provide the power information to the client through an application installed on the client's (user) terminal.

Referring to FIG. 7 , the EMS 200 may generate power information including charge amount information, charge/discharge schedule information, and/or usage information of the battery 130 of the ESS 100. The user's terminal may display a screen 700 including the power information and provide the power information to the user. The user can intuitively recognize the charge/discharge or power usage of the battery 130 of the ESS 100 based on the screen 700.

Referring to FIG. 8, the EMS 200 generates power information including the client's power consumption, expected electricity price, comparison with other clients, and/or a power saving message, and the user's terminal includes the power information. A screen 800 can be displayed. The user can conveniently check electricity bill predictions, power usage status, etc. through the displayed screen 800.

Referring to FIG. 9, when a power transaction between clients occurs as described above in FIG. 6, the EMS 200 generates power information including the sales revenue amount or electricity bill reduction amount according to the power transaction, and the user's terminal A screen 900 including the power information may be displayed. The user can check the profits from power trading through the displayed screen 900.

Referring to FIG. 10, the EMS 200 acquires information related to various promotions, events, and demand resource trading market (DR) from the power system 500 or the power company's server, and generates power information based on the obtained information. You can. By displaying the screen 1000 containing the power information, the user's terminal can induce the user to participate in the promotion or event, thereby enabling additional reduction in electricity bills.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention.

Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but rather to explain it, and the scope of the technical idea of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

Claims (15)

An energy storage device including a power conversion device, a battery that stores power, and a meter that measures the amount of power discharged from the battery; and
Comprising an energy management device that controls the power stored in the battery to be supplied to a plurality of clients,
The amount of power of the battery is distributed to each of the plurality of clients,
The energy management device,
Calculate the amount of power supplied by each of the plurality of clients from the power system based on the power consumption of each of the plurality of clients and the distributed power amount,
The energy management device,
Generate power information including at least one of the battery charge amount, charge/discharge schedule, and usage information,
Transmitting the generated power information to a terminal corresponding to each of at least one client among the plurality of clients,
Allocating the same amount of power to each of the plurality of clients and transmitting the allocated power amount information to the terminal,
When the power consumption of a first client among the plurality of clients is less than the amount of power distributed to the first client,
Controlling the energy storage device to supply surplus power among the amount of power distributed to the first client to a second client among the plurality of clients,
Controlling the power stored in the battery to be supplied to each of the plurality of clients at a time when the power purchase fee from the power system is the highest,
Transmitting power consumption information, power transaction information, and power-related promotions, events, or compensation-related information of the plurality of clients to the terminal,
The energy storage device,
Converting power supplied from a renewable energy power generation device through the power conversion device, and storing the converted power in the battery,
The energy management device,
When the power consumption of the plurality of clients is less than the amount of power supplied from the renewable energy power generation device and the battery is fully charged, selling a portion of the power supplied from the renewable energy power generation device to the power system, Power management system.
According to paragraph 1,
The energy management device,
Obtaining information about the power consumption of each of the plurality of clients from a meter included in each of the plurality of clients.
Power management system. According to paragraph 1,
The energy management device,
Calculating an electricity bill for each of the plurality of clients based on a calculation result of the amount of power each of the plurality of clients receives from the power system.
Power management system. delete According to paragraph 1,
The energy management device,
Calculate the profit of the first client based on the supply amount of surplus power of the first client,
Calculating the amount of power supplied by the second client from the power system based on the power consumption of the second client, the distributed power amount, and the supply amount of the surplus power,
Calculating the electricity bill of the second client based on the amount of surplus power supplied and the amount of power supplied from the power system
Power management system.
delete delete delete According to paragraph 1,
The energy management device,
Controlled to receive power from the power system and store it in the battery at a time when the power purchase fee from the power system is lowest.
Power management system. delete In a method of operating a power management system including an energy storage device including a battery storing power allocated to a plurality of clients, and an energy management device controlling power supply,
Obtaining power consumption of each of the plurality of clients;
calculating the amount of power supplied to each of the plurality of clients from the power system based on the amount of power allocated to each of the plurality of clients; and
Based on the calculation result, generating power information for each of the plurality of clients,
The energy management device,
Generate power information including at least one of the battery charge amount, charge/discharge schedule, and usage information,
Transmitting the generated power information to a terminal corresponding to each of at least one client among the plurality of clients,
Allocating the same amount of power to each of the plurality of clients and transmitting the allocated power amount information to the terminal,
When the power consumption of a first client among the plurality of clients is less than the amount of power distributed to the first client,
Controlling the energy storage device to supply surplus power among the amount of power distributed to the first client to a second client among the plurality of clients,
Controlling the power stored in the battery to be supplied to each of the plurality of clients at a time when the power purchase fee from the power system is the highest,
Transmitting power consumption information, power transaction information, and power-related promotions, events, or compensation-related information of the plurality of clients to the terminal,
The energy storage device,
Converting power supplied from a renewable energy power generation device through a power conversion device, and storing the converted power in the battery,
The energy management device,
When the power consumption of the plurality of clients is less than the amount of power supplied from the renewable energy power generation device and the battery is fully charged, selling a portion of the power supplied from the renewable energy power generation device to the power system, How a power management system works. According to clause 11,
The step of generating the power information is,
A method of operating a power management system that includes generating the power information including electricity charges for each of the plurality of clients. delete According to clause 11,
The calculating step is,
A method of operating a power management system comprising calculating the amount of power supplied by the second client from the power system based on the power consumption of the second client, the allocated power amount, and the supply amount of the surplus power. delete