KR20130096430A - Cooling apparatus for battery - Google Patents

Abstract

PURPOSE: A cooling apparatus for a bulk energy storage system is provided to be excellent in the cooling efficiency and to be able to evenly cool each battery cell without large variation of cooling. CONSTITUTION: A cooling apparatus for a bulk energy storage system includes a duct (10) and a refrigerant dispersion supply board (20). The duct is installed in a form of surrounding the rear part of the bulk energy storage system in which a battery pack (5) is arranged. The refrigerant flows inside. The refrigerant is flowed in from the top or bottom. The refrigerant dispersion supply board is formed with multiple refrigerant flowing holes (21) in which the refrigerant flows. The refrigerant flows to a cooling channel of the battery pack through the refrigerant flowing holes. The cross section of the refrigerant flowing hole becomes smaller as closer to the inflow direction of the refrigerant supplied through the duct.

Description

Cooling device for large capacity power storage device {COOLING APPARATUS FOR BATTERY}

The present invention relates to a cooling device for cooling a large capacity power storage device, such as a battery of a cell assembly type consisting of a plurality of battery cells.

Secondary batteries, unlike primary batteries, can be charged and discharged in general, and are used in advanced electric and electronic fields such as hybrid cars, notebook computers, digital cameras, and cellular phones.

Examples of the secondary battery include nickel-cadmium batteries, nickel-metal hydride batteries, nickel-hydrogen batteries, lithium batteries, and the like.

The lithium secondary battery is used as a power source for portable electronic devices with an operating voltage of 3.6 V or more, or used in high-power hybrid vehicles by connecting several to several tens in series, and used in nickel-cadmium batteries or nickel-metal hydride batteries. Compared with the three times higher operating voltage and excellent energy density characteristics per unit weight, the demand is increasing.

Lithium secondary batteries can be manufactured in various forms, and typical shapes include a cylinder type and a prismatic type.

In recent years, a lithium polymer battery has been manufactured in a pouch type having flexibility and its shape is relatively free.

In addition, the lithium polymer battery has excellent safety and light weight, which is advantageous in slimming and reducing the weight of a portable electronic device.

Among the secondary batteries, there are a type of cell assembly in which a plurality of battery cells 1 are assembled, and this type has a feature capable of high power.

As is the case with conventional batteries, batteries in cell assembly form have a greater impact on battery efficiency.

As a result, various technologies for increasing the cooling efficiency of the battery, such as Korean Patent Application Publication No. 2011-0044387 and Korean Patent Application Publication No. 2010-0012018, are proposed.

Specifically, Figure 1 is a schematic cross-sectional view showing a conventional cell assembly type secondary battery.

 As shown in FIG. 1, in the conventional cell assembly type secondary battery battery, each battery cell 1 is disposed at an interval so that a space between the battery cell 1 and the battery cell 1 (usually 'cooling channel 2) And a plurality of battery cells 1 are located in the case. (A recent cell assembly type secondary battery battery includes a plurality of battery packs arranged while forming cooling channels. Form)

In addition, the case is provided with an air inlet 3a and an air outlet 4a through which air for cooling is introduced, and a fan is provided to allow air for cooling to enter the air inlet and be discharged to the air outlet.

However, simply by allowing the air for cooling to flow into the air inlet (3a) and then to the air outlet (4a) can not increase the cooling efficiency, and even cooling effect of the battery cell (1) can not be obtained various cooling structure Was drafted.

However, it is not intended for a large power storage device, but only for a small power storage device as shown in FIG.

The large-capacity power storage device has a structure in which a plurality of battery packs 5 are arranged not only in a plurality of left and right as shown in FIG. 2, but also in a plurality of up and down arrangements to form a plurality of stages.

Conventional high-capacity power storage device cooling device was simply configured to operate the fan in the rear or front of the large-capacity power storage device to allow air to pass through the cooling channel of the battery pack (5).

This structure has a problem that the cooling efficiency does not meet the expectations and that the deviation of the cooling is greatly generated according to the point where the battery pack 5 is located.

Korea Patent Publication No. 2011-0044387 Korean Patent Publication No. 2010-0012018

The present invention is to solve the above problems, and more particularly, to provide a cooling device for a large capacity power storage device that can cool each battery cell evenly without a great variation of cooling efficiency and cooling. There is this.

In the present invention, the rear of the large-capacity power storage device is to be wrapped in a duct, the refrigerant flows through the duct so that the refrigerant via the cooling channel provided in each battery pack, the farther from the inflow direction of the refrigerant By placing a refrigerant distribution supply plate which allows the refrigerant to flow into the cooling channel more smoothly, not only the cooling efficiency is excellent but also the cooling of each battery cell evenly without large deviation of cooling.

The cooling device for a high-capacity battery storage device of the present invention includes a large-capacity power storage device in which a plurality of battery cells are arranged while forming a cooling channel, and the battery packs are arranged left and right as well as arranged up and down. It is a chiller for.

In addition, it is installed in the form of surrounding the rear of the power storage device and the inside of the refrigerant flows but has a duct that the refrigerant flows from the upper or lower flows.

In addition, a plurality of coolant flow holes through which the coolant flows are formed, and are positioned in such a way as to block the rear of the power storage device so that the coolant flows through the coolant flow holes to the cooling channels of the battery packs. The holes are formed in the upper, lower, left, and right sides corresponding to the respective cooling channels formed in the respective battery packs, and the closer to the inflow direction of the coolant supplied through the duct, the coolant dispersion supply plate having a smaller cross-sectional area of the coolant flow hole is formed. Have

Cooling device for a large-capacity power storage device of the present invention, because the form of the duct is wrapped around the rear of the large-capacity power storage device does not cause the loss of the refrigerant, the cooling channel is provided in each of the battery pack refrigerant supplied through the duct In the case of passing through the evenly, all of the battery cells which are components of the battery packs located above and below are evenly cooled and have excellent cooling efficiency.

In addition, the intermediate point between the upper end and the lower end of each refrigerant flow hole may be formed to correspond to the intermediate point between the upper end and the lower end of the corresponding cooling channel, in which case the cooling efficiency is more excellent.

1 is a schematic diagram illustrating a cooling apparatus of a conventional small power storage device (cell assembly type secondary battery battery).
Figure 2 is a schematic diagram for explaining a conventional cooling device for a large capacity power storage device
Figure 3 is a schematic diagram for explaining the cooling device for a large-capacity power storage device of the present invention
A: Isometric view
B: front view
FIG. 4 is a cross-sectional view taken along line AA of FIG. 3 for explaining a refrigerant dispersion supply plate, which is a component of the present invention, in which cross-sectional areas of the refrigerant flow holes are adjusted differently by adjusting the length of the refrigerant flow holes. FIG.
FIG. 5 is a cross-sectional view taken along line AA of FIG. 3 for explaining a refrigerant dispersion supply plate that is a component of the present invention, and the cross-sectional areas of the refrigerant flow holes are differently controlled by adjusting the width of the refrigerant flow holes, respectively, and an intermediate point between the upper end and the lower end of the refrigerant flow hole. Schematic diagram in the case where it is to correspond to the intermediate point between the upper end and the lower end of the cooling channel

Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

It is to be understood, however, that the appended drawings illustrate only typical embodiments of the present invention and are not to be considered as limiting the scope of the invention.

The present invention provides a large capacity power storage device in which a plurality of battery cells 1 are arranged while forming a cooling channel 2 and are arranged not only in left and right but also in up and down. It relates to a cooling structure.

However, the present invention is not only excellent in cooling efficiency, but also has an object to allow cooling of each battery cell evenly without a large variation in cooling.

To this end, the present invention supplies a refrigerant (air or gas for cooling) to the rear of the large-capacity power storage device through the duct 10 so that the cooling is made while the refrigerant flows in front of the large-capacity power storage device.

That is, the coolant supplied through the duct 10 is cooled through the cooling channel 2 between the battery cell and the battery cell, which are components of the battery pack 5.

However, if a loss occurs in a specific portion of the supplied coolant, the coolant cannot flow evenly to the cooling channel 2, and thus, even cooling is not achieved.

For this reason, in the present invention, the duct 10 is installed in a form surrounding the rear of the large-capacity power storage device.

By the way, since the battery pack 5 is located in an upright position, it is preferable to allow the refrigerant to flow into the inside of the duct 10 when the cooling efficiency is considered, but to allow the refrigerant to flow from the upper or lower portion.

In order to prevent the loss of the refrigerant, an additional configuration is required in addition to the above configuration.

That is, since the battery pack 5 is stacked up and down, but stacked on the shelf 6 while forming a stage, there is a need to block the space between the shelf and the shelf.

Since the space between the shelf and the shelf has little resistance to the flow of the refrigerant, when the space is left, the refrigerant does not pass through the cooling channel 2 smoothly, and a large variation in cooling occurs.

For this reason, the present invention includes a refrigerant dispersion supply plate 20 positioned to block the rear of the power storage device, and the refrigerant dispersion supply plate 20 includes a plurality of refrigerant flow holes 21 through which refrigerant flows. Formed.

That is, the refrigerant flows to the cooling channel 2 of the battery pack 5 through the refrigerant flow hole 21.

Since the refrigerant must pass through each cooling channel 2, each refrigerant flow hole 21 is formed in the upper, lower, left, and right sides corresponding to each cooling channel 2 formed in each battery pack 5. It is.

That is, one refrigerant flow hole 21 corresponds to one cooling channel 2.

However, even if the cross-sectional area of the refrigerant flow hole 21 is the same, it is difficult to obtain an even cooling effect.

The amount of coolant flowing into the coolant flow hole 21 increases as the coolant flow hole 21 near the inflow direction of the coolant supplied through the duct 10 increases. Because it is less.

This leads to the result that the deviation of the cooling occurs even if the refrigerant passes through all of the cooling channels 2.

For this reason, each of the refrigerant flow holes 21 formed in the refrigerant dispersion supply plate 20 has a smaller cross-sectional area as it approaches the inflow direction of the refrigerant supplied through the duct 10.

That is, the closer to the inflow direction of the refrigerant, the greater the amount of refrigerant flowing into the refrigerant flow hole 21 and the speed through the cooling channel may be faster, so the closer the inflow direction of the refrigerant, the smaller the cross-sectional area of the refrigerant flow hole 21 is. As a result, the flow rate of the refrigerant is reduced, which slows down the cooling channel, resulting in the same flow rate of the refrigerant in all cooling channels.

The form of adjusting the cross-sectional area of the refrigerant flow hole 21 has a form of adjusting the length (up, down) of the refrigerant flow hole 21 by lengthening or shortening it.

That is, the coolant flow hole 21 is to shorten the length of the up and down as the closer to the inflow direction of the coolant supplied through the duct (10).

As another form, there is a form in which the width (distance from the left side to the right side) of the refrigerant flow hole 21 is lengthened or shortened to be adjusted.

That is, the coolant flow hole 21 is to shorten the width of the left, right as the closer to the inflow direction of the refrigerant supplied through the duct (10).

In consideration of the even cooling, it is preferable that the cross-sectional area of the refrigerant flow hole 21 is realized by adjusting the width of the refrigerant flow hole 21.

This is because, when the cross-sectional area of the refrigerant flow hole 21 is adjusted through the upper and lower lengths of the refrigerant flow hole 21, the diffusion of the refrigerant flowing through the refrigerant in the cooling channel 2 is relatively poor. (As the refrigerant spreads widely through any one cooling channel, the more it cannot pass through, the cooling deviation occurs within one cooling channel.)

Of course, if the large-capacity power storage device is very large, it may be difficult to obtain an even cooling effect only by adjusting the width of the refrigerant flow hole 21.

In this case, it is preferable to implement a form in which the shape of adjusting the width of the refrigerant flow hole 21 and the shape of adjusting the length of the refrigerant flow hole 21 are merged.

In the merged form in which the two or two forms of controlling the cross-sectional area of the refrigerant flow hole 21 are applied, whether the intermediate point between the upper end and the lower end of the refrigerant flow hole 21 corresponds to which portion of the cooling channel. It is important.

In consideration of the object of the present invention, the intermediate point between the upper end and the lower end of each refrigerant flow hole 21 (the intermediate point of the length of the refrigerant flow hole 21) is located at the intermediate point between the upper end and the lower end of the corresponding cooling channel 2. It is good to make it correspond.

1. Battery Cell
2. Cooling Channel
3a. Air inlet
4a. Air outlet
5. Battery Pack
6. Lathe
10. Duct
20. Refrigerant Dispersion Supply Plate
21. Refrigerant flow hole

Claims (4)

A plurality of battery cells are arranged while forming a cooling channel, and the battery packs are arranged not only to the left and to the right but also to surround the rear of the large-capacity power storage device arranged up and down. A duct which is configured to flow but the refrigerant is introduced from the top or the bottom to flow; And
A plurality of coolant flow holes through which the coolant flows is formed, and the coolant flow holes are positioned to block the rear of the power storage device so that the coolant flows to the cooling channel of the battery pack through the coolant flow hole. It is formed in the upper, lower, left, right corresponding to each cooling channel formed in each battery pack, and the closer to the inflow direction of the refrigerant supplied through the duct refrigerant dispersion supply plate formed with a smaller cross-sectional area of the refrigerant flow hole; Cooling device for a large-capacity power storage device configured by.
The method of claim 1,
The coolant flow hole is a shorter up, down length as the closer to the inflow direction of the refrigerant supplied through the duct, the cooling device for a large capacity power storage device.
The method of claim 1,
The coolant flow hole is a cooling device for a large-capacity power storage device, the shorter the width of the left and right, the closer to the inflow direction of the refrigerant supplied through the duct.
4. The method according to claim 2 or 3,
And an intermediate point between the upper end and the lower end of each refrigerant flow hole corresponds to an intermediate point between the upper end and the lower end of the corresponding cooling channel.

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