KR102273934B1 - Energy storage apparatus - Google Patents

Abstract

According to an embodiment of the present invention, an energy storage device comprises: a housing in which a plurality of battery cells can be mounted; a camera driving unit installed on a housing cover connected to the housing; a thermal image camera installed in the camera driving unit to photograph thermal images of the plurality of battery cells; a control unit configured to control charging and discharging of the plurality of battery cells according to a charge/discharge schedule generated according to a schedule parameter including the thermal images of the plurality of battery cells; and a communication unit that transmits information on the thermal images to a battery management server according to control of the control unit and receives information on the charge/discharge schedule from the battery management server.

Description

Energy storage device {ENERGY STORAGE APPARATUS}

The present invention relates to an energy storage device.

Due to global warming caused by environmental pollution, there is an increasing demand for efficiency in power consumption. For this purpose, a power peak controller is installed, and charging and discharging of the battery cells is controlled according to the power peak controller.

In the battery charging/discharging schedule according to the general power peak controller, the charging/discharging time of the battery is fixed. Accordingly, it may be difficult to efficiently manage the battery cells because charging and discharging of the battery cells is not performed according to various factors affecting the operation of the battery cells.

In addition, a general peak controller blocks the air conditioner that consumes a lot of power at the peak of the consumer's power consumption, and thus people's discomfort may increase in summer.

Patent Publication 10-2018-0097344 (published on August 31, 2018)

An energy storage device according to an embodiment of the present invention is for managing a battery cell according to a power peak of a consumer.

The task of the present application is not limited to the task mentioned above, and another task that is not mentioned will be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, a plurality of battery cells (cell) can be mounted in a housing; a camera driving unit provided on a housing cover connected to the housing; a thermal imaging camera provided in the camera driving unit to take thermal images of the plurality of battery cells; a controller configured to control charging and discharging of the plurality of battery cells according to a charge/discharge schedule generated according to a schedule parameter including a thermal image of the plurality of battery cells; and a communication unit that transmits information on the thermal image to a battery management server under the control of the controller and receives information on the charge/discharge schedule from the battery management server.

The energy storage device according to an aspect of the present invention further includes a protection unit provided on the housing or the housing cover, wherein the protection unit is capable of transmitting infrared rays due to heat of the battery cell, and the thermal imaging camera and the camera driving unit can be protected from the explosion of the battery cell.

The protection unit may include one of a protective mesh network in which a plurality of holes are formed, a protective window capable of transmitting infrared rays, and a protective window made of a material capable of transmitting infrared rays and having a plurality of holes.

The control unit may transmit temperature information of a pixel exceeding a temperature threshold among pixels constituting the thermal image to the battery management server through the communication unit.

The battery management server derives a power peak expected time of the consumer according to the schedule parameter, generates the charge/discharge schedule according to the power peak expected time, and the charge/discharge schedule is based on the power peak expected time By stopping discharging of the battery cell and charging the battery cell, electricity is supplied from the battery cell to the consumer at the expected power peak time, thereby preventing the consumer from exceeding the peak power.

The schedule parameter may further include power consumption of consumers electrically connectable to the battery cell, generated power of a solar cell electrically connectable to the battery cell, residual power of the battery cell, and the number of times of charging and discharging of the battery cell. have.

The schedule parameter may further include temperature, humidity, wind speed, vertical insolation, and oblique insolation in an area in which the battery cell is installed.

The battery management server derives the reference pattern of each of the schedule parameters up to the first time point through machine learning, synchronizes the reference pattern of each of the parameters, and analyzes the degree of correlation between the reference patterns of each of the parameters to determine the reference degree of correlation , and it is possible to derive the expected power peak time of the consumer according to the comparison result of the correlation degree of each pattern of the parameter at the second time point after the first time point and the reference correlation degree.

The energy storage device according to an embodiment of the present invention may manage the battery cell by deriving the expected power peak time of the consumer and generating a charge/discharge schedule according to the power peak expected time.

The effect of the present application is not limited to the above-mentioned effects, and another effect not mentioned will be clearly understood by those skilled in the art from the following description.

1 and 5 show an energy storage device according to an embodiment of the present invention.
2 illustrates an internal structure of a housing cover of an energy storage device according to an embodiment of the present invention.
3 shows an example of a camera driving unit.
4 shows an example of a thermal image of a battery cell.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the accompanying drawings are only described in order to more easily disclose the contents of the present invention, and the scope of the present invention is not limited to the scope of the accompanying drawings. you will know

In addition, the terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

1 shows an energy storage device according to an embodiment of the present invention. 2 illustrates an internal structure of a housing cover of an energy storage device according to an embodiment of the present invention.

As shown in FIG. 1 , the energy storage device according to an embodiment of the present invention includes a housing 100 , a thermal imaging camera 110 , a camera driving unit 130 , a control unit 150 , and a communication unit 170 .

A plurality of battery cells are mounted in the housing 100 . To this end, the housing 100 may be provided with a rack for attaching and detaching the battery cells.

The camera driver 130 is provided in the housing cover HC connected to the housing 100 . Such a housing cover HC may cover one side of the housing 100 . When the housing cover HC covers one side of the housing 100 , heat from the battery cells may be transferred to the thermal imaging camera 110 . Since the connection structure between the housing cover HC and the housing 100 is a common technique for those skilled in the art, a description thereof will be omitted.

The camera driver 130 may move the thermal imaging camera 110 along the x-axis and the y-axis. The camera driving unit 130 will be described in detail later with reference to the drawings.

The thermal imaging camera 110 is provided in the camera driving unit 130 to take thermal images of a plurality of battery cells. Accordingly, the temperature of the battery cell according to charging and discharging may be measured.

The thermal imaging camera 110 may photograph all battery cells as one thermal image, or may photograph thermal images for each zone. In this case, some of all battery cells may be located in one zone.

The controller 150 controls charging/discharging of the plurality of battery cells according to a charge/discharge schedule generated according to a schedule parameter including a thermal image of the plurality of battery cells. The controller 150 may include a memory unit (not shown) capable of storing a charge/discharge schedule.

If the temperature of the battery cell is excessively high, the battery cell may not operate normally or, if severe, the risk of explosion may increase. The thermal image may provide information on the temperature of the battery cell, and the charge/discharge schedule is generated according to a schedule parameter including the temperature of the battery cell. The controller 150 may respond to a temperature change of the battery cell by controlling the charging/discharging of the battery cell according to the charging/discharging schedule.

As shown in FIG. 5 , the communication unit 170 transmits thermal image information to the battery management server 300 under the control of the control unit 150 , and performs charging/discharging schedules from the battery management server 300 . information is sent about

The energy storage device according to an embodiment of the present invention may further include a battery management server 300 , and the battery management server 300 will be described in detail later with reference to the drawings.

The communication unit 170 may perform at least one of wired communication and wireless communication. The communication unit 170 may access at least one of a wired network and a wireless network. The communication unit 170 may include a Bluetooth module or an NFC module for performing short-range communication, but the present invention is not limited to such a short-range communication module.

Next, an operation of the camera driving unit 130 will be described with reference to the drawings.

3 shows an example of the camera driving unit 130 . The driving unit 130 includes a stage 131 , a first motor 132 , a second motor 133 , a first rail movable body 134 , a second rail movable body 135 , and first to fourth guide rails 136 , 137, 138, 139), first belt 140, second belt 141, first movable pulley 142, second movable pulley 143, first fixed pulley 144, second It may include a fixed pulley 145 .

In this case, the first motor 132 and the second motor 133 may be stepping motors, but are not limited to the type of such motors. The first belt 140 and the second belt 141 may be a timing belt, but are not limited to the type of the belt. In addition, the first and second movable pulleys 142 and 143 and the first and second fixed pulleys 144 and 145 may be timing pulleys, but are not limited to such pulley types.

The first rail movable body 134 may move along the first guide rail 136 , and the second rail movable body 135 may move along the second guide rail 137 . In this case, the first guide rail 136 and the second guide rail 137 may be installed to be spaced apart from each other in parallel and extend in the first direction.

A first movable body pulley 142 and a second movable body pulley 143 may be provided in the first rail movable body 134 and the second rail movable body 135 , respectively. The third guide rail 138 and the fourth guide rail 139 may be connected to the first rail movable body 134 and the second rail movable body 135 .

At this time, the third guide rail 138 and the fourth guide rail 139 may be installed to be spaced apart from each other and extend in the second direction, and the second direction may perpendicularly cross the first direction.

The first motor 132 may be disposed adjacent to the first guide rail 136 , and the first fixed pulley 144 may be disposed adjacent to the first guide rail 136 opposite the first motor 132 . can be

The second motor 133 may be disposed adjacent to the second guide rail 137 , and the second fixed pulley 145 may be disposed adjacent to the second guide rail 137 opposite the second motor 133 . can be

Accordingly, the first fixed pulley 144 and the second fixed pulley 145 may face each other in the second direction.

The first belt 140 is connected to both sides of the stage 131 , and the first movable pulley 142 , the first motor 132 , the first fixed pulley 144 , the second fixed pulley 145 , and the second It may be caught on the movable pulley 143 . In addition, the second belt 141 is connected to both sides of the stage 131 , the second movable pulley 143 , the second motor 133 , the second fixed pulley 145 , the first fixed pulley 144 , the first 1 It can be caught on the movable pulley 142 .

The first belt 140 and the second belt 141 include a first movable pulley 142 , a first motor 132 , a first fixed pulley 144 , a second fixed pulley 145 , and a second movable pulley ( 143), but they can be hung apart so as not to overlap each other.

The stage 131 may move along the third guide rail 138 and the fourth guide rail 139 , and the third guide rail 138 and the fourth guide rail 139 are connected to the first rail movable body 134 and It is connected to the second rail movable body 135 . Also, the controller 150 may control the rotation directions of the first motor 132 and the second motor 133 .

Accordingly, the stage 131 may move to a position on a plane formed with the first and second directions as axes, and the thermal imaging camera 110 mounted on the stage 131 also uses the first and second directions as axes. can be moved to

Meanwhile, in the present invention, the thermal imaging camera 110 and the camera driving unit 130 are provided in the housing cover HC, unlike a general energy storage device. The battery cell has a risk of explosion, and when the battery cell explodes, flames or debris may damage the thermal imaging camera 110 and the camera driver 130 .

To prevent this, the energy storage device according to the embodiment of the present invention may further include a protection unit 105 . The protection part 105 may be provided in the housing 100 or the housing cover HC. The protection unit 105 may transmit infrared rays due to the heat of the battery cell, and may protect the thermal imaging camera 110 and the camera driving unit 130 from explosion of the battery cell.

In this case, the protection unit 105 may include one of a protective mesh network in which a plurality of holes are formed, a protective window capable of infrared transmission, and a protection window made of a material capable of infrared transmission and having a plurality of holes.

For example, as shown in FIGS. 1 and 2 , the protection unit 105 may include a copper protection mesh network in which a plurality of holes are formed, but is not limited thereto. In addition, the protective window may be made of a silicon glass material capable of transmitting infrared rays, but is not limited thereto.

The reason for using a protective mesh network or a protective window in which a plurality of holes is formed is that infrared transmission is possible and the heat generated in the battery cell can be smoothly convectioned to prevent the heat of the battery cell from being accumulated in the housing 100 . .

Meanwhile, the controller 150 may transmit temperature information of a pixel exceeding a temperature threshold among pixels constituting the thermal image to the battery management server 300 through the communication unit 170 .

For example, when the resolution of the thermal imaging camera 110 is 640×480, the thermal image may include approximately 300,000 pixels. Unlike the present invention, when the temperature information corresponding to each of 300,000 pixels is transmitted to the battery management server 300, the amount of transmitted data increases, so that the data transmission speed may be slowed down or the transmission bandwidth may need to be expanded.

According to the present invention, by transmitting temperature information about a pixel exceeding a temperature threshold, it is possible to prevent a decrease in data transmission speed and reduce the need for an extension of a transmission bandwidth.

Meanwhile, the controller 150 may transmit at least one of location information of pixels exceeding the temperature threshold and information on the number of pixels exceeding the temperature threshold to the battery management server 300 .

For example, as shown in FIG. 4 , three battery cells are mounted in the housing 100 , and the thermal imaging camera 110 may take a thermal image for each battery cell according to the operation of the camera driving unit 130 . .

The controller 150 may transmit at least one of location information (eg, coordinate information) and the number of pixels exceeding a temperature threshold among pixels constituting a thermal image for each battery cell to the battery management server 300 .

Such pixel location information and pixel number information may be further included in the schedule parameter, and the battery management server 300 may generate a charge/discharge schedule according to the schedule parameter including the pixel location information and the pixel number information. .

In addition, the battery management server 300 may predict and provide to the manager a battery cell in which an abnormal operation occurs more frequently than the remaining battery cells among all battery cells through machine learning on pixel location information and pixel number information. That is, if the temperature of a specific battery cell is frequently higher than that of other battery cells, it may be predicted and the specific battery cell may be replaced.

In this case, the identification information on the battery cell may be matched with the location information of the battery cell and stored in advance in the aforementioned memory unit. The controller 150 controls the first motor 132 and the second motor 133 of the camera driving unit 130 according to the location information of the battery cells, so that the thermal imaging camera 110 moves to a position for photographing each battery cell. can be moved

In addition, unlike FIG. 4 , when a plurality of battery cells are photographed in one thermal image, the identification information of the battery cells is matched with the position information of the battery cells and the pixel position information occupied by each battery cell in one thermal image to match the memory. It can also be pre-stored in the department.

On the other hand, the battery management server 300 may derive a power peak (peak) expected time of the consumer according to the schedule parameter, and generate a charge/discharge schedule according to the expected power peak time. Consumers are customers who purchase electricity for their own use.

At this time, the charging/discharging schedule stops discharging of the battery cells according to the expected power peak time and proceeds to charge the battery cells, and supplies electricity from the battery cells to the consumers at the expected power peak time to prevent the consumer from exceeding the power peak. .

The schedule parameter may further include power consumption of a consumer electrically connectable to the battery cell, generated power of a solar cell electrically connectable to the battery cell, residual power of the battery cell, and the number of times of charging and discharging of the battery cell.

Since the consumer's power consumption, the generated power of the solar cell, and the remaining power of the battery cell are related to the charge/discharge amount of the battery cell, the charge/discharge schedule of the battery cell may be affected.

Since the amount of charge or discharge of a battery cell may change according to the number of times of charge/discharge, the number of times of charge/discharge may affect the charge/discharge schedule.

In addition, the schedule parameter may further include temperature, humidity, wind speed, vertical insolation, and oblique insolation in an area in which the battery cells are installed. Such weather observation data may be transmitted from a weather information providing server 400 such as a server of the Korea Meteorological Administration.

Temperature, humidity, and wind speed may affect the performance of battery cells and solar cells, and vertical and oblique insolation may affect the amount of generation of solar cells.

As shown in FIG. 5 , the solar cell may be electrically connected to the battery cell to charge the battery cell or to supply power to the consumer as necessary. In addition, the energy storage device of the present invention may receive power from the power grid or supply charged power to the power grid.

In general EMS (Energy Management System), the consumer's power peak is set in advance, and when the consumer's power consumption exceeds the power peak, the power-consuming air conditioner can be shut down while maintaining the power supply to the work computer essential for work. . This can cause great inconvenience to people in the summer.

In contrast, the present invention can reduce the possibility of shutting down the air conditioner by preventing the power peak from being exceeded according to various schedule parameters in advance.

On the other hand, the battery management server 300 derives the reference pattern of each of the schedule parameters up to the first time point through machine learning, synchronizes the reference pattern of each parameter, and analyzes the degree of correlation between the reference patterns of each parameter to determine the reference correlation degree can be derived.

The battery management server 300 is an energy storage device, characterized in that deriving the power peak expected time of the consumer according to the comparison result of the correlation degree and the reference correlation degree of each parameter pattern of the second time point after the first time point.

In order to derive the expected power peak time of the consumer, the battery management server 300 derives the reference pattern of each schedule parameter up to the first time point through machine learning, and synchronizes the reference pattern of each schedule parameter to each schedule parameter. By analyzing the degree of correlation between the reference patterns of

The battery management server 300 may derive the expected power peak time of the consumer according to the comparison result of the correlation degree of each pattern of the schedule parameters at the second time point after the first time point and the reference correlation degree.

For example, the battery management server 300 derives a reference pattern for each of a plurality of schedule parameters through machine learning, synchronizes the reference patterns, and analyzes the degree of correlation between the reference patterns to derive a reference degree of correlation. have.

Thereafter, the battery management server 300 may derive a pattern of each of a plurality of schedule parameters transmitted in real time, and may derive a degree of correlation between these patterns.

The battery management server 300 may compare the degree of correlation with the reference degree of correlation to derive the expected power peak time of the consumer.

As described above, in the battery charge/discharge schedule of the general power peak controller, the charge/discharge time of the battery is fixed.

Accordingly, it may be difficult to efficiently manage the battery cells because charging and discharging of the battery cells is not performed according to various factors affecting the operation of the battery cells. In addition, the general peak controller can block the air conditioner that consumes a lot of power at the peak of the consumer's power consumption.

In contrast, in the present invention, by deriving the expected power peak time using a pattern of various parameters derived through machine learning, the battery cell is pre-charged by receiving power from the solar cell before the power peak expected time, or the power supplied by the battery cell can reduce

On the other hand, as described above, the battery management server 300 predicts a battery cell in which an abnormal operation occurs more frequently than the remaining battery cells among all battery cells through machine learning on pixel location information and pixel number information. can also be provided to

That is, the battery management server 300 derives a reference pattern for each of the schedule parameter for the pixel location information and the schedule parameter for the pixel number information through machine learning, and synchronizes the reference patterns to correlate the reference patterns By analyzing the degree, the standard correlation degree can be derived.

Thereafter, the battery management server 300 may derive a pattern of each of the schedule parameters transmitted in real time, and derive a degree of correlation between these patterns. The battery management server 300 may predict a battery cell in which an abnormal operation occurs by comparing the degree of correlation with the reference degree of correlation.

As shown in FIG. 5 , the battery management server 300 may transmit information about the expected power peak time of the consumer to the manager's terminal 400 . In addition, the manager's terminal 400 may perform short-range communication with the communication unit 170 to check status information on the battery cells.

As described above, the embodiments according to the present invention have been reviewed, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope of the present invention in addition to the above-described embodiments is recognized by those skilled in the art. It is self-evident to Therefore, the above-described embodiments are to be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description, but may be modified within the scope of the appended claims and their equivalents.

housing (100)
protection unit (105)
housing cover (HC)
thermal imaging camera (110)
camera driver 130
control unit 150
communication unit 170
Battery Management Server (300)
Weather information providing server (400)

Claims (8)

a housing in which a plurality of battery cells can be mounted;
a camera driving unit provided on a housing cover connected to the housing;
a thermal imaging camera provided in the camera driving unit to sense infrared rays generated by heat of the plurality of battery cells to capture a thermal image;
a controller configured to control charging and discharging of the plurality of battery cells according to a charge/discharge schedule generated according to a schedule parameter including a thermal image of the plurality of battery cells; and
and a communication unit that transmits information on the thermal image to a battery management server under the control of the controller and receives information on the charge/discharge schedule from the battery management server,
Further comprising a protection unit provided on the housing or the housing cover,
The protection unit,
Infrared rays can be transmitted by the heat of the battery cell, and the thermal imaging camera and the camera driving unit are protected from explosion of the battery cell,
An energy storage device comprising one of a protective mesh network having a plurality of holes formed therein, a protective window capable of transmitting infrared rays, and a protective window made of a material capable of infrared transmission and having a plurality of holes. delete delete According to claim 1,
wherein the control unit transmits temperature information of pixels exceeding a temperature threshold among pixels constituting the thermal image to the battery management server through a communication unit. According to claim 1,
The battery management server derives a power peak expected time of the consumer according to the schedule parameter, and generates the charge/discharge schedule according to the expected power peak time,
The charging/discharging schedule stops discharging of the battery cells according to the expected power peak time, and proceeds to charge the battery cells, and supplies electricity from the battery cells to the consumers at the power peak expected time to supply the consumer's power peak Energy storage device, characterized in that it prevents overflow. 6. The method of claim 5,
The schedule parameter further includes power consumption of consumers electrically connectable to the battery cell, generated power of a solar cell electrically connectable to the battery cell, residual power of the battery cell, and the number of times of charging and discharging of the battery cell. energy storage device. 7. The method of claim 6,
The schedule parameter is an energy storage device, characterized in that it further comprises temperature, humidity, wind speed, vertical insolation and oblique insolation of the area where the battery cells are installed. 8. The method according to any one of claims 5 to 7,
The battery management server
Deriving the reference pattern of each of the schedule parameters up to the first time point through machine learning,
A reference correlation degree is derived by synchronizing the reference pattern of each of the parameters and analyzing the degree of correlation between the reference patterns of each of the parameters,
Energy storage device, characterized in that deriving the expected power peak time of the consumer according to the comparison result of the correlation degree of each pattern of the parameter at a second time point after the first time point and the reference correlation degree.

Images