KR102540658B1 - PMS with Increased Versatility and Its Control Method - Google Patents

Abstract

The present invention relates to a PMS with increased versatility and a control method thereof, and more particularly, to a user directly manipulates (inputs) specification information such as the number of modules constituting an energy storage device through a GUI, and to an energy storage device. It relates to a PMS and its control method that can increase versatility by not having to redevelop the PMS every time the specification information of a is changed.
The PMS with increased versatility according to an embodiment of the present invention is composed of a plurality of modules, connected to the PMS equipment through CAN communication, and transmits its own specification value to the PMS equipment at the request of the PMS equipment. more than one energy storage device; and
It is connected to the energy storage device through CAN communication, and when the specification information of the energy storage device, such as the number of modules, is changed, a power situation is simulated, and a specification value is requested from the energy storage device, and the energy storage device responds with the specification value. When received, PMS equipment that compares the received specification value with the specification value stored in the DB through program execution and monitors the energy storage equipment if they match each other;
It is composed of.

Description

PMS with increased versatility and its control method {PMS with Increased Versatility and Its Control Method}

The present invention relates to a PMS with increased versatility and a control method thereof, and more particularly, to a user directly manipulates (inputs) specification information such as the number of modules constituting an energy storage device through a GUI, and to an energy storage device. It relates to a PMS and its control method that can increase versatility by not having to redevelop the PMS every time the specification information of a is changed.

ESS (Energy Storage System), one of the energy storage equipment, is a storage device that temporarily stores excess power from a power plant and transmits power when power is in short supply. Therefore, there is an increasing demand for the performance and use of ESSs that can efficiently use power.

The ESS not only has the advantage of being able to divide and store power produced through general thermal or nuclear power generation according to the time of use, but also stores power produced through renewable energy generation such as solar power generation or wind power generation in advance. It has the advantage of being able to be used during times when power is intensively needed, so it is possible not only to suppress the use of power peaks according to each season, but also to easily respond to power quality improvement and power supply crisis response.

Such an ESS is a method of directly storing electricity using a battery, a method of generating electricity by turning a turbine with compressed and stored air, a method of storing electricity in the form of rotational force in a flywheel, and a method of storing electricity in the form of rotational force in a flywheel, and in the form of magnetism in a superconducting magnet with no electrical resistance. It is used as a way to store electricity.

Such an ESS is controlled by a power management system (PMS) that manages a power system and energy supplied to the power system.

The power management system (PMS) collects the generated power of the power generation device from the power meter and determines the power command value based on the collected data.

In addition, the power management system compares the power reference value with the generated power of the power generation device measured in real time to determine whether to charge or discharge.

Here, the power reference value is for power system stabilization and represents power to be output to the power system.

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In this way, in controlling ESS with PMS, conventionally, the number and details of each module such as cells, temperature measurement sensors, BMU (Battery Management Unit), CMU (Cell Management Unit) constituting ESS are different for each product. Therefore, there is a problem in that the PMS needs to be redeveloped according to the specification of the ESS, which is changed whenever the number and details of each module are changed, and time and cost are incurred accordingly.

Registration No. 10-1798554 (Announcement date March 25, 2022)

The present invention has been made to solve the above problems, and allows specification information such as the number of modules constituting energy storage equipment to be manipulated (input) through a GUI, so that when the specification information of energy storage equipment is changed Versatility that allows the user to directly manipulate (input) the specification information of the energy storage equipment to control the PMS of the energy storage equipment, and to increase versatility by not having to redevelop the PMS whenever the specification information of the energy storage equipment is changed. Its purpose is to provide a PMS and its control method with increased

In addition, another object of the present invention is to manipulate (input) the protection level and function as well as the number of modules constituting the energy storage device, and information constituting one energy storage device can be stored in one file. It is an object of the present invention to provide a PMS and a control method thereof, which can be stored through the system and have improved versatility for easy management.

The PMS with increased versatility according to an embodiment of the present invention for achieving the above object is composed of a plurality of modules and is connected to the PMS equipment through CAN communication, so that its current specification value is requested by the PMS equipment. one or more energy storage devices that transmit the PMS device; and

It is connected to the energy storage device through CAN communication, and when the specification information of the energy storage device, such as the number of modules, is changed, a power situation is simulated, and a specification value is requested from the energy storage device, and the energy storage device responds with the specification value. When received, PMS equipment that compares the received specification value with the specification value stored in the DB through program execution and monitors the energy storage equipment if they match each other;

It is composed of.

In addition, the PMS equipment provides a GUI screen to manipulate (input) specification information such as the number of modules, and manipulate (input) protection levels of voltage, current, and temperature values on the GUI screen. to be

In addition, on the GUI screen,

A clear button that clears the values set on the screen;

An update button that functions to change the spec value retrieved from the current DB to the spec value set on the screen,

Delete button that functions to delete the file selected in the current DB,

A create button that functions to newly save the values set on the screen to the DB;

An import button that loads the current spec values into the energy storage device and displays them on the screen;

Among the Export buttons that export the values set on the screen to the energy storage device,

It is characterized in that one or more buttons are provided.

Further, it is characterized in that the information of the energy storage device can be manipulated only through an authorized account by granting permission to an ID of a user account using the PMS device.

A PMS control method with increased versatility according to an embodiment of the present invention includes: (A) first executing a program of a PMS device and loading a specification that was opened at the end of the last program;

(B) checking a communication state by exchanging data with one or more energy storage devices through CAN communication in the PMS device;

(C) requesting a specification value from the connected energy storage device when the CAN communication is connected;

(D) receiving a response of a specification value from an energy storage device in the PMS device;

(E) comparing the received specification value with the specification value stored in the DB through program execution; and

(F) monitoring the energy storage device when both specification values coincide;

It is composed of.

In addition, after executing the program in step (A), performing a login by inputting an ID and password;

clicking any one of the create, delete, and change buttons displayed on the screen after performing the log-in;

checking whether the ID has an authority function; and

If the ID has an authority function, performing the corresponding authority function and creating, deleting, or changing a specification value stored in the DB;

It is characterized by further performing.

And the PMS equipment is characterized in that when the specification value of the energy storage equipment is changed, the power situation is simulated, and the changed specification value and simulation result value are stored.

According to the means for solving the above-described problem, the specification information such as the number of modules constituting the ESS, that is, the energy storage equipment, can be manipulated (input) through the GUI, so that when the specification information of the energy storage equipment is changed, the corresponding energy storage The user can directly manipulate (input) the equipment specification information to control the PMS of the energy storage equipment, and it is not necessary to redevelop the PMS whenever the specification information of the energy storage equipment is changed, thereby increasing versatility.

In addition, it is possible to manipulate (input) the protection level and functions as well as the number of modules constituting the energy storage device, and the information constituting one energy storage device can be stored through a single file, making management easy. It's easy.

1 is a schematic configuration diagram of a PMS applied to the present invention.
2 is a flowchart illustrating a PMS control method according to an embodiment of the present invention.
3 is a flow chart of the energy storage device shown in FIG. 1;
4 is a flowchart of setting PMS equipment according to an embodiment of the present invention.
5 is a GUI screen of the PMS equipment shown in FIG.
6 is a login screen of the PMS equipment shown in FIG.

Hereinafter, the configuration and operation of embodiments of the present invention will be described with reference to the accompanying drawings.

It should be noted that the same reference numerals and symbols refer to the same components in the drawings as much as possible, even if they are displayed on different drawings.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted.

In addition, when a part "includes" a certain component, it means that it may further include other components without excluding other components unless otherwise stated.

1 is a schematic configuration diagram of a PMS applied to the present invention.

As shown in FIG. 1, it is configured to include a PMS device 100 and a plurality of energy storage devices 200a, 200b, ..., 200n.

The plurality of energy storage devices 200a, 200b, ..., 200n may be, for example, SOFC (Solid Oxide Fuel Cell), BMS, CAP (Capacitor), ESS, and the like.

The energy storage devices 200a, 200b, ..., 200n are connected to the PMS device 100 through CAN communication and wait for the requested data of the PMS device. ) value is transmitted to the PMS device.

The PMS device 100 is connected to a plurality of energy storage devices 200a, 200b, ..., 200n through CAN communication, collects information such as power from each energy storage device, and determines a power command value based on the collected information. .

In addition, whether to charge or discharge is determined by comparing the power reference value with the power value measured in real time.

In addition, it adopts the Distributed Generation (DG) method that manages energy supply and demand in small units by accommodating distributed energy storage equipment.

In addition, security can be enhanced by granting authority settings to the ID of each account so that information can be manipulated only through authorized accounts.

At this time, a level is given to each authority, and functions can be performed differently for each level, and a specification value can be created, modified, or deleted.

In addition, it exchanges data with each energy storage device (200a, 200b,…, 200n) through CAN communication, requests a specification value from each energy storage device, and executes a program with the received specification value when a response is received from each equipment. Compares the spec values previously stored in the DB and starts monitoring if they match.

At this time, while monitoring each energy storage device (200a, 200b, ..., 200n), received data is stored in a DB in real time.

At this time, information constituting one energy storage device may be stored and managed in one file.

In addition, specifications such as the number of modules, such as cells, temperature sensors, BMU (Battery Management Unit), CMU (Cell Management Unit), etc. that make up each energy storage equipment, and the number of modules when details are changed. The GUI screen of FIG. 5A is provided so that information can be manipulated (input).

In addition, specification information can be manipulated (input) by setting protection levels such as voltage, current, and temperature values on the GUI screen.

In this way, when the specification information is changed by the user's manipulation of the GUI screen, it is possible to control the PMS of the energy storage device by simulating a power situation.

The user-manipulated specification information and simulation results can be stored in the DB, and this stored file can be maintained and managed through import and export.

The PMS device 100 includes an input/output unit, a control unit (microcomputer), a simulator, a communication unit, a DB, and the like to perform the above functions.

2 is a flowchart illustrating a PMS control method according to an embodiment of the present invention.

As shown in FIG. 2, when the PMS equipment 100 is started and the program is executed for the first time, the first specification standard is loaded with the specification standard opened at the end of the last program (S202).

Thereafter, the PMS device 100 starts checking specification synchronization with each energy storage device 200a, 200b, ..., 200n (S204), exchanges data with each energy storage device through CAN communication, and checks the communication state ( S206).

When CAN communication is connected by the communication state check, a specification value is requested from each connected energy storage device (S208).

The PMS device receives a response from the energy storage device (S210), and if there is no response for a certain amount of time (for example, 1 second), it retries a certain number of times (for example, 3 times) (S220) to obtain the specified value. to receive a response.

When a response of the spec value is received from the energy storage device, the response spec value is compared with the spec value of the program (S212), and if they match, the energy storage device is monitored (S214) and the energy storage device is controlled.

In addition, when a specification value is changed by a user's manipulation of a GUI screen while monitoring the energy storage device, the energy storage device may be controlled by simulating a power situation.

If the CAN communication is not connected in step S206 or the specification values do not match in step S212, the process returns to step S204 to start checking specification synchronization with each energy storage device.

3 is a flow chart of the energy storage device shown in FIG. 1;

As shown in FIG. 3, the energy storage devices 200a, 200b, ..., 200n connect CAN communication with the PMS device 100 (S302) and wait for the requested data of the PMS device (S304).

Thereafter, the energy storage device transmits a specification value of the current PMS device to the PMS device when receiving a request from the PMS device (S306).

4 is a flowchart of setting PMS equipment according to an embodiment of the present invention.

As shown in FIG. 4, after executing the program of the PMS device 100, login is performed by inputting an ID and password to use the PMS device.

After performing the log-in, any one of the Create, Delete, and Change buttons displayed on the screen is clicked (S402).

When the button is clicked, the PMS device checks whether or not the ID performing the login has an authority function (S404).

If the corresponding ID has an authority function, the function is performed and the specification value stored in the DB is created, deleted, or changed (S406).

If there is a level of authority, the corresponding function for each level can be performed differently.

FIG. 5 is a GUI screen of the PMS device shown in FIG. 1, and is a GUI screen capable of manipulating information of the energy storage device.

As shown in FIG. 5, the number of modules (cells, temperature measuring sensors, BMUs, and CMUs) constituting the energy storage equipment and protection levels such as voltage, current, and temperature values can be set, stored, and managed. can

In addition, a plurality of buttons are provided on the GUI screen, but from the upper left to the right,

A clear button that clears the values set on the screen;

An update button that functions to change the spec value retrieved from the current DB to the spec value set on the screen,

Delete button that functions to delete the file selected in the current DB,

A create button that functions to newly save the values set on the screen to the DB;

An import button that loads the current spec values into the energy storage device and displays them on the screen;

It is provided with an Export button that functions to send the value set on the screen to the energy storage device.

6 is a login screen of the PMS equipment shown in FIG.

6 shows a login screen for inputting an ID and password and a screen for checking communication data packets for each energy storage device in real time.

At this time, the authority function is given to the ID that performed the login, but the function can be performed differently according to the level by assigning a level to each authority.

Although the technical idea of the present invention has been described above with the accompanying drawings, this is illustratively described a preferred embodiment of the present invention, but does not limit the present invention.

In addition, it is obvious that anyone skilled in the art can make various modifications and imitations without departing from the scope of the technical spirit of the present invention.

100: PMS equipment 200a, 200b, ... ,200n: energy storage equipment

Claims (7)

One or more energy storage devices composed of a plurality of modules and connected to the PMS device through CAN communication to transmit their current spec value to the PMS device at the request of the PMS device; and
It is connected to the energy storage device through CAN communication, and when the specification information of the energy storage device, such as the number of modules, is changed, a power situation is simulated, and a specification value is requested from the energy storage device, and the energy storage device responds with the specification value. When received, PMS equipment that compares the received specification value with the specification value stored in the DB through program execution and monitors the energy storage equipment if they match each other; including,
Permissions are assigned to the ID of the user account using the PMS device so that information on the energy storage device can be manipulated only through an account with permission, but each permission is also assigned a grade and functions are performed differently for each grade to specify specifications Allows you to create, modify, and delete values;
The PMS with increased versatility, characterized in that the PMS device stores information constituting one energy storage device in one file when storing the spec value received in response from the energy storage device. According to claim 1,
The PMS equipment provides a GUI screen to manipulate (input) specification information such as the number of modules, and manipulate (input) protection levels of voltage, current, and temperature values on the GUI screen. Characterized in that PMS with increased versatility. According to claim 2,
On the GUI screen,
A clear button that clears the values set on the screen;
An update button that functions to change the spec value retrieved from the current DB to the spec value set on the screen,
Delete button that functions to delete the file selected in the current DB,
A create button that functions to newly save the values set on the screen to the DB;
An import button that loads the current spec values into the energy storage device and displays them on the screen;
Among the Export buttons that export the values set on the screen to the energy storage device,
PMS with increased versatility, characterized in that any one or more buttons are provided. delete (A) first executing the program of the PMS device and loading the specifications that were opened when the last program was terminated;
(B) checking a communication state by exchanging data with one or more energy storage devices through CAN communication in the PMS device;
(C) requesting a specification value from the connected energy storage device when the CAN communication is connected;
(D) receiving a response of a spec value from an energy storage device in the PMS device, and storing information constituting one energy storage device in a file when the response spec value is stored;
(E) comparing the received specification value with the specification value stored in the DB through program execution; and
(F) monitoring the energy storage device when both specification values coincide; including,
After executing the program in step (A), logging in by inputting an ID and password;
clicking any one of the create, delete, and change buttons displayed on the screen after performing the log-in;
checking whether the ID has an authority function;
If the ID has a permission function, the corresponding permission function is performed and the spec value stored in the DB is created, deleted, or changed. However, each permission level is also assigned to perform functions differently for each level to create, modify, or delete the spec value. enabling; do more,
The PMS control method with improved versatility, characterized in that the PMS equipment simulates the power situation when the specification value of the energy storage equipment is changed and stores the changed specification value and simulation result value. delete delete

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