KR101456090B1 - Educational test of the power storage system method and apparatus - Google Patents

Abstract

The present invention relates to an education test method of a power storage system and an apparatus thereof. More particularly, the present invention relates to an education test method of a power storage system for simulating an electrical energy storage (EES) system using an energy storage device associated with a power system, and an apparatus thereof. An embodiment of the present invention may improve the whole understanding of the user with respect to the ESS and improve a battery stack design performance of the ESS by simulating charge/discharge operation of a battery according to preset charge/discharge based on battery stack design data of various sizes designed by a user, and providing the simulation result to the user through feed-back.

Description

TECHNICAL FIELD [0001] The present invention relates to a test method for a power storage system,

[0001] The present invention relates to a test method and apparatus for teaching an electric power storage system, and more particularly, to an electric power storage system (EES) using a battery stack device of a predetermined standard, And more particularly, to an apparatus and method for testing a power storage system.

Recently, as energy demand has been increasing every year due to the increase in income and quality of life, demand for upgrading of various services, and expansion of supply of cooler and heater according to abnormal climate, it is an effective means to manage electricity supply and demand, (EES) is becoming more and more important.

The above-mentioned power storage system is a device that can store electricity generated by using surplus produced electricity or renewable energy so that it can be used at the required time, and it is installed separately in the homes, commercial and industrial facilities, It is utilized as a power backup device or as a device for covering unstable power of solar power and wind power generation system.

Meanwhile, the above power storage system is designed and installed in various sizes in consideration of the installation purpose, charge / discharge scale, charge / discharge pattern, economical efficiency, and the like, There is a growing need for design education devices, but the development and research on these are still insignificant.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the related art as described above, and it is an object of the present invention to provide a battery stack of various specifications established by a user (a trainee) battery stack design data for simulating the operation of a power storage system based on design data.

According to an embodiment of the present invention, there is provided an apparatus for testing a power storage system using a battery stack having a predetermined size, the system comprising: a battery stack design data of a power storage system designed by a user; A control unit for calculating a power command value according to a predetermined charge / discharge pattern, a cooperative inverter for controlling the charge / discharge operation of the battery stack based on the power command value, a sensing unit for detecting operation state information of the battery stack and the co- And a screen display unit for displaying simulation operation results of the power storage system based on the operation state information.

In this case, the battery stack design data may include a capacity of a battery stack, a capacity of a battery cell constituting a battery stack, a voltage of a battery cell, and a number of serial / parallel connections in a connection manner between battery cells.

The control unit may calculate the power command value through the following equation.

Here, P _ref is the power command value, P _pattern has a nominal (nominal) voltage, V _d-norm of the charge / discharge power, V _r-norm is the battery stack design target electric power storage system according to the charging and discharging pattern by the user, The nominal voltage of the designed battery stack, N _rs N _ds is the number of series connections of the battery cells constituting the battery stack designed by the user, C _{r is the} number of series connections of the battery cells constituting the battery stack, The capacity of the battery stack, the C _d N _rp is the number of parallel connections of the battery cells constituting the battery stack, and N _dp is the number of parallel connections of the battery cells constituting the battery stack designed by the user.

In accordance with another aspect of the present invention, there is provided a method of testing a power storage system using a battery stack of a predetermined standard, the method comprising the steps of: (a) receiving battery stack design data of a power storage system from a user; (b) calculating a power command value according to a predetermined charge / discharge pattern based on the battery stack design data and the specification of the battery stack, (c) performing a charge / discharge operation of the battery stack according to the power command value (d) detecting operation state information of the battery stack, and (e) displaying a simulation operation result of the power storage system based on the operation state information.

The step (a) includes the steps of: (a-1) receiving information on the components of the battery stack including the capacity of the battery stack, the capacity of the cells constituting the battery stack, and the voltage information of the battery cells from the user; (a-2) receiving information on a connection relationship between battery stack configurations including information on the number of serial / parallel connections of the battery cell from the user.

The step (a) includes the steps of (a-3) determining whether a design suitable for carrying out the charge / discharge pattern has been made based on information on constituent elements of the battery stack and information on a connection relation between the battery stack configurations If it is determined that the information is not appropriate as a result of the check, the information can be repeatedly input from the user.

According to the embodiment of the present invention, the operation of the power storage system is simulated through the battery stack device of a predetermined standard based on the battery stack design data of various specifications designed by the user, and the result of the simulation is fed- By presenting it to the user, it is possible to enhance the user's overall understanding of the power storage system as well as to develop the battery stack design capability of the power storage system.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
1 is a diagram schematically showing a configuration of a testing device for an education of an electric power storage system according to an embodiment of the present invention.
2 is a diagram illustrating a charge / discharge pattern of a power storage system according to an embodiment of the present invention.
3 is a flowchart illustrating a method for testing a power storage system according to an embodiment of the present invention.
4 is a flowchart illustrating a battery stack design learning method of a power storage system according to an embodiment of the present invention.
5 is a flowchart illustrating a method of simulating a power storage system according to an embodiment of the present invention.

The present invention relates to an educational test method and apparatus for an electrical energy storage (EES), and more particularly, to a test method and apparatus for an electric power storage system (EES) The present invention relates to a test method and apparatus for a power storage system for simulating charging and discharging operations of an actual power storage system through a battery stack device of a standard.

1 is a diagram schematically showing a configuration of a testing device for an education of an electric power storage system according to an embodiment of the present invention.

1, a testing apparatus 100 for a training of an electric power storage system according to an exemplary embodiment of the present invention includes a battery stack 110, a linkage inverter 120, a control unit 130, a sensing unit 140, And a screen display unit 150.

The battery stack 110 is an apparatus for simulating an energy storage device of an electric power storage system. The battery stack 110 is configured to charge and discharge an actual electric power storage system according to a predetermined charge / discharge pattern based on battery stack design data of various sizes designed by a user In order to simulate the operation, a rechargeable battery cell having a predetermined capacity may be connected in series or in parallel.

Specifically, the battery stack 110 can simulate the charging / discharging operation of the actual power storage system by controlling the charging / discharging operation by the operation of the inverter 120. The battery stack 110 is connected to an actual power system network 20 to receive power from the upper power grid 20 under the control of the inverter 120 or to transmit power stored in the upper power grid 20.

The coupled inverter 120 is a device that performs frequency conversion for power exchange between the battery stack 110 and the power grid 20 by being interlocked with one end of the battery stack 110, The charge / discharge operation of the battery stack 110 may be controlled based on a power command value received from the control unit 130. Here, the charge / discharge operation control may include control of charge / discharge of the battery stack 110 as well as control of charge / discharge amount.

The control unit 130 performs charging and discharging operations of the actual power storage system through the battery stack 110 according to predetermined charging and discharging pattern information based on battery stack design data of various sizes designed by the user It is possible to calculate a power command value for simulation and transmit it to the linkage inverter 120.

The battery stack design data collectively refers to information related to an energy storage device of a power storage system that is input by a user. The battery stack design data includes information on the components of the energy storage device, such as the capacity of the battery stack, Capacity, the voltage of the battery cell, and the like, and may include information on the connection relationship between components of the energy storage device, and may include information on the number of parallel / parallel connections between the battery cells.

At this time, the battery stack design data is input by the user through the training program of the power storage system related to the embodiment of the present invention installed in the educational computer 10 interlocked with the educational test apparatus 100 of the power storage system, (130).

The capacity of the battery stack, the capacity of the battery cell constituting the battery stack, the voltage of the battery cell, and the number of serial / parallel connections by the connection method between the battery cells can be appropriately designed based on predetermined charge / discharge pattern information.

The charging / discharging pattern information can be set by appropriately changing the charging / discharging pattern information as virtual data related to the charging / discharging operation and the charging / discharging amount according to the time according to the operation plan of the design target power storage system. The information can be expressed as a function of the charge / discharge power amount with respect to time, and can be appropriately represented by a continuous function, a discrete function or a waveform function. The charge / discharge pattern information may be provided in advance in designing the user's battery stack.

2 is a diagram illustrating a charge / discharge pattern of a power storage system according to an embodiment of the present invention.

The graph shown in FIG. 2 shows an example of charging / discharging pattern information on the charging / discharging state and the charging / discharging amount by time zone, where the horizontal axis indicates time and the vertical axis indicates the amount of power (kW).

Specifically, as shown in FIG. 2, the charge / discharge pattern information is a day-to-day charge / discharge plan, and the discharge of the set amount of electric power for each time zone in the period from 00:00 to 05:00 and 06:00 to 10:00 is performed at 11 to 13:00, And 23:00 to 24:00, and may be set not to perform the charge / discharge operation in the other time zones.

The control unit 130 may calculate a power command value for simulating charging and discharging operations of the actual power storage system according to predetermined battery charge / discharge pattern information based on the battery stack design data and the specification of the battery stack 110.

Specifically, the power command value may include battery stack data 110 designed by the user to implement the charging / discharging operation of the actual power storage system through a battery stack 110 device of a predetermined size based on battery stack data of various sizes designed by the user. For example, according to the predetermined charge / discharge pattern information according to the specification of the battery stack 110. For example, the power command value can be calculated by the following equation.

Here, P _ref is the power command value, P _pattern has a nominal (nominal) voltage, V _d-norm of the charge / discharge power, V _r-norm is the battery stack design target electric power storage system according to the charging and discharging pattern by the user, The nominal voltage of the designed battery stack, N _rs N _ds is the number of series connections of the battery cells constituting the battery stack designed by the user, C _{r is the} number of series connections of the battery cells constituting the battery stack, The capacity of the battery stack, the C _d N _rp represents the number of parallel connections of the battery cells constituting the battery stack, and N _dp represents the number of parallel connections of the battery cells constituting the battery stack designed by the user.

Meanwhile, in order to achieve an efficient test / education purpose, the apparatus for testing education 100 of the power storage system according to the embodiment of the present invention calculates a power command value according to the charge / discharge pattern, The power command value can be calculated. For example, one hour in the charge / discharge pattern can be reduced to one minute or the like and simulated.

The controller 130 may transmit the calculated power command value to the coupled inverter 120 through an analog output channel and the coupled inverter 120 may receive the power command value received from the controller 130, The charge / discharge operation of the battery stack 110 can be controlled by operating according to the set value.

Meanwhile, the educational test apparatus 100 of the power storage system according to the embodiment of the present invention simulates a power storage system through the battery stack 110 by feedback based on the battery stack design data established by the user And a screen display unit 150 for presenting / displaying the operation result to the user.

Specifically, the screen display unit 150 displays, as a simulation operation result of the power storage system received from the control unit 130, the power generation amount of the power storage system, the charging amount, the charging state of the energy storage device, the input / output voltage, The display unit 150 may display the information on the current electricity bill or the like by using a display window such as a liquid crystal display (LCD) or a light emitting diode (LED) Can be implemented. Of course, the simulation operation result of the power storage system can also be output through the monitor of the educational computer 10. [

The training test apparatus 100 of the power storage system according to the embodiment of the present invention collects the operation status information of the battery stack 110 and the link inverter 120 to calculate simulation operation result information of the power storage system, And a sensing unit 140 provided to the control unit 130.

More specifically, the sensing unit 140 detects a real time voltage and current according to the operation of the battery stack 110 and the coupled inverter 120, and provides the detected voltage and current to the control unit 130, A charging amount, an input / output voltage, an input / output current, and the like of the power storage system based on the real-time voltage and current of the battery stack 110 and the coupled inverter 120 collected through the sensing unit 140 Can be calculated.

The sensing unit 140 may include a voltmeter and an ammeter installed between the battery stack 110 and the inverter 120 and between the inverter 120 and the power grid 20 have.

Hereinafter, an instructional testing method of the power storage system using the testing apparatus 100 for the education of the power storage system according to another embodiment of the present invention will be described.

3 is a flowchart illustrating a method for testing a power storage system according to an embodiment of the present invention.

The method for testing the power storage system according to the embodiment of the present invention can be performed by the user through the educational computer 10, and the battery stack design learning mode and the practice training mode of the power storage system can be performed. And a concept learning mode related to the power storage system may be performed as a pre-training for smooth progress of the training (S301).

The battery stack design learning of the power storage system and the concept learning process related to the power storage system are performed by the implementation of the present invention installed in the educational computer 10 interlocked with the educational test apparatus 100 of the power storage system according to the embodiment of the present invention. The training program may be executed by the user through the design learning process so that the battery stack design data of the power storage system can be transmitted to the educational test apparatus 100 of the power storage system And then simulating the power storage system through the battery stack 110 of a predetermined standard.

If the concept learning mode related to the power storage system is selected by the user in step S301, concept learning related to the power storage system can be started through the training program of the power storage system (S311). The concept of the power storage system, , A battery stack, a power conversion device, an operation information collecting / monitoring device of a power storage system, and a battery management system, in a suitable manner according to a user's selection, And can be displayed / explained using a speaker or the like (S313).

If the battery stack design learning mode of the power storage system is selected by the user in step S301, the battery stack design learning can be started through the training program of the power storage system (S321) The design learning can be performed through the input of battery stack design data including the battery stack capacity, the capacity of the battery cell constituting the battery stack, the voltage of the battery cell, and the number of serial / parallel connections by the connection method of the battery cell S323).

At this time, the step S323 may provide a user with a battery stack design learning process of a systematic / professional power storage system, and may allow a user to improve understanding of a specific battery stack design process according to various power consumption patterns, The battery stack design data may be input to the battery stack, and the battery stack design data may be input to the battery stack.

Hereinafter, a battery stack design learning process of the power storage system including the compatibility determination process will be described with reference to a new drawing.

4 is a flowchart illustrating a battery stack design learning method of a power storage system according to an embodiment of the present invention.

As shown in FIG. 4, when the battery stack design learning mode of the power storage system is started according to the user's selection, the charge / discharge pattern information of the battery stack preset in the operation plan of the design target power storage system is provided to the user first S401).

Information on components of the battery stack including the battery stack capacity of the design target power storage system based on the charge / discharge pattern information, the capacity of individual battery cells constituting the battery stack, and the voltage information of the battery cells from the user 403), and then receives information about the connection relationship between the battery stack configurations including the serial / parallel connection number information of the battery cell from the user (S405).

(S407) whether or not a design suitable for performing a predetermined charge / discharge pattern has been performed based on information on the input battery stack component and information on a connection relation between the battery stack configurations.

If it is determined in step S407 that the battery pack is not suitable as a result of the determination, information on the battery stack component and information on the connection relationship between the battery stack configurations can be repeatedly performed. Alternatively, The input process of the battery stack design data can be completed.

In operation S325, battery stack design data including information on the components of the battery stack received from the user through the execution of step S323 and information on connection relationships between battery stack configurations may be stored.

If the training of the power storage system is started through the training program of the power storage system according to the selection of the training mode of the power storage system by the user at step S301 (S331), the power storage system of steps S321 to S325 The battery stack design data for simulating the power storage system through the educational test apparatus 100 of the power storage system according to the user's selection among the battery stack design data generated / stored through the battery stack design learning of the battery stack design data (S333).

The battery stack design data may be transmitted from the education computer 10 to the control unit 130 of the educational test apparatus 100 of the power storage system to simulate the power storage system based on the battery stack design data.

The control unit 130 simulates charging and discharging operations of the power storage system through the battery stack 110 and the coupled inverter 120 based on the received battery stack design data and displays the simulated results on the screen display unit 150 (S335).

A simulation method of the power storage system through the educational test apparatus 100 of the power storage system will be described with reference to a new drawing.

5 is a flowchart illustrating a method of simulating a power storage system according to an embodiment of the present invention.

The control unit 130 of the tester 100 of the power storage system calculates a power command value according to a predetermined charge / discharge pattern based on battery stack design data received from the educational computer 10 (S501). The calculation method of the power command value is as described above.

The controller 130 transmits the power command value to the inverter 120 in step S503 and the inverter 120 operates according to the power command value to determine whether the battery stack is charged or discharged and how much charge / (S505).

At this time, the sensing unit 140 detects the operation results of the battery stack 110 and the coupled inverter 120 in response to the battery stack design data established by the user (S507) The detected result through the sensing unit 140 may be converted into the operation result of the power storage system and displayed on the screen display unit 150 (S509).

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention.

Claims (6)

1. An apparatus for testing a power storage system using a battery stack of a predetermined standard,
A control unit for calculating a power command value according to a predetermined charge / discharge pattern based on battery stack design data of a power storage system designed by a user and a specification of the battery stack;
A linkage inverter for controlling charging and discharging operations of the battery stack based on the power command value;
A sensing unit for detecting operation state information of the battery stack and the coupled inverter; And
And a screen display unit for displaying simulation operation results of the power storage system based on the operation state information,
The battery stack design data may include a capacity of a battery stack, a capacity of a battery cell constituting the battery stack, a voltage of the battery cell, and a number of serial /
Wherein,
Wherein the power command value is calculated through the following equation.

Vr-norm is the nominal voltage of the battery stack, and Vd-norm is the charge / discharge power of the battery stack designed by the user. Nd-s is the number of series connections of the battery cells constituting the battery stack designed by the user, Cr is the capacity of the battery stack, Cd is the capacity of the battery stack, Nr-s is the number of series connections of the battery cells constituting the battery stack, Denotes the capacity of the battery stack designed by the user, Nr-p denotes the number of parallel connections of the battery cells constituting the battery stack, and Nd-p denotes the number of parallel connections of the battery cells constituting the battery stack designed by the user. delete delete A method for testing a power storage system using a battery stack of a predetermined standard,
(a) receiving battery stack design data of a power storage system from a user;
(b) calculating a power command value according to a predetermined charge / discharge pattern based on the battery stack design data and the specification of the battery stack;
(c) performing a charging / discharging operation of the battery stack according to the power command value;
(d) detecting operation state information of the battery stack; And
(e) displaying a simulated operation result of the power storage system based on the operation state information,
The step (a)
(a-1) receiving information on the components of the battery stack including the capacity of the battery stack, the capacity of the cells constituting the battery stack, and the voltage information of the battery cells from the user; And
(a-2) receiving information on a connection relationship between battery stack configurations including information on serial / parallel connection counts of battery cells from a user,
The step (b)
Wherein the power command value is calculated through the following equation.

Vr-norm is the nominal voltage of the battery stack, and Vd-norm is the charge / discharge power of the battery stack designed by the user. Nd-s is the number of series connections of the battery cells constituting the battery stack designed by the user, Cr is the capacity of the battery stack, Cd is the capacity of the battery stack, Nr-s is the number of series connections of the battery cells constituting the battery stack, Denotes the capacity of the battery stack designed by the user, Nr-p denotes the number of parallel connections of the battery cells constituting the battery stack, and Nd-p denotes the number of parallel connections of the battery cells constituting the battery stack designed by the user. delete delete

Images