KR20120076756A - Battery system - Google Patents

Abstract

PURPOSE: A battery system is provided to be able to control the temperature of batteries, to control moisture of a space in which the batteries are installed, and to reduce temperature difference among batteries. CONSTITUTION: A battery system(1) comprises a rack(100) in which a first tray(200a) and a second tray(200b) for accepting at least one battery respectively are lateral symmetrically combined each other. the rack comprises a first discharge part(120), and a second discharge part(130) for dispersing temperature control fluid supplied to between the first tray and the second tray to side to side. The rack comprises a supply part between the first tray and the second tray. Both sides of the supply part facing the first tray and the second tray are formed to be opened. Between the first discharge part and the second discharge part, the first tray and the second tray are located.

Description

Battery System {Battery System}

The present invention relates to a battery system in which a battery is installed for use in a battery energy storage system.

With the development of the industry, the demand for electric power is increasing, and the gap of electricity use between day and night, season, and day is increasing. For this reason, many techniques are being developed rapidly to reduce peak load by utilizing the surplus power of the system. Among these technologies, a battery which stores surplus power of the system in the battery or supplies the underpower of the system from the battery Battery Energy Storage System (BESS).

The battery energy storage system stores surplus power generated from renewable energy sources such as wind power and solar power at night, and supplies the power stored in the battery to the grid in case of peak load or system accident. This will stabilize system power fluctuating by renewable energy sources and achieve maximum load reduction and load leveling. In particular, such a battery energy storage system may be used in an intelligent grid, which is recently emerging due to the emergence of various renewable energy sources.

Such battery energy storage systems include a Power Conditioning System (PCS), and a Battery System in which batteries are installed. The power management system (PCS) has a function of managing the power of the batteries, such as performing power conversion (AC / DC) between the grid and the battery system. Batteries are either discharged to power the system or charged using power supplied from the system.

Such batteries are affected by temperature and humidity. Discharge efficiency and charging efficiency are different according to temperature, and electrical safety is reduced in a high humidity space. Therefore, the development of a battery system that can be adjusted to the temperature of the batteries to increase the discharge efficiency and charging efficiency for the batteries is required. In addition, the development of a battery system that can control the humidity of the space in which the batteries are installed is required to improve the electrical safety for the batteries.

In addition, the state of charge (SOC) of the batteries must be checked before replacement or maintenance work is performed in order to prevent occurrence of a condition that impairs electrical safety such as inrush current during the replacement or maintenance work of the batteries. Estimation must be done. Here, when the temperature deviation between the batteries is large, the accuracy of the operation of estimating the state of charge of the batteries is degraded. Therefore, there is a need for the development of a battery system that can reduce the temperature variation between batteries in order to improve the accuracy of the task of estimating the state of charge of the batteries.

The present invention has been made to solve the above-described needs, and an object of the present invention is to provide a battery system that can adjust the temperature of the batteries.

Another object of the present invention is to provide a battery system that can control the humidity of the space in which the batteries are installed.

Another object of the present invention is to provide a battery system that can reduce the temperature deviation between the batteries.

In order to achieve the above-mentioned object, the present invention can include the following configuration.

The battery system according to the present invention may include a rack in which a first tray and a second tray for accommodating at least one battery are symmetrically coupled to each other. The rack may include a first discharge part and a second discharge part for dispersing the temperature control fluid supplied between the first tray and the second tray from side to side.

A battery system according to the present invention includes a rack including a first discharge portion and a second discharge portion for discharging the temperature control fluid of the battery, and a supply portion located between the first discharge portion and the second discharge portion; And a plurality of trays coupled to the rack to be positioned between one side of the supply unit and the first discharge unit and between the other side of the supply unit and the second discharge unit. The supply part may be formed such that both sides are open to move the temperature control fluid to the trays located at both sides.

According to the present invention, the following effects can be obtained.

The present invention can maintain the temperature of the battery to a temperature that can increase the discharge efficiency and charging efficiency for the battery by adjusting the temperature of the battery.

The present invention can maintain the humidity of the space in which the batteries are installed with a humidity that can improve the electrical safety for the battery by adjusting the humidity of the space in which the batteries are installed.

The present invention can improve the accuracy of the operation of estimating the state of charge (SOC) of the batteries by reducing the temperature deviation between the batteries, and thus the inrush current during the replacement, maintenance work, etc. Likewise, it is possible to prevent the occurrence of a situation that impairs electrical safety.

The present invention improves the ease of the operation of coupling the tray to the rack and the operation of separating the tray from the rack, thereby improving the ease of replacement, maintenance work for the batteries.

1 is a schematic perspective view of a battery system according to the present invention;
2 is a schematic plan view of a battery system according to the present invention;
3 is a conceptual side view of a battery system according to the present invention;
4 is a schematic perspective view of a rack and tray according to the present invention;
5 is a schematic exploded perspective view of a rack according to the present invention;
FIG. 6 is a side cross-sectional view taken along line II of FIG. 4. FIG.
7 is a schematic perspective view of a tray according to the present invention;
8 is a schematic exploded perspective view of a tray according to the present invention;
9 is a schematic perspective view illustrating a connection relationship between a battery module, a control line, and a bus bar according to the present invention;
10 is a schematic perspective view of a battery system according to a modified embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of a battery system according to the present invention will be described in detail.

1 is a schematic perspective view of a battery system according to the present invention, FIG. 2 is a schematic plan view of a battery system according to the present invention, and FIG. 3 is a conceptual side view of the battery system according to the present invention.

1 to 3, the battery system 1 according to the present invention includes a rack 100 in which a temperature control fluid for controlling a temperature of a battery (not shown) moves therein. A plurality of trays 200 (shown in FIG. 3) are installed in the rack 100. Each of the trays 200 accommodates at least one battery. The temperature control fluid is a fluid capable of heating or cooling the battery to regulate the temperature of the battery. For example, the temperature control fluid may be heated or cooled air, a refrigerant, or the like. The battery system 1 according to the present invention can control the temperature of the batteries by heating or cooling the batteries using the temperature control fluid. The temperature control fluid is supplied into the rack 100, and after adjusting the temperature of the batteries accommodated in the trays 200 while passing through the trays 200 installed in the rack 100, the rack 100. Is discharged from. Therefore, the battery system 1 according to the present invention can maintain the temperature of the batteries at a temperature that can increase the discharge efficiency and the charging efficiency for the batteries. For example, the battery system 1 according to the invention can be adjusted such that the temperature of the batteries is maintained at approximately 25 ° C. In addition, the battery system 1 according to the present invention can adjust the humidity of the space in which the batteries are installed using the temperature control fluid. Therefore, the battery system 1 according to the present invention can improve the electrical safety for the battery by maintaining a constant humidity of the space in which the batteries are installed.

Hereinafter, the components for moving the temperature control fluid will be described in detail with reference to the accompanying drawings, before explaining the rack 100 and the tray 200 in detail.

1 to 3, the battery system 1 according to the present invention may include a first vent (Vent, 10) for supplying the temperature control fluid to the rack (100). The first vent 10 is connected to the rack 100 so that the temperature control fluid can be supplied to the rack 100. The flow path through which the temperature control fluid is moved is formed in the first vent 10.

Battery system 1 according to the present invention may include a second vent (20) for discharging the temperature control fluid to adjust the temperature of the batteries from the rack (100). The second vent 20 is connected to the rack 100 so that the temperature control fluid can be discharged from the rack 100. A flow path through which the temperature control fluid is moved is formed in the second vent 20. As shown in FIG. 3, the rack 100 may be installed to be positioned between the second vent 20 and the first vent 10. The second vent 20 may be installed to be positioned above the rack 100, and the first vent 10 may be installed to be positioned below the rack 100. The temperature control fluid is raised from the first vent 10 is supplied to the rack 100, and after adjusting the temperature of the battery is raised to be discharged from the rack 100 to the second vent (20) I can move it. When the temperature control fluid heats the batteries, the temperature control fluid discharged to the second vent 20 is in a state where the temperature is lowered by heating the batteries. When the temperature control fluid cools the batteries, the temperature control fluid discharged to the second vent 20 is in a state where the temperature is increased by cooling the batteries.

When the battery system 1 according to the present invention includes a plurality of racks 100, the first vent 10 and the second vent 20 may be connected in communication with each of the racks 100. . The first vent 10 and the second vent 20 may be formed long in the direction in which the racks 100 are arranged. The racks 100 may be arranged in a plurality of rows, and in this case, the battery system 1 according to the present invention may have a number corresponding to the number of rows of the racks 100 and the first vent 10. The second vent 20 may be included. As shown in FIG. 2, the first vent 10 may be installed below the racks 100, and the second vent 20 may be spaced apart from the racks 100 by a predetermined distance. Can be installed. In this case, the second vent 20 may further include conduits (not shown) connected in communication with the racks 100.

The battery system 1 according to the present invention may include an air conditioner 30 connected to the first vent 10 and the second vent 20. The air conditioning apparatus 30 may move the temperature control fluid to the first vent 10, the rack 100, and the second vent 20. The air conditioning apparatus 30 includes a fan (Fan, 31) for moving the temperature control fluid, and a temperature control unit (32) for cooling or heating the temperature control fluid supplied from the second vent (20). do. The fan 31 provides a suction force for discharging the temperature control fluid from the second vent 20, thereby supplying the temperature control fluid to the first vent 10, the rack 100, and the second. May be moved to the vent 20. In this case, the fan 31 is installed close to the portion in which the second vent 20 is connected in the air conditioning apparatus 30, and the temperature control unit 32 is the fan 31 and the air conditioning apparatus ( In 30), the first vent 10 may be installed between the connected portions. The fan 31 provides a blowing force for moving the temperature control fluid to the first vent 10, thereby transferring the temperature control fluid to the first vent 10, the rack 100, and the first fluid. It can also be moved to 2 vents 20. In this case, the fan 31 is installed close to the portion where the first vent 10 is connected in the air conditioning apparatus 30, and the temperature control unit 32 is the fan 31 and the air conditioning apparatus ( In 30), the second vent 20 may be installed between the connected parts. The air conditioning apparatus 30 may include a plurality of fans 31, some of the fans 31 may provide a suction force, and some of the fans 31 may provide a blowing force. The temperature control fluid may circulate the first vent 10, the rack 100, the second vent 20, and the air conditioning apparatus 30. The air conditioning device 30 may be a heating, ventilation and air conditioning (HVAC) device.

The battery system 1 according to the invention may comprise a power supply 41 for supplying power. The power supply 41 is connected to a Power Conditioning System (PCS) (not shown). The battery system 1 according to the invention may further comprise a control device 42. The control device 42 controls and monitors the components of the battery system 1 according to the invention. The battery system 1 according to the present invention may further include a fire fighting equipment 43 for preparing for a fire. The power supply device 41 may supply power to the control device 42, the fire fighting equipment 43, and the air conditioning device 30. The battery system 1 according to the invention may further comprise a sub-control device 44 (shown in FIG. 3). The sub-control device 44 is installed in the rack 100 to be positioned on the tray 200. The sub controller 44 may include a power switch, a battery management system (BMS) for checking current, voltage, and temperature of batteries installed in the rack 100, and batteries installed in the rack 100. It may include an initial charging circuit for preventing a sudden current inflow, and a terminal unit for electrically connecting to the batteries installed in the rack 100. When the battery system 1 according to the present invention includes a plurality of racks 100, the sub-control device 44 may be installed in each of the racks 100.

In the above, the first vent 10, the second vent 20, the air conditioning device 30, the power supply device 41, the control device 42, the fire fighting equipment 43, and the sub Although the control device 44 has been described as being provided in the battery system 1 according to the present invention, it may be configured as a separate system from the battery system 1 according to the present invention. Hereinafter, the rack 100 will be described in detail with reference to the accompanying drawings.

Figure 4 is a schematic perspective view of the rack and tray according to the present invention, Figure 5 is a schematic exploded perspective view of the rack according to the invention, Figure 6 is a side cross-sectional view of the line I-I of FIG.

Referring to FIG. 3, the trays 200 are symmetrically coupled to the rack 100. The temperature control fluid is supplied into the rack 100 between the trays 200 positioned symmetrically. The rack 100 includes a first discharge part 120 and a second discharge part 130 for dispersing the temperature control fluid supplied between the trays 200 from side to side. The trays 200 are positioned between the first discharge part 120 and the second discharge part 130. Hereinafter, the tray 200 located closer to the first discharge unit 120 than the second discharge unit 130 among the trays 200 is defined as a first tray 200a, and the first discharge unit The tray 200 located closer to the second discharge unit 130 than to the 120 will be described as a second tray 200b. The temperature control fluid is supplied into the rack 100 between the first tray 200a and the second tray 200b, and is then distributed to the left and right to the first tray 200a and the second tray ( 200b) is supplied to each. That is, a part of the temperature control fluid is supplied to the first tray 200a, and a part is supplied to the second tray 200b. Accordingly, the temperature of the battery accommodated in the first tray 200a and the second tray 200b may be controlled by the temperature control fluid. And, the temperature control fluid passed through the first tray 200a is discharged to the outside of the rack 100 through the first discharge unit 120, the temperature control fluid passed through the second tray 200b is It is discharged to the outside of the rack 100 through the second discharge unit 130. Therefore, the battery system 1 according to the present invention can achieve the following effects.

First, the first tray 200a and the second tray 200b are located side by side, and the temperature of the first tray 200a and the second tray 200b in one direction with respect to the inside of the rack 100. When the control fluid is supplied, the temperature control fluid adjusts the temperature of the battery accommodated in the first tray 200a and then adjusts the temperature of the battery accommodated in the second tray 200b. When the temperature control fluid cools the temperature of the battery, the temperature control fluid cools the battery accommodated in the second tray 200b in a state where the temperature is increased by cooling the battery accommodated in the first tray 200a. Will be done. Accordingly, there is a problem that the temperature deviation between the battery accommodated in the first tray 200a and the battery housed in the second tray 200b becomes large.

On the contrary, in the battery system 1 according to the present invention, the first tray 200a and the second tray 200b are symmetrically positioned between the first tray 200a and the second tray 200b. Thermostatic fluid is supplied. Accordingly, the temperature control fluid is supplied into the rack 100 between the first tray 200a and the second tray 200b, and is then distributed to the left and right to the first tray 200a and the first tray 200a. It is supplied to each of the two trays 200b. Accordingly, the temperature control fluid controls the temperature of the battery accommodated in the first tray 200a and the battery accommodated in the second tray 200b. Accordingly, the battery system 1 according to the present invention can reduce the temperature deviation between the batteries. Therefore, the battery system 1 according to the present invention can improve the accuracy of the operation of estimating the state of charge (SOC) of the batteries, and thus inrush current during replacement and maintenance of the batteries It is possible to prevent the occurrence of a situation that impairs electrical safety, such as.

3 to 5, the battery system 1 according to the present invention includes a supply unit 110 for receiving the temperature control fluid.

The supply unit 110 is installed to be positioned between the first discharge unit 120 and the second discharge unit 130. The first tray 200a is positioned between the supply unit 110 and the first discharge unit 120, and the second tray 200b is disposed between the supply unit 110 and the second discharge unit 130. Located. Some of the temperature control fluid supplied to the supply unit 110 moves in the direction (A arrow direction) in which the first tray 200a is located. Some of the temperature control fluid supplied to the supply unit 110 moves in the direction in which the second tray 200b is located (B arrow direction). That is, the temperature control fluid is supplied to the supply unit 110 and then dispersed and moved in both directions (A arrow direction and B arrow direction) so that the battery accommodated in the first tray 200a and the second tray 200b. The temperature of the battery accommodated in the can be adjusted. To this end, the supply unit 110 is formed such that both sides facing the first tray 200a and the second tray 200b are open. Therefore, the battery system 1 according to the present invention can achieve the following effects.

First, when the first tray (200a) and the second tray (200b) is located side by side in the direction of the supply unit 110, the temperature control fluid is the temperature of the battery accommodated in the first tray (200a) After controlling the temperature of the battery accommodated in the second tray 200b. When the temperature control fluid cools the temperature of the battery, the temperature control fluid cools the battery accommodated in the second tray 200b in a state where the temperature is increased by cooling the battery accommodated in the first tray 200a. Will be done. Accordingly, there is a problem that the temperature deviation between the battery accommodated in the first tray 200a and the battery housed in the second tray 200b becomes large.

In contrast, in the battery system 1 according to the present invention, the first tray 200a and the second tray 200b are positioned at both sides of the supply unit 110. Accordingly, the temperature control fluid controls the temperature of the battery accommodated in the first tray 200a and the battery accommodated in the second tray 200b. Accordingly, the battery system 1 according to the present invention can reduce the temperature deviation between the batteries. Therefore, the battery system 1 according to the present invention can improve the accuracy of the operation of estimating the state of charge (SOC) of the batteries, and thus the electrical safety, such as inrush current during replacement, maintenance work for the batteries It is possible to prevent the situation from occurring.

3 to 5, the supply unit 110 receives a temperature control fluid from the first vent 10 (shown in FIG. 3), and supplies the supplied temperature control fluid to the first tray 200a. Supply to the second tray 200b. The temperature control fluid supplied to the first tray 200a moves to the first discharge part 120 through the first tray 200a and the second vent through the first discharge part 120. To 20 (shown in FIG. 3). The temperature control fluid supplied to the second tray 200b passes through the second tray 200b and moves to the second discharge unit 130, and the second vent is provided through the second discharge unit 130. To 20 (shown in FIG. 3). The supply unit 110 is connected in communication with the first vent 10 so that the temperature control fluid is supplied from the first vent 10. When the battery system 1 according to the present invention includes a plurality of racks 100, the supply unit 110 of each of the racks 100 may be connected to communicate with the first vent 10.

The supply unit 110 is formed such that a portion connected to the first vent 10 is opened so that the temperature control fluid flows from the first vent 10. The first vent 10 may be installed to be positioned below the rack 100, and the second vent 20 may be installed to be positioned above the rack 100. In this case, the supply unit 110 is formed so that the lower portion is open, the upper portion is closed (閉鎖). Accordingly, the supply unit 110 may receive the temperature control fluid from the first vent 10 through the lower portion formed to be open, and prevent the temperature control fluid from leaking by the upper part formed to be closed. . Therefore, the supply unit 110 may induce the first tray 200a and the second tray 200b to be supplied through both sides of the temperature control fluid.

The supply unit 110 includes a first supply hole 111 (shown in FIG. 5) for receiving the temperature control fluid from the first vent 10. When the first vent 10 is installed to be positioned below the supply unit 110, the first supply hole 111 is formed below the supply unit 110. The supply unit 110 includes a second supply hole 112 (shown in FIG. 5) for supplying the temperature control fluid to the first tray 200a and the second tray 200b. The second supply hole 112 is formed at both sides of the supply unit 110. The second supply hole 112 may be formed through one side portion and the other side portion of the supply portion 110. Although not shown, the supply unit 110 may include a plurality of second supply holes 112. In this case, some of the second supply holes 112 may be formed at one side of the supply unit 110, and some of the second supply holes 112 may be formed at the other side of the supply unit 110. Can be. The first tray 200a and the second tray 200b may be coupled to the supply unit 110 by a fastening means such as a bolt. To this end, the supply unit 110 includes a first fastening groove 113 for fastening the fastening means. The supply unit 110 may include a plurality of first fastening grooves 113.

The supply unit 110 may be formed by combining a plurality of frames 114, 115, 116, and 117. The supply unit 110 may be formed by combining the lower frame 114, the upper frame 115, the front frame 116, and the rear frame 117.

The first supply hole 111 is formed in the bottom frame 114. The first supply hole 111 is formed through the lower frame 114. The upper frame 115 is positioned to be spaced apart a predetermined distance from the lower frame 114 in an upward direction. The upper frame 115 blocks the temperature control fluid from leaking to the upper side of the supply unit 110.

The front frame 116 is coupled to the bottom frame 114 and the top frame 115. The front frame 116 blocks the temperature control fluid from leaking to the front side of the supply unit 110. The first fastening groove 113 may be formed in the front frame 116. The rear frame 117 is coupled to the lower frame 114 and the upper frame 115. The rear frame 117 blocks the temperature control fluid from leaking to the rear side of the supply unit 110. The rear frame 117 and the front frame 116 are spaced apart from each other by a predetermined distance and are coupled to the lower frame 114 and the upper frame 115.

As the lower frame 114, the upper frame 115, the front frame 116, and the rear frame 117 are combined, the second supply hole 112 may be formed. By the lower frame 114, the upper frame 115, the front frame 116, and the rear frame 117, the supply unit 110 may be formed in a 'k' shape as a whole. The lower frame 114, the upper frame 115, the front frame 116, and the rear frame 117 may be coupled by a fastening means such as a bolt. The lower frame 114, the upper frame 115, the front frame 116, and the rear frame 117 may be integrally formed. Although not shown, the supply unit 110 may further include a center frame. The center frame of the supply unit 110 is coupled to be located in the space formed by the lower frame 114, the upper frame 115, the front frame 116, and the rear frame 117. The center frame of the supply unit 110 may be formed in a rectangular rectangular shape as a whole. The second supply hole 112 may be formed at both sides of the central frame of the supply unit 110. A connection hole (not shown) connected in communication with the first supply hole 111 may be formed below the central frame of the supply unit 110. The lower frame 114, the upper frame 115, the front frame 116, the rear frame 117, and the center frame may be integrally formed. The center frame of the supply unit 110 may form a lower portion and an upper portion of the supply unit 110 in place of the lower frame 114 and the upper frame 115. In this case, the first supply hole 111 may be formed at a lower portion of the central frame of the supply unit 110.

A plurality of first trays 200a may be installed to be stacked up and down between one side of the supply unit 110 and the first discharge unit 120. A plurality of second trays 200b may be installed to be stacked up and down between the other side of the supply unit 110 and the second discharge unit 130. Accordingly, the battery system 1 according to the present invention can increase the number of batteries that can control the temperature by using one supply unit 110. In addition, the battery system 1 according to the present invention is installed so that the first tray (200a) and the second tray (200b) is stacked up and down, the first tray (200a) and the second tray (200b) Each of the) may be directly supplied to the temperature control fluid from the supply unit (110). Therefore, the battery system 1 according to the present invention can increase the number of batteries that can adjust the temperature using one supply unit 110 while preventing the temperature deviation between the batteries from increasing.

The supply unit 110 may be formed to extend in the vertical direction, that is, the first tray 200a and the second tray 200b are stacked vertically. The front frame 116 and the rear frame 117 is formed long in the vertical direction, the supply unit 110 may be formed long in the vertical direction. In FIG. 4, four first trays 200a and two second trays 200b are installed to be stacked. However, the first tray 200a and the second tray 200b are not limited thereto. Two or more may be installed to be stacked. The supply unit 110 may be formed long in the vertical direction to a length corresponding to the height formed by the stack of the first tray (200a) and the second tray (200b). The supply unit 110 may include a plurality of first fastening grooves 113, and the first fastening grooves 113 may be formed to be spaced apart from each other by a predetermined distance in a vertical direction. Although not shown, it is also possible that the first tray 200a and the second tray 200b are provided one by one.

3 to 5, the temperature control fluid passing through the first tray 200a is discharged from the first discharge part 120. The first discharge part 120 is installed to be spaced apart from the supply part 110 in a direction (A arrow direction) from the supply part 110 toward the first tray 200a. The first discharge part 120 is installed to be located opposite to the second discharge part 130 with respect to the supply part 110.

The temperature control fluid that has passed through the first tray 200a flows into the first discharge part 120, and the temperature control fluid that flows in is discharged from the first discharge part 120. The temperature control fluid discharged from the first discharge part 120 moves to the second vent 20 (shown in FIG. 3). The first discharge part 120 is connected in communication with the second vent 20 so that the temperature control fluid is discharged to the second vent 20. When the battery system 1 according to the present invention includes a plurality of racks 100, the first discharge part 120 of each of the racks 100 may be connected to communicate with the second vent 20. have.

The first discharge part 120 is formed such that a part connected to the second vent 20 is opened so that the temperature control fluid is discharged to the second vent 20. When the second vent 20 is installed to be positioned above the rack 100, the first discharge part 120 is formed to have an upper portion open and a lower portion thereof closed. Accordingly, the first discharge part 120 may allow the temperature control fluid to be discharged to the second vent 20 through an upper part formed to be open, and the temperature control fluid leaks by a lower part formed to be closed. Can be blocked.

The first discharge part 120 includes a first discharge hole 121 (shown in FIG. 5) for discharging the temperature control fluid to the second vent 20. When the second vent 20 is installed to be positioned above the first discharge part 120, the first discharge hole 121 is formed at an upper portion of the first discharge part 120. The first discharge part 120 includes a first vent hole 122 (shown in FIG. 5) for introducing a temperature control fluid that has passed through the first tray 200a. The first vent hole 122 is formed on one surface of the first discharge part 120 facing the first tray 200a. The first vent hole 122 may be formed to penetrate through one surface of the first discharge part 120 facing the first tray 200a. The temperature control fluid introduced into the first discharge part 120 through the first vent hole 122 is discharged to the second vent 20 through the first discharge hole 121. Although not shown, when the supply unit 110 includes a center frame, the first vent hole 122 may be formed to have a larger size than the second supply hole 112 formed in the center frame of the supply unit 110. Can be.

The first tray 200a may be coupled to the first discharge part 120 by a fastening means such as a bolt. To this end, the first discharge part 120 includes a second fastening groove 123 for fastening the fastening means. The first discharge part 120 may include a plurality of second fastening grooves 123. The first tray 200a is fixed to the supply part 110 and the first discharge part 120 by the fastening means, so that the first tray 200a may be prevented from being shaken by vibration.

The first discharge part 120 may be formed by combining a plurality of frames 124, 125, 126, and 127. The first discharge part 120 may be formed by combining the lower frame 124, the front frame 125, the rear frame 126, and the center frame 127.

The lower frame 124 blocks the temperature control fluid from leaking to the lower side of the first discharge part 120. The front frame 125 is coupled to the bottom frame 124. The front frame 125 blocks the temperature control fluid from leaking to the front side of the first discharge part 120. The second fastening groove 123 may be formed in the front frame 125. The rear frame 126 is coupled to the lower frame 124. The rear frame 126 blocks the temperature control fluid from leaking to the rear side of the first discharge part 120. The rear frame 126 and the front frame 125 are coupled to the bottom frame 124 spaced apart from each other by a predetermined distance. The center frame 127 is coupled to be positioned in a space formed as the lower frame 124, the front frame 125, and the rear frame 126 are coupled to each other. The center frame 127 may be formed in a rectangular parallelepiped shape as a whole. The first discharge hole 121 is formed at an upper portion of the central frame 127, and the first vent hole 122 is formed at one surface facing the first tray 200a. The lower frame 124, the front frame 125, the rear frame 126, and the center frame 127 may be coupled by a fastening means such as a bolt. The lower frame 124, the front frame 125, the rear frame 126, and the center frame 127 may be integrally formed.

A plurality of first trays 200a may be installed to be stacked vertically between the first discharge part 120 and the supply part 110. The first discharge part 120 may be formed to be elongated in the vertical direction in which the first trays 200a are stacked vertically. The front frame 125, the rear frame 126, and the center frame 127 are formed long in the vertical direction, so that the first discharge part 120 may be formed long in the vertical direction. The first discharge part 120 may be formed to extend in the vertical direction with a length greater than the height formed by stacking the first trays 200a. The first discharge part 120 may include a plurality of second fastening grooves 123, and the second fastening grooves 123 may be formed to be spaced apart from each other in a vertical direction by a predetermined distance. The first discharge part 120 may include a plurality of first vent holes 122, and the first vent holes 122 may be formed to be spaced apart from each other by a predetermined distance in a vertical direction. The first through holes 122 may be formed at a height corresponding to the height at which the first trays 200a are positioned.

3 to 5, the temperature control fluid passing through the second tray 200b is discharged from the second discharge unit 130. The second discharge part 130 is provided to be spaced apart from the supply part 110 in a direction (B arrow direction) from the supply part 110 toward the second tray 200b. The second discharge unit 130 is installed to be located opposite to the first discharge unit 120 with respect to the supply unit 110.

The temperature control fluid that has passed through the second tray 200b flows into the second discharge part 130, and the introduced temperature control fluid is discharged from the second discharge part 130. The temperature control fluid discharged from the second discharge unit 130 moves to the second vent 20 (shown in FIG. 3). The second discharge unit 130 is connected in communication with the second vent 20 so that the temperature control fluid is discharged to the second vent 20. When the battery system 1 according to the present invention includes a plurality of racks 100, the second discharge unit 130 of each of the racks 100 may be connected in communication with the second vent 20. have.

The second discharge part 130 is formed such that a portion connected to the second vent 20 is opened so that the temperature control fluid is discharged to the second vent 20. When the second vent 20 is installed to be positioned above the rack 100, the second discharge part 130 is formed to have an upper portion open and a lower portion thereof closed. Accordingly, the second discharge part 130 may allow the temperature control fluid to be discharged to the second vent 20 through an upper part formed to be open, and the temperature control fluid leaks by a lower part formed to be closed. Can be blocked.

The second discharge unit 130 includes a second discharge hole 131 (shown in FIG. 5) for discharging the temperature control fluid to the second vent 20. When the second vent 20 is installed to be positioned above the second discharge unit 130, the second discharge hole 131 is formed at an upper portion of the second discharge unit 130. The second discharge unit 130 includes a second vent hole 132 (shown in FIG. 5) for introducing a temperature control fluid that has passed through the second tray 200b. The second vent hole 132 is formed on one surface of the second discharge portion 130 facing the second tray 200b. The second vent hole 132 may be formed to penetrate through one surface of the second discharge unit 130 toward the second tray 200b. The temperature control fluid introduced into the second discharge unit 130 through the second vent hole 132 is discharged to the second vent 20 through the second discharge hole 131. Although not shown, when the supply unit 110 includes a center frame, the second vent hole 132 may be formed to have a larger size than the second supply hole 112 formed in the center frame of the supply unit 110. Can be.

The second tray 200b may be coupled to the second discharge unit 130 by a fastening means such as a bolt. To this end, the second discharge portion 130 includes a third fastening groove 133 for fastening the fastening means. The second discharge unit 130 may include a plurality of third fastening grooves 133. The second tray 200b is fixed to the supply part 110 and the second discharge part 130 by the fastening means, so that the second tray 200b may be prevented from being shaken by vibration.

The second discharge unit 130 may be formed by combining a plurality of frames 134, 135, 136, and 137. The second discharge unit 130 may be formed by combining the lower frame 134, the front frame 135, the rear frame 136, and the center frame 137.

The lower frame 134 blocks the temperature control fluid from leaking to the lower side of the second discharge unit 130. The front frame 135 is coupled to the bottom frame 134. The front frame 135 blocks the temperature control fluid from leaking to the front side of the second discharge unit 130. The third fastening groove 133 may be formed in the front frame 135. The rear frame 136 is coupled to the lower frame 134. The rear frame 136 blocks the temperature control fluid from leaking to the rear side of the second discharge unit 130. The rear frame 136 and the front frame 135 are separated from each other by a predetermined distance and are coupled to the bottom frame 134. The center frame 137 is coupled to be positioned in a space formed as the lower frame 134, the front frame 135, and the rear frame 136 are coupled to each other. The center frame 137 may be formed in a rectangular parallelepiped shape as a whole. The second discharge hole 131 is formed at an upper portion of the central frame 137, and the second vent hole 132 is formed at one surface facing the second tray 200b. The lower frame 134, the front frame 135, the rear frame 136, and the center frame 137 may be coupled by a fastening means such as a bolt. The lower frame 134, the front frame 135, the rear frame 136, and the center frame 137 may be integrally formed.

A plurality of second trays 200b may be disposed between the second discharge unit 130 and the supply unit 110 to be stacked up and down. The second discharge unit 130 may be formed long in the vertical direction, in which the second trays 200b are stacked vertically. The front frame 135, the rear frame 136, and the center frame 137 is formed long in the vertical direction, the second discharge unit 130 may be formed long in the vertical direction. The second discharge part 130 may be formed to be longer in the vertical direction with a length greater than the height formed by stacking the second trays 200b. The second discharge part 130 may include a plurality of third fastening grooves 133, and the third fastening grooves 133 may be formed to be spaced apart from each other in a vertical direction by a predetermined distance. The second discharge part 130 may include a plurality of second vent holes 132, and the second vent holes 132 may be formed to be spaced apart from each other by a predetermined distance in a vertical direction. The second vent holes 132 may be formed at a height corresponding to the height at which the second trays 200b are located.

4 and 5, the rack 100 may include a first packing 141 and FIG. 5 to block leakage of a temperature control fluid between the first discharge part 120 and the first tray 200a. It is further shown). The first packing 141 is interposed between the first discharge part 120 and the first tray 200a. The first packing 141 may be formed of a material having elasticity, for example, may be formed of rubber. The first packing 141 is in close contact with one surface on which the first vent hole 122 is formed in the first discharge part 120 and the first tray 200a, and thus one surface of the first discharge part 120. And it can block the leakage of the temperature control fluid between the first tray (200a). The first packing 141 may be coupled to one surface of the first discharge part 120 to surround the outside of the first vent hole 122. The first packing 141 may include a through hole having a shape and a size corresponding to the first through hole 122. The first packing 141 may be formed in a rectangular ring shape as a whole. When a plurality of first vent holes 122 are formed on one surface of the first discharge part 120, the rack 100 may include a plurality of first packings 141. The first packings 141 may be coupled to one surface of the first discharge part 120 to surround the outside of the first vent holes 122, respectively.

4 and 5, the rack 100 may include a second packing 142 and FIG. 5 to block leakage of the temperature control fluid between the second discharge unit 130 and the second tray 200b. It is further shown). The second packing 142 is interposed between the second discharge unit 130 and the second tray 200b. The second packing 142 may be formed of a material having elasticity, for example, may be formed of rubber. The second packing 142 is in close contact with one surface on which the second vent hole 132 is formed in the second discharge unit 130 and the second tray 200b, and thus one surface of the second discharge unit 130. And leakage of the temperature control fluid between the second tray 200b. The second packing 142 may be coupled to one surface of the second discharge unit 130 to surround the outside of the second vent hole 132. The second packing 142 may include a through hole having a shape and a size corresponding to the second through hole 132. The second packing 142 may be formed in a rectangular ring shape as a whole. When a plurality of second vent holes 132 are formed on one surface of the second discharge part 130, the rack 100 may include a plurality of second packings 142. The second packings 142 may be coupled to one surface of the second discharge unit 130 to surround the outside of the second vent holes 132, respectively.

4 and 5, the rack 100 further includes a first sealing frame 151 and a second sealing frame 152. One side of the first sealing frame 151 is coupled to the supply unit 110, the other side is coupled to the first discharge unit 120. One side of the second sealing frame 152 is coupled to the supply unit 110, the other side is coupled to the second discharge unit 130. The supply unit 110, the first discharge unit 120, and the second discharge unit 130 are maintained in a coupled state by the first sealing frame 151 and the second sealing frame 152. Can be. Therefore, the battery system 1 according to the present invention can improve the ease of installing or removing the rack 100. The first sealing frame 151 may be coupled to the supply part 110 and the first discharge part 120 by a fastening means such as a bolt. The second sealing frame 152 may be coupled to the supply unit 110 and the second discharge unit 130 by a fastening means such as a bolt.

4 and 5, the rack 100 further includes a first sealing member 161 and a second sealing member 162. The first sealing member 161 is interposed between the first tray 200a and the first sealing frame 151, and thus between the first tray 200a and the first sealing frame 151. It can be sealed. Accordingly, the first sealing member 161 may block the temperature control fluid from flowing between the first tray 200a and the first sealing frame 151. The first sealing member 161 may be formed of a material having elasticity, for example, may be formed of rubber. The first sealing member 161 is in close contact with the first tray 200a and the first sealing frame 151, so that the temperature control fluid is between the first tray 200a and the first sealing frame 151. You can block inflow. The first sealing member 161 may be coupled to one surface of the first sealing frame 151 facing the first tray 200a. The rack 100 may include a plurality of first sealing members 161.

The second sealing member 162 is interposed between the second tray 200b and the second sealing frame 152, and thus between the second tray 200b and the second sealing frame 152. It can be sealed. Therefore, the second sealing member 162 may block the flow of the temperature control fluid between the second tray 200b and the second sealing frame 152. The second sealing member 162 may be formed of an elastic material, for example, may be formed of rubber. The second sealing member 162 is in close contact with the second tray (200b) and the second sealing frame 152, the temperature control fluid between the second tray (200b) and the second sealing frame (152). You can block inflow. The second sealing member 162 may be coupled to one surface of the second sealing frame 152 that faces the second tray 200b. The rack 100 may include a plurality of second sealing members 162.

The battery system 1 according to the present invention has a direction in which the first tray 200a is positioned in the supply unit 110 by the first sealing member 161 and the first packing 141 (A arrow direction). Temperature control fluid to move to the first tray 200a may be guided to move to the first discharge unit 120. In addition, in the battery system 1 according to the present invention, the temperature control fluid passes through the first tray 200a by the first sealing member 161 and the first packing 141, and thus the first discharge part. Leakage may be prevented in the process of moving to 120.

The battery system 1 according to the present invention is a direction in which the second tray 200b is positioned in the supply unit 110 by the second sealing member 162 and the second packing 142 (B arrow direction). The temperature control fluid moving to the second tray 200b may be guided to move to the second discharge unit 130. In addition, in the battery system 1 according to the present invention, the temperature control fluid passes through the second tray 200b by the second sealing member 162 and the second packing 142, and thus the second discharge part. It may be prevented from leaking in the process of moving to 130.

4 to 6, the rack 100 includes a first support member 170 for supporting the first tray 200a and a second support member for supporting the second tray 200b. 180) further. The rack 100 includes a plurality of first support members 170 and a plurality of second support members 180.

The first support members 170 may include the first trays 200a such that a plurality of first trays 200a are stacked vertically between the first supply unit 110 and the first discharge unit 120. I support it. The first support members 170 are installed to be spaced apart from each other by a predetermined distance in a direction in which the first trays 200a are stacked vertically, that is, in a vertical direction. The first support members 170 are positioned between the first supply part 110 and the first discharge part 120, the first supply part 110, the first discharge part 120, and the first discharge part 120. It may be coupled to at least one of the sealing frame (151, shown in Figure 5). Therefore, the battery system 1 according to the present invention inserts the first tray 200a into a space formed above the first support member 170 as shown in FIG. 4, thereby providing the first tray 200a. It can be coupled to the rack 100. In addition, the battery system 1 according to the present invention may selectively separate any one of the first tray (200a) from the rack 100 as shown in FIG. Therefore, the battery system 1 according to the present invention may improve the ease of the operation of coupling and separating the first tray 200a with respect to the rack 100. The first support member 170 may be formed in a rectangular plate shape as a whole. The first support member 170 may be coupled to at least one of the first supply part 110, the first discharge part 120, and the first sealing frame 151 by fastening means such as a bolt. .

4 and 6, the first support members 170 include first blocking members 171 (shown in FIG. 6) for insertion into the first tray 200a, respectively. The first blocking member 171 is inserted into the upper side of the first tray (200a) located on the lower side, the temperature control fluid is introduced between the first support member 170 and the first tray (200a). You can block. That is, the first support member 170 has a function of supporting the first tray 200a located above and is inserted into the first tray 200a of the first blocking member 171 located below. It has a function to block the flow of the temperature control fluid. The first blocking member 171 may be formed in a 'b' shape as a whole, and an upper portion of the first tray 200a may be formed in a shape corresponding to the first blocking member 171. Each of the first supporting members 170 may include two first blocking members 171. The first blocking members 171 are formed to be spaced apart from each other in a direction (A arrow direction) from the supply part 110 toward the first discharge part 120. The first blocking members 171 may have a function of guiding that the first tray 200a is coupled to or separated from the rack 100.

4 to 6, the second support members 180 are installed such that a plurality of second trays 200b are stacked up and down between the first supply part 110 and the second discharge part 130. The second trays 200b are supported to be supported. The second supporting members 180 are installed to be spaced apart from each other by a predetermined distance in a direction in which the second trays 200b are stacked vertically, that is, in a vertical direction. The second support members 180 are positioned between the first supply part 110 and the second discharge part 130, and the first supply part 110, the second discharge part 130, and the second supply part 180 are located between the first and second supply parts 110 and 130. It may be coupled to at least one of the sealing frame 152 (shown in FIG. 5). Accordingly, the battery system 1 according to the present invention inserts the second tray 200b into a space formed above the second support member 180 as shown in FIG. 4, thereby providing the second tray 200b. It can be coupled to the rack 100. In addition, the battery system 1 according to the present invention may selectively separate any one of the second tray (200b) from the rack 100 as shown in FIG. Therefore, the battery system 1 according to the present invention may improve the ease of the operation of coupling and separating the second tray 200b with respect to the rack 100. The second support member 180 may be formed in a rectangular plate shape as a whole. The second support member 180 may be coupled to at least one of the first supply part 110, the second discharge part 130, and the second sealing frame 152 by a fastening means such as a bolt. .

4 and 6, the second support members 180 include second blocking members 181 (shown in FIG. 6) for insertion into the second tray 200b, respectively. The second blocking member 181 is inserted into the upper side of the second tray (200b) located on the lower side, that the temperature control fluid flows between the second support member 180 and the second tray (200b). You can block. That is, the second support member 180 has a function of supporting the second tray 200b positioned at the upper side and the second blocking member 181 is inserted into the second tray 200b positioned at the lower side. It has a function to block the flow of the temperature control fluid. The second blocking member 181 may be formed in a 'b' shape as a whole, and an upper portion of the second tray 200b may be formed in a shape corresponding to the second blocking member 181. Each of the second supporting members 180 may include two second blocking members 181. The second blocking members 181 are formed to be spaced apart from each other in a direction (B arrow direction) from the supply part 110 toward the second discharge part 130. The second blocking members 181 may have a function of guiding that the second tray 200b is coupled to or separated from the rack 100.

Hereinafter, the tray 200 will be described in detail with reference to the accompanying drawings. 7 is a schematic perspective view of a tray according to the present invention, FIG. 8 is a schematic exploded perspective view of a tray according to the present invention, and FIG. 9 is a view illustrating a connection relationship between a battery module, a control line, and a bus bar according to the present invention. 10 is a schematic perspective view of a battery system according to a modified embodiment of the present invention. The first tray 200a is a tray 200 located between the supply unit 110 and the first discharge unit 120, and the second tray 200b is the supply unit 110 and the second discharge. The tray 200 is positioned between the portions 130.

6 to 8, the tray 200 includes a battery module 210 for accommodating a battery.

The battery module 210 includes an accommodation space 211 for accommodating a battery. The accommodation space 211 is formed in a size that can accommodate at least one battery. When a plurality of batteries are accommodated in the battery module 210, the batteries are perpendicular to the direction (B arrow direction) from the first discharge part 120 toward the second discharge part 130. Arrow)) may be accommodated in the battery module 210 to be spaced apart from each other by a predetermined distance. As the batteries are spaced apart from each other, the batteries may be heated or cooled while the temperature control fluid passes between the spaces formed between the batteries.

The battery module 210 has passage holes 214 and 214 'through which the temperature control fluid passes through the side surfaces 212 and 213, respectively. The through holes 214 and 214 'and the accommodation space 211 are formed through the battery module 210. The temperature control fluid is a through hole 214 formed in one side 212 of the battery module 210, the accommodation space 211, and a through hole formed in the other side 213 of the battery module 210 ( While passing through 214 ′, the battery accommodated in the accommodation space 211 may be heated or cooled. The tray 200 is formed such that both sides corresponding to the through holes 214 and 214 'are opened.

In the case of the first tray 200a located between the supply unit 110 and the first discharge unit 120, the temperature is passed through a through hole 214 formed in one side 212 of the battery module 210. The control fluid moves from the supply part 110 to the accommodation space 211, and the temperature control fluid is supplied to the accommodation space through a through hole 214 ′ formed in the other side 213 of the battery module 210. In operation 211, the first discharge part 120 may be moved. When the first tray 200a is coupled to the rack 100, a through hole 214 formed in one side 212 of the battery module 210 is connected in communication with the second supply hole 112. The through hole 214 formed in the other side 212 of the battery module 210 may be connected to the first through hole 122.

In the case of the second tray 200b positioned between the supply unit 110 and the second discharge unit 130, the through hole 214 ′ formed in the other side 213 of the battery module 210 is formed. The temperature control fluid moves from the supply part 110 to the accommodation space 211, and the temperature control fluid is transferred to the accommodation space through a through hole 214 formed in one side 212 of the battery module 210. In operation 211, the second discharge unit 130 may be moved. When the second tray 200b is coupled to the rack 100, a passage hole 214 ′ formed in the other side 213 of the battery module 210 is connected in communication with the second supply hole 112. The through hole 214 formed in one side 213 of the battery module 210 may be connected to the second through hole 132. The battery module 210 may be formed in a rectangular parallelepiped shape as a whole. The through holes 214 and 214 'may be formed in a rectangular plate shape as a whole.

6 to 8, the tray 200 includes a lower tray 220 for supporting the battery module 210. The lower tray plate 220 forms a lower portion of the tray 200. The lower tray plate 220 includes an insertion member 221 to be inserted into the insertion groove 215 formed in the battery module 210. The insertion groove 215 is formed on the lower surface of the battery module 210, the insertion member 221 is formed to protrude on the upper surface of the lower tray 220. The battery module 210 may be coupled to the tray lower plate 220 by inserting the insertion member 221 into the insertion groove 215. The lower tray plate 220 may be formed in a rectangular plate shape as a whole.

The tray lower plate 220 may support the plurality of battery modules 210. That is, a plurality of battery modules 210 may be coupled to the lower tray 220. The battery module 210 may be coupled to the tray lower plate 220 in a direction perpendicular to both side surfaces 212 and 213 on which the through holes 214 and 214 'are formed (the direction of the arrow C). That is, the battery modules 210 in the tray lower plate 220 in a direction perpendicular to the direction (B arrow direction) from the first discharge unit 120 toward the second discharge unit 130 (B arrow direction). ) May be combined. The insertion member 221 is elongated in a direction (C arrow direction) in which the battery modules 210 are coupled to the tray lower plate 220 so that the insertion grooves 215 formed in the battery modules 210 can be inserted. Can be formed. In FIG. 9, three battery modules 210, 210 ′ and 210 ″ are coupled to the lower tray 220, but the present invention is not limited thereto, and two or more batteries may be provided on the lower tray 220. Modules 210 may be combined, it is also possible that one battery module 210 is coupled to the lower tray 220.

4, 7 and 8, the tray 200 further includes a tray front plate 230. The tray front plate 230 forms the front of the tray 200. The tray front plate 230 is coupled to the tray lower plate 220. The tray front plate 230 may be coupled to the tray lower plate 220 by a fastening means such as a bolt. The tray front plate 230 and the tray lower plate 220 may be integrally formed.

The tray front plate 230 includes a plurality of coupling members 231 and 232. The coupling members 231 and 232 are formed to protrude in both directions (A arrow direction and B arrow direction) from the tray front plate 230. Accordingly, when the tray 200 is inserted between one side of the first supply unit 110 and the first discharge unit 120, the coupling members 231 and 232 are connected to the first supply unit 110. The first discharge unit 120 is supported. The coupling members 231 and 232 may be firmly coupled to the first supply part 110 and the first discharge part 120 by a fastening means such as a bolt. Therefore, the tray 200 is fixed to the supply unit 110 and the first discharge unit 120 by the fastening means, it can be prevented from shaking by vibration or the like. In addition, when the tray 200 is inserted between the other side of the first supply unit 110 and the second discharge unit 130, the coupling members 231 and 232 are the first supply unit 110 and the It is supported by the second discharge unit 130. The coupling members 231 and 232 may be firmly coupled to the first supply part 110 and the second discharge part 130 by a fastening means such as a bolt. Therefore, the tray 200 is fixed to the supply unit 110 and the second discharge unit 130 by the fastening means, it can be prevented from shaking by vibration or the like. Fastening holes 2311, 2312 and shown in FIG. 8 may be formed in the coupling members 231 and 232 to fasten the fastening means, respectively. The tray front plate 230 and the coupling members 231 and 232 may be formed in a rectangular plate shape as a whole.

The tray front plate 230 further includes a supporting member 233 (shown in FIG. 7). The support member 233 is coupled to a battery management device (Slave Battery Management System, BMS) (not shown) for checking the current, voltage, temperature, etc. of the battery accommodated in the tray module 210. The battery management device coupled to the support member 233 may be connected to the battery management device BMS of the sub-control device 44 (shown in FIG. 3). The battery management device BMS of the sub-control device 44 (shown in FIG. 3) functions as a master battery management device Master BMS, and the battery management device BMS coupled to the support member 233 is a slave. It can function as a battery management device (Slave BMS). The support member 233 may be formed in a 'c' shape as a whole so that the battery management device BMS can be inserted therein.

The tray front plate 230 further includes a handle 234 (shown in FIG. 7). A worker or a moving device for moving the tray 200 may couple or separate the tray 200 to the rack 100 using the handle 234, and use the handle 234. The tray 200 may be transported. The handle 234 may be formed in a '' form as a whole. The handle 234 may be rotatably coupled to the tray front plate 230.

7 to 9, the tray front plate 230 has a front hole through which a bus bar 50 (shown in FIG. 9) for electrically connecting the battery modules 210 passes. 235). The front hole 235 may be formed through the tray front plate 230. Each of the battery modules 210 includes terminals 216 to be electrically connected to each other, and the terminals 216 are electrically connected to each other by connection lines 51. The battery modules 210 may be connected in series. The bus bar 50 is electrically connected to the battery module 210 located closest to the tray front plate 230. The bus bars 50 are coupled to the trays 200 coupled to the rack 100, and the battery modules 210 coupled to the rack 100 are electrically connected by electrically connecting the bus bars 50. Can be electrically connected The bus bars 50 may be electrically connected to terminal portions of the sub controller 44 (shown in FIG. 3). The busbars 50 may be connected in series.

7 and 8, the tray 200 further includes a tray back plate 240. The tray back plate 240 forms a rear portion of the tray 200. The tray rear plate 240 is coupled to the lower tray 220 to be spaced apart from the tray front plate 230 by a predetermined distance. The tray rear plate 240 may be coupled to the tray lower plate 220 by a fastening means such as a bolt. The tray rear plate 240 and the tray lower plate 220 may be integrally formed. The tray rear plate 240 does not include coupling members 231 and 232, unlike the tray front plate 230. Therefore, the tray 200 may be inserted into or separated from the rack 100 without being disturbed by the tray rear plate 240. When the tray 200 is coupled to the rack 100, the tray rear plate 240 is the first sealing member 161 (shown in FIG. 5) and the second sealing member 162 (shown in FIG. 5). May be adhered to).

7 to 9, the tray rear plate 240 has a rear hole 241 through which a bus bar 50 '(shown in FIG. 9) for electrically connecting the battery modules 210 passes. , As shown in FIG. 8). The rear hole 241 may be formed through the tray rear plate 240. The bus bar 50 ′ is electrically connected to the battery module 210 positioned closest to the tray rear plate 240. The bus bar 50 ′ passes through the tray rear plate 240 through the rear hole 241 and then extends in the direction in which the tray front plate 230 is positioned to protrude from the tray front plate 230. Can be. The bus bars 50 ′ are coupled to the trays 200 coupled to the rack 100, and the battery modules 210 coupled to the rack 100 by electrically connecting the bus bars 50 ′. ) Can be electrically connected. The bus bars 50 ′ may be electrically connected to terminal portions of the sub controller 44 (shown in FIG. 3). The busbars 50 ′ may be connected in series.

Although not shown, the tray back plate 240 further includes a handle. A worker or a moving device for moving the tray 200 may couple or separate the tray 200 to the rack 100 using a handle formed on the tray rear plate 240, and the tray rear surface. The tray 200 may be transported using a handle formed on the plate 240. The handle formed on the tray rear plate 240 may be formed in a 'c' shape as a whole. The handle formed on the tray rear plate 240 may be rotatably coupled to the tray rear plate 240.

7 and 8, the tray 200 further includes a tray upper plate 250. The tray top plate 250 forms an upper portion of the tray 200. One side of the tray upper plate 250 is coupled to the tray front plate 230, and the other side is coupled to the tray rear plate 240. The tray upper plate 250 is coupled to the tray front plate 230 and the tray rear plate 240 so as to be spaced apart from the tray lower plate 220 by a predetermined distance. The tray top plate 250 may be coupled to the tray front plate 230 and the tray rear plate 240 by fastening means such as bolts.

6 to 8, the tray top plate 250 includes a protruding member 251. The protruding member 251 may be formed to protrude upward from the tray upper plate 250. Two protruding members 251 and 251 ′ may be formed on the tray top plate 250. The protruding members 251 and 251 ′ are formed to be spaced apart from each other in a direction (B arrow direction) from the first discharge part 120 toward the second discharge part 130. One of the first blocking member 171 and the second blocking member 181 may be inserted into a space formed between the protruding members 251 and 251 ′. The protruding members 251 and 251 ′ may be in close contact with any one of the first blocking member 171 and the second blocking member 181 inserted therebetween. Accordingly, the temperature control fluid may be blocked from flowing between the first support member 170 and the tray 200 and between the second support member 180 and the tray 200. The protruding members 251 and 251 ′ may be formed to correspond to the first blocking member 171 and the second blocking member 181.

7 to 9, the protruding member 251 includes a receiving groove 2511 for receiving a control line 217 (shown in FIG. 9) connected to the battery modules 210. One side of the control line 217 is electrically connected to the control terminal 218 formed on the battery module 210, the other side is electrically connected to the battery management device (BMS) coupled to the support member 233. . The control terminal 218 is electrically connected to the batteries accommodated in the battery module 210. A portion between one side and the other side of the control line 217 is inserted into the receiving groove 2511. Accordingly, the control line 217 may be implemented so that the control line 217 is not disturbed while the tray 200 is inserted into or separated from the rack 100. The battery management device (BMS) coupled to the support member 233 may check the current, voltage, temperature, etc. of the battery accommodated in the battery module 210 through the control line 217. When the tray top plate 250 includes two protruding members 251 and 251 ′, the control line 217 is inserted into the receiving groove 2511 formed in one protruding member 251, and the other The bus bar 50 ′ may be inserted into the accommodation groove 2511 ′ formed in the protrusion 251 ′. The bus bar 50 'passes through the tray rear plate 240 through the rear hole 241 and is inserted into the receiving groove 2511' to extend in the direction in which the tray front plate 230 is located. It may protrude from the tray front plate 230.

7 to 9, an upper plate hole 252 may be formed in the tray upper plate 250. The upper plate hole 252 is formed through the tray upper plate 250. In a state where the tray upper plate 250 is positioned above the battery module 210, the terminal 216 and the control terminal 218 of the battery module 210 are connected to the tray upper plate through the upper plate hole 252. 250 may be exposed to the outside. Accordingly, as shown in FIG. 9, the terminals 216 are electrically connected to each other through the upper hole 252 while the battery modules 210, 210 ′ and 210 ″ are coupled to the tray 200. And the electrical connection of the control lines 217 to the control terminals 218 through the upper plate hole 252. Accordingly, according to the present invention The battery system 1 may improve the ease of work of connecting the battery modules 210, 210 ′ and 210 ″. The upper plate hole 252 may be formed in a rectangular plate shape as a whole.

Although not shown, protrusions may be formed on the tray top plate 250. The protrusion may be formed to protrude in a direction in which the battery module 210 is located from the bottom of the tray upper plate 250. A groove (not shown) for inserting the protrusion may be formed on an upper surface of the battery module 210. As the protrusion is inserted into the groove formed in the battery module 210, the battery module 210 may be prevented from being shaken by vibration or the like.

Referring to FIG. 8, the tray 200 includes the battery modules 210, which are disposed on the lower tray 220, the tray front plate 230, the tray rear plate 240, and the tray upper plate 250. It further comprises a tray packing 260 for close contact (210 '). The tray packing 260 may be formed of a material having elasticity, for example, may be formed of rubber. The tray packing 260 is disposed between the lower tray plate 220, the tray front plate 230, the tray rear plate 240, and the tray upper plate 250 and the battery modules 210 and 210 ′. By pressing, the temperature control fluid flows between the lower tray plate 220, the tray front plate 230, the tray rear plate 240, and the tray upper plate 250 and the battery modules 210 and 210 ′. You can block it. The tray packing 260 may include a first tray packing 261, a second tray packing 262, a third tray packing 263, a fourth tray packing 264, a fifth tray packing 265, and a sixth tray packing 260. Tray packing 266 may be included.

The first tray packing 261 is interposed between the tray front plate 230 and the battery module 210 located closest to the tray front plate 230. The first tray packing 261 is pressed to the battery module 210 located closest to the tray front plate 230 and the tray front plate 230, and thus the tray front plate 230 and the battery module. It is possible to block the flow of the temperature control fluid between (210). Therefore, the battery system 1 according to the present invention prevents the temperature control fluid from leaking between the tray front plate 230 and the battery module 210, thereby allowing the temperature control fluid to accommodate the space in which the batteries are accommodated ( You can increase the amount to move to 211). The first tray packing 261 may be formed in a 'ㅂ' shape as a whole so as not to cover the front hole 235 formed in the tray front plate 230.

The second tray packing 262 is interposed between the tray rear plate 240 and the battery module 210 ′ positioned closest to the tray rear plate 240. The second tray packing 262 is compressed to the battery module 210 'which is located closest to the tray rear plate 240 and the tray rear plate 240, thereby providing the tray rear plate 240 and the battery. The temperature control fluid may be blocked from flowing between the modules 210 '. Therefore, the battery system 1 according to the present invention prevents the temperature control fluid from leaking between the tray rear plate 240 and the battery module 210 ', so that the temperature control fluid accommodates the batteries. You can increase the amount to go to (211). The second tray packing 262 may be formed in a 'ㅂ' shape as a whole so as not to cover the rear hole 241 formed in the tray rear plate 240.

The third tray packing 263, the fourth tray packing 264, the fifth tray packing 265, and the sixth tray packing 266 may include the tray top plate 250 and the battery modules 210. , 210 '). The third tray packing 263, the fourth tray packing 264, the fifth tray packing 265, and the sixth tray packing 266 may have a bottom surface of the tray upper plate 250 and the battery modules. By pressing the upper surface of the (210, 210 '), it is possible to block the flow of the temperature control fluid between the tray top plate 250 and the battery modules (210, 210'). Accordingly, the battery system 1 according to the present invention prevents the temperature control fluid from leaking between the tray upper plate 250 and the battery modules 210 and 210 ', thereby preventing the temperature control fluid from receiving the batteries. The amount of movement to the accommodation space 211 can be increased. The third tray packing 263, the fourth tray packing 264, the fifth tray packing 265, and the sixth tray packing 266 may each have a rectangular plate shape, and the tray top plate ( 250) may be combined to form a rectangular ring as a whole.

Referring to FIG. 8, the tray 200 further includes a module packing 270 for bringing the battery modules 210 and 210 'into close contact with each other. The module packing 270 may be formed of a material having elasticity, for example, may be formed of rubber. The module packing 270 may be interposed between the battery modules 210 and 210 ′, thereby preventing the temperature control fluid from flowing into the battery modules 210 and 210 ′. Accordingly, the battery system 1 according to the present invention prevents the temperature control fluid from leaking between the battery modules 210 and 210 ', thereby moving the temperature control fluid to the accommodation space 211 in which the batteries are accommodated. You can increase the amount you say. The tray 200 may include a plurality of module packings 270. When the number of battery modules 210 coupled to one tray 200 is N (N is an integer greater than 1), the tray 200 includes (N-1) module packings 270. can do. The module packings 270 may be interposed between the battery modules 210. The module packing 270 may be formed in a rectangular ring shape as a whole.

The tray lower plate 220, the tray front plate 230, the tray rear plate 240, and the tray upper plate 250 may be manufactured by bending a material formed in a plate shape. Although not shown, the tray front plate 230 and the tray top plate 250 may be combined using a cicada ring. To this end, a cicada ring may be coupled to any one of the tray front plate 230 and the tray top plate 250, and a locking member to which the cicada ring is caught may be formed. Although not shown, the tray back plate 240 and the tray top plate 250 may be coupled using a cicada ring. To this end, a cicada ring may be coupled to any one of the tray rear plate 240 and the tray top plate 250, and a locking member to which the cicada ring is caught may be formed.

The battery system 1 according to the present invention may include a plurality of racks 100. The racks 100 each include the first supply part 110, the first discharge part 120, and the second discharge part 130. The racks 100 are disposed adjacent to each other. That is, any one of the first discharge unit 120 and the second discharge unit 130 of the other rack 100 is located next to the second discharge unit 130 of any one rack 100 do. Therefore, in the battery system 1 according to the present invention, since each of the racks 100 is independent, it is possible to independently install and replace each of the racks 100.

Referring to FIG. 10, in the battery system 1 according to the modified embodiment of the present invention, racks 100 and 100 ′ installed adjacent to each other may share one discharge part. That is, the second discharge unit 130 of the rack 100 may function as the first discharge unit 120 of the other rack 100 ′ installed adjacent to the rack 100. In this case, vents are formed at both sides of the outlets shared by the adjacent racks 100 and 100 'so that the temperature control fluid controlling the temperature of the battery can be introduced from the trays 200 located at both sides. Can be. Therefore, the battery system 1 according to the modified embodiment of the present invention can reduce the space occupied by the rack 100 compared to the above-described embodiment, and thus can be implemented to install more batteries. .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It will be clear to those who have knowledge.

DESCRIPTION OF SYMBOLS 1 Battery system 10 First vent 20 Second vent 30 Air conditioning apparatus
100: rack 110: first supply part 120: first discharge part 130: second discharge part
141: first packing 142: second packing 151: first sealed frame
152: second sealing frame 161: first sealing member 162: second sealing member
170: first support member 180: second support member 200: tray 210: battery module
220: tray lower plate 230: tray front plate 240: tray rear plate
250: tray top plate 260: tray packing 270: module packing

Claims (19)

A rack including left and right symmetrically coupled first and second trays for accommodating at least one battery;
The rack system includes a first discharge portion and a second discharge portion for dispersing left and right the temperature control fluid supplied between the first tray and the second tray. The method of claim 1,
The rack includes a supply located between the first tray and the second tray;
The supply part is formed so that both sides toward the first tray and the second tray is open,
The battery system, characterized in that the first tray and the second tray is located between the first discharge unit and the second discharge unit. The method of claim 1,
A first vent for supplying the temperature control fluid to the rack, a second vent for discharging the temperature control fluid from the rack, and an air conditioner connected to the first vent and the second vent; ;
The air conditioning apparatus includes a fan for moving the temperature control fluid to the first vent, the rack, and the second vent, and a temperature control for heating or cooling the temperature control fluid supplied from the second vent. A battery system comprising a unit. The method of claim 2,
A first vent for supplying the thermostatic fluid to the rack, and a second vent for discharging the thermostatic fluid from the rack;
The first vent is installed below the rack;
The second vent is installed to be located above the rack;
The supply part is formed such that a lower part is opened to allow a temperature control fluid to flow from the first vent, and an upper part is closed;
The first discharge portion and the second discharge portion is a battery system, characterized in that the lower portion is formed to be closed, the upper portion is formed to open so that the temperature control fluid is discharged to the second vent. The method according to claim 1 or 2,
A first vent for supplying the thermostatic fluid to the rack, and a second vent for discharging the thermostatic fluid from the rack;
The first discharge part includes a first vent hole formed on one surface facing the first tray so that the temperature regulating fluid is introduced, and a first discharge hole for discharging the temperature regulating fluid to the second vent;
The second discharge portion includes a second vent formed on one surface facing the second tray so that the temperature control fluid is introduced, and a second discharge hole for discharging the temperature control fluid to the second vent. Battery system. The rack of claim 1, wherein the rack is
A first packing interposed between the first discharge part and the first tray to prevent leakage of the temperature control fluid between the first discharge part and the first tray, and
And a second packing interposed between the second discharge part and the second tray to prevent leakage of the temperature control fluid between the second discharge part and the second tray. The method of claim 2,
A first vent for supplying the thermostatic fluid to the rack, and a second vent for discharging the thermostatic fluid from the rack;
A plurality of racks are installed between the first vent and the second vent,
The supply part of each of the racks is connected in communication with the first vent so that the temperature control fluid is supplied from the first vent,
And a first discharge part and a second discharge part of each of the racks are in communication with the second vent so that the temperature control fluid is discharged to the second vent. The rack of claim 2, wherein the rack is
A first sealing frame having one side coupled to the supply part and the other side coupled to the first discharge part;
A first sealing member interposed between the first sealing frame and the first tray to seal between the first tray and the first sealing frame located between the supply part and the first discharge part;
A second sealing frame having one side coupled to the supply unit and the other side coupled to the second discharge unit; And
And a second sealing member interposed between the second sealing frame and the second tray to seal between the second tray and the second sealing frame located between the supply part and the second discharge part. Battery system. The method of claim 2,
A plurality of first trays are disposed to be stacked vertically between the supply part and the first discharge part;
A battery system, characterized in that a plurality of second trays are installed to be stacked up and down between the supply portion and the second discharge portion. The rack of claim 2, wherein the rack is
A plurality of first support members for supporting the first trays such that a plurality of first trays are stacked between the supply part and the first discharge part so as to be stacked up and down; And
And a plurality of second support members for supporting the second trays such that a plurality of second trays are stacked up and down between the supply part and the second discharge part. The method of claim 10,
The first support members each include a first blocking member for inserting into the first tray, the first blocking member to block the flow of the temperature control fluid between the first support member and the first tray;
Each of the second supporting members includes a second blocking member for inserting into the second tray, and the second blocking member prevents a temperature control fluid from flowing between the second supporting member and the second tray. Characterized by a battery system. A rack including a first discharge part and a second discharge part for discharging the temperature control fluid of the battery, and a supply part positioned between the first discharge part and the second discharge part; And
And a plurality of trays coupled to the rack to be positioned between one side of the supply unit and the first discharge unit and between the other side of the supply unit and the second discharge unit.
The supply unit is a battery system, characterized in that the both sides are opened so that the temperature control fluid is moved to the tray located on both sides. The method of claim 12,
The tray includes a battery module having a receiving space for accommodating a battery, and a tray lower plate for supporting a plurality of battery modules;
Each of the battery modules has through holes formed on both sides thereof for the temperature control fluid to pass therethrough.
The battery system, characterized in that the battery module is coupled to the lower plate in a direction perpendicular to both sides of the battery module is formed through the through holes. The method of claim 12,
The tray includes a battery module including a battery module for accommodating a battery, and an insertion member for inserting into an insertion groove formed in the battery module. The method of claim 12, wherein the tray is
A tray lower plate for supporting a plurality of battery modules containing batteries;
A tray front plate coupled to the lower tray plate;
A tray rear plate coupled to the lower tray plate to be spaced apart from the tray front plate;
One side is coupled to the tray front plate, the other side battery system comprising a tray top plate coupled to the tray rear plate. The method of claim 15, wherein the tray
A tray packing for blocking a temperature control fluid from flowing between the tray front plate, the tray lower plate, the tray rear plate, and the tray upper plate and the battery modules; And
And a module packing interposed between the battery modules to block the temperature control fluid from flowing between the battery modules. 16. The method of claim 15,
The tray top plate includes a protruding member having a receiving groove for receiving a control line connected to the battery module, and an upper plate hole through which the control line passes so that the control line connected to the battery module is received in the receiving groove;
The tray front plate includes a front hole through which a busbar for electrically connecting the battery modules passes;
The tray back plate includes a back hole for passing the bus bar. 16. The method of claim 15,
The tray is inserted between one side of the supply part and the first discharge part and between the other side of the supply part and the second discharge part;
The tray front plate includes a plurality of coupling members for coupling to any one of the first discharge unit and the second discharge unit and the supply unit. The method of claim 12,
A plurality of trays are respectively stacked up and down between one side of the supply unit and the first discharge unit, and between the other side of the supply unit and the second discharge unit;
Each of the trays includes a plurality of battery modules for accommodating batteries, wherein the battery modules are coupled in a direction perpendicular to a direction from the first discharge portion toward the second discharge portion.

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