KR20210097299A - Energy Storage System(ESS) with Li-Ion Capacitor for Short-Period Frequency Fluctuation Compensation - Google Patents

Abstract

The present invention relates to an energy storage system (ESS) having a lithium ion capacitor for compensating for short-period frequency variation. The energy storage system according to the present invention comprises: a lithium battery including lithium secondary batteries; and a lithium ion capacitor connected in parallel to the lithium battery to compensate for an instantaneous peak when short-period frequency variation occurs.

Description

Energy Storage System (ESS) with Li-Ion Capacitor for Short-Period Frequency Fluctuation Compensation

The present invention relates to an energy storage system (ESS), and more particularly, energy storage having a lithium ion capacitor for short-cycle frequency fluctuation compensation capable of extending the lifespan of a lithium battery including lithium secondary batteries It's about the system.

With the development of industry, the demand for electricity is increasing, and the gap in electricity consumption between day and night, season, and day is gradually deepening. For this reason, many technologies for reducing the peak load by utilizing the surplus power of the power system are being rapidly developed.

A representative of these technologies is an energy storage system (ESS) that stores surplus power of the system in a battery or supplies insufficient power of the power system from the battery.

As described above, the energy storage system is used to stably connect the power generated from renewable energy to the power system. Renewable energy is electrical energy generated through solar power or wind power, and has a disadvantage in that the stability of power production is lowered. To solve these shortcomings, renewable energy is used in combination with an energy storage system. An energy storage system uses a lithium battery including lithium secondary batteries as a battery, stores excess power, and then discharges it when power is insufficient to stabilize power supply and demand. That is, the energy storage system accumulates and stores the new and renewable energy that is insignificantly collected when the power demand is low in the lithium battery, and then improves the power utilization efficiency by allowing the stored power to be used during the peak time when the power demand is high. do.

Here, a lithium battery including a lithium secondary battery may stabilize power quality through output compensation of an instantaneous peak when a short-cycle frequency is changed.

However, since this instantaneous peak output compensation is made through frequent charging and discharging of the lithium battery, it acts as a factor to shorten the lifespan of the lithium secondary battery.

Registered Patent Publication No. 10-1587488 (2016.01.21. Announcement)

Accordingly, it is an object of the present invention to provide an energy storage system including a lithium ion capacitor for short-cycle frequency fluctuation compensation capable of extending the life of a lithium battery including lithium secondary batteries.

In order to achieve the above object, the present invention is a lithium battery including lithium secondary batteries; and a lithium ion capacitor connected in parallel to the lithium battery to compensate for an instantaneous peak when a short-cycle frequency change occurs.

When the lithium battery is 100 kW class, the lithium ion capacitor has capacities of 3.8V and 4000F.

The energy storage system according to the present invention further includes a power conversion device for converting power from direct current to alternating current or from alternating current to direct current for charging and discharging the lithium battery and the lithium ion capacitor.

The lithium battery may have a use current of 100A and a use voltage range of 800 to 1200V.

And the lithium battery is the overcharge voltage of the lithium secondary battery, the overdischarge voltage of the lithium secondary battery, the lower temperature limit, the upper temperature limit, the overcharge current of the lithium battery, the overdischarge current of the lithium battery, the overcharge voltage of the lithium battery and the overdischarge of the lithium battery It can have an alarm function for voltage.

According to the present invention, by using the lithium ion capacitor for short-cycle frequency fluctuation compensation in parallel with the lithium battery, it is possible to suppress the shortening of the lifespan of the lithium secondary battery due to an instantaneous peak when the short-cycle frequency fluctuation occurs.

1 is a view showing an energy storage system having a lithium ion capacitor for short-period frequency fluctuation compensation.

It should be noted that, in the following description, only parts necessary for understanding the embodiments of the present invention are described, and descriptions of other parts will be omitted without departing from the gist of the present invention.

The terms or words used in the present specification and claims described below should not be construed as being limited to their ordinary or dictionary meanings, and the inventors have appropriate concepts of terms in order to best describe their inventions. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined in Accordingly, the embodiments described in this specification and the configurations shown in the drawings are only preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, so various equivalents that can be substituted for them at the time of the present application It should be understood that there may be variations and variations.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a view showing an energy storage system having a lithium ion capacitor for short-period frequency fluctuation compensation.

Referring to FIG. 1 , the energy storage system 100 according to the present embodiment includes a lithium battery 10 and a lithium ion capacitor 20 , and may further include a power conversion device 30 . The lithium battery 10 includes lithium secondary batteries. In addition, the lithium ion capacitor 20 is connected in parallel to the lithium battery 10 to compensate for an instantaneous peak when a short-period frequency change occurs.

As described above, according to the present embodiment, by using the lithium ion capacitor 20 for short-cycle frequency fluctuation compensation in parallel with the lithium battery 10, the lifespan of the lithium secondary battery due to an instantaneous peak during the short-cycle frequency fluctuation is shortened. can be prevented from becoming

Here, the power converter 30 converts electric power from direct current to alternating current or from alternating current to direct current for charging and discharging the lithium battery 10 and the lithium ion capacitor 20 . That is, the lithium battery 10 must be converted to an appropriate amount of power in order to perform charging and discharging, which is performed by the power conversion device 30 . The power conversion device 30 includes a converter or an inverter. A converter is a device that changes the magnitude of a voltage. An inverter is a device that converts a DC voltage into an AC voltage or converts an AC voltage into a DC voltage.

The lithium battery 10 includes a plurality of lithium secondary batteries for supplying electric energy to the power system. Lithium secondary batteries (or cells) are manufactured as a battery module put in a frame with a certain number, for example, about 10, in order to protect against external shock, heat, or vibration. The lithium battery 10 is manufactured in the form of a battery pack by bundling a plurality of these battery modules.

And the lithium ion capacitor 20 is connected in parallel to the lithium battery 10 to perform charging and discharging. The lithium ion capacitor 20 may have capacities of 3.8V and 4000F when the lithium battery 10 is 100kW class. The lithium ion capacitor 20 may be implemented as a cylindrical axial type. The lithium ion capacitor 20 may be manufactured as a module of a plurality of unit lithium ion capacitors 20 .

The lithium battery 10 may have a use current of 100A and a use voltage range of 800 to 1200V.

The charging/discharging mode of the lithium battery 10 may be at the level of 100 kW by electrostatic power charging and discharging.

And the lithium battery 10 is the overcharge voltage of the lithium secondary battery, the overdischarge voltage of the lithium secondary battery, the lower temperature limit, the upper temperature limit, the overcharge current of the lithium battery 10, the overdischarge current of the lithium battery 10, the lithium battery ( 10) may have an alarm function for at least one of the overcharge voltage and the overdischarge voltage of the lithium battery 10 . Here, the alarm may be output in a plurality of steps. The alarm may be output by at least one of sound, light, and display. For example, an alarm may be output in two stages: a warning and a fault. In the case of outputting an alarm as a warning light, green may be output in a normal case, a yellow color may be output in case of a warning, and a red color may be output in a defective case.

In addition, the energy storage system 100 according to the present embodiment may further include a communication unit or a display unit.

The communication unit communicates with the manager terminal through a wired/wireless network. Such a communication unit may include a wired communication unit or a wireless communication unit. The wireless communication unit includes a short-range communication unit or a long-distance communication unit.

The display unit may display status information of the energy storage system 100 as well as various function menus executed in the energy storage system 100 . LCD, LED, AMOLED or touch screen may be used as such a display unit. The touch screen simultaneously functions as a display device and an input device.

The function menu displayed on the display is the main page (Main Page 1), the second main page (Main Page 2), the rack page (Rack Page), the tray page (Tray Page) and the cell monitor page may include

The first main page may include a ribbon bar, a status bar, a rack status, and tray information.

The ribbon bar includes home, rack, tray, cell monitor, alarm, and setting buttons, and when each button is clicked, it moves to each screen. If you click Settings, you must enter your password to enter the settings window.

The status bar displays system messages, Internet communication status with PMS, CAN communication status, and current time.

The rack status indicates the voltage, current, power, relay, rack fan, rack temperature, and charge/discharge status of the rack. Here, the relay includes a precharge relay, a charging relay, and a discharging relay. As states, it represents a standby state (IDLE), a charging state (Charge), and a discharging state (Discharge). The state transition criterion is changed to charging or discharging based on 2A.

And the tray information displays the voltage and temperature of the tray. The voltage and temperature of the tray include the cell (lithium secondary battery) maximum voltage and maximum temperature, and the cell minimum voltage and minimum temperature.

The voltage and temperature of the tray can be displayed in color. For example, a text color of a tray having a virtual high cell voltage among the trays may be displayed in red. A text color of a tray having the lowest cell voltage among the trays may be displayed in blue.

The second main page displays the alarm status. Alarm conditions can be displayed in two stages: warning and fault. In the case of outputting an alarm with a warning light, green is output in normal case, yellow is output in case of warning, and red is output in case of failure. For example, through the second main page, the overcharge voltage of the lithium secondary battery, the overdischarge voltage of the lithium secondary battery, the lower temperature limit, the upper temperature limit, the overcharge current of the lithium battery 10, the overdischarge current of the lithium battery 10, the lithium battery The overcharge voltage of 10 and the overdischarge voltage of the lithium battery 10 may be displayed.

The Rack page displays Tray Information, Rack Status, Tray Min/Max, and Cell Min/Max.

Through tray information, each of the trays voltage, balance, cell maximum voltage, minimum voltage, voltage deviation, maximum temperature, minimum temperature, temperature deviation, and fan operation status are displayed.

Rack status displays the voltage, current, current, relay status, and temperature of the rack.

Through the tray min/max, the maximum and minimum values of the voltage and temperature of the power tray are displayed, and the tray number having the maximum and minimum values is displayed.

And, through the cell min/max, the maximum, minimum, average, and deviation of voltage and temperature of all cells are displayed, and the tray number and cell number having the maximum and minimum values are displayed.

The tray page displays Tray Information.

That is, through the tray page, the voltage and temperature of each cell of the trays are displayed, and the maximum and minimum values are output from each tray. Through the tray page, detailed data of up to 5 trays are output, and when you want to view other tray information, you can click the desired tray area at the top to check it.

Through the tray page, the background color of cells being balanced is displayed in yellow, the maximum voltage of the cells in the tray is displayed in red text, and the minimum voltage of cells in the tray is displayed in blue text.

And the cell monitor page displays the voltage, temperature, and fan operation status of each cell in the entire tray. Through the cell monitor page, the maximum cell voltage is displayed in red text color, and the minimum cell voltage is displayed in blue color. Through the cell monitor page, the maximum cell temperature is displayed in red text color, and the minimum cell temperature is displayed in blue text color.

The other function menu may further include an alarm page and a setting page.

The alarm page displays the alarm log. Through the alarm log, previously generated alarm information can be checked. Through the alarm log, if you select a period and click Search, you can output records within the period. Alarm information displayed through the alarm log includes alarm occurrence time, alarm type, alarm code, and alarm contents.

And the setting page displays Communication, Serial (CAN/RS232), Modbus TCP, Password, Timer and SOC R Value.

Through communication, ON/OFF of CAN, Modbus TCP communication is set through a switch, and the ON/OFF state is changed when the corresponding switch is clicked.

Through serial, you can modify settings such as communication speed and port of serial communication.

Through Modbus TCP, it is possible to modify the setting value of Modbus Internet communication communicating with PMS.

Via password, you can change it by clicking on the password to access the settings.

Through the timer, the recording period of rack data and tray data can be changed.

Through the SOC R Value, it is possible to set the R value that affects the SOC calculation.

On the other hand, the embodiments disclosed in the present specification and drawings are merely presented as specific examples to aid understanding, and are not intended to limit the scope of the present invention. It is apparent to those of ordinary skill in the art to which the present invention pertains that other modifications based on the technical spirit of the present invention can be implemented in addition to the embodiments disclosed herein.

10: lithium battery
20: lithium ion capacitor
30: power conversion device
100: energy storage system

Claims (5)

lithium batteries including lithium secondary batteries; and
a lithium ion capacitor connected in parallel to the lithium battery to compensate for an instantaneous peak when a short-cycle frequency change;
An energy storage system comprising a. According to claim 1,
When the lithium battery is 100 kW class, the lithium ion capacitor is an energy storage system, characterized in that it has a capacity of 3.8V, 4000F. According to claim 1,
a power converter for converting electric power from direct current to alternating current or from alternating current to direct current for charging and discharging the lithium battery and the lithium ion capacitor;
Energy storage system, characterized in that it further comprises. According to claim 1,
The lithium battery is an energy storage system, characterized in that the use current is 100A, the use voltage range is 800 to 1200V. According to claim 1,
The lithium battery includes an overcharge voltage of a lithium secondary battery, an overdischarge voltage of a lithium secondary battery, a lower temperature limit, an upper temperature limit, an overcharge current of a lithium battery, an overdischarge current of a lithium battery, an overcharge voltage of a lithium battery, and an overdischarge voltage of a lithium battery Energy storage system, characterized in that it has an alarm function for.

Images