KR101318391B1 - Sodium-sulfur rechargeable battery module - Google Patents

Abstract

More simple and easy to arrange the unit cells in the container, and to facilitate the easy re-installation of the unit cell, a container in which a plurality of sodium sulfur cells are housed, a cover installed on the open top of the container, the The present invention provides a sodium sulfur battery module including a battery socket that is accommodated in a container and has a plurality of accommodating grooves arranged at intervals on a front surface thereof.

Description

[0001] SODIUM-SULFUR RECHARGEABLE BATTERY MODULE [0002]

The present invention relates to a sodium-sulfur battery module. In more detail, the present invention relates to a sodium sulfur battery module, which makes it easier to mount a single cell inside the module.

Generally, a sodium-sulfur battery is developed as a large-capacity power storage battery because of its high energy density, charge / discharge efficiency, self-discharge, and irregular charge / discharge characteristics.

Sodium sulfur batteries use sodium alumina (Na) as the cathode, sulfur (S) as the anode, and beta-alumina ceramics of the solid electrolyte having sodium ion conductivity as the electrolyte. Since beta-alumina has a property of passing only sodium ions, sodium ions are charged / discharged by moving between the cathode and the anode through the beta-alumina.

The sodium sulfur battery includes an anode tube enclosing an electrolyte tube and an electrolyte tube. The inside of the electrolyte tube is filled with sodium, and sulfur and carbon felt are placed between the electrolyte tube and the positive electrode container.

A plurality of the sodium sulfur cells are accommodated in one container and integrated, thereby forming a large capacity sodium sulfur battery module.

In the past, a filler such as sand was used to fix a plurality of sodium sulfur batteries in a container. In other words, the electrically connected unit cells are disposed in a container, and the unit cells are fixed by filling a filling thread between the unit cells so that the unit cells do not swing.

By the way, the fixing structure using the filling yarn has a disadvantage that takes a lot of time to assemble the battery module. In particular, when after-care is required, such as replacing a single cell, it is difficult to re-install a new cell between charging companies, so that after-care is difficult and not properly performed, such as having to remove and re-install the whole.

Therefore, the development of a new technology for fixing a single cell in the sodium sulfur battery module is a long situation.

Accordingly, the present invention provides a sodium sulfur battery module that enables simpler and easier arrangement of unit cells in a container.

In addition, the reinstallation of the unit cell can be made easily and easily provides a convenient sodium sulfur battery module for post-management.

To this end, the battery module includes a container in which a plurality of sodium sulfur batteries are accommodated, a cover installed at an open upper end of the container, and a plurality of receiving grooves stored in the container and having the sodium sulfur battery inserted therein at an interval. It may comprise an array of battery sockets.

The battery module may further include an insulating sheet inserted into the receiving groove of the battery socket and disposed between the inner surface of the receiving groove and the sodium sulfur battery.

The battery socket may have a structure in which the receiving groove is formed from the top to the bottom and the bottom thereof is blocked.

The battery socket may have a structure in which the receiving groove penetrates from the top to the bottom.

The battery socket may be formed at a height corresponding to the length of the sodium sulfur battery.

The battery socket may be made of a plastic material.

The insulating sheet may be made of mica or silicon.

As described above, according to the present embodiment, the unit cell can be easily mounted in the container of the battery module, thereby shortening the process time required for assembling the battery module and reducing the workload.

In addition, the post-management of the battery module can be made easily and efficiently, maximizing the life of the battery module, it is possible to more secure the competitiveness of the product.

1 is an exploded perspective view showing the configuration of a sodium sulfur battery module according to the present embodiment.
2 is a side sectional view of the sodium sulfur battery module according to the present embodiment.
3 is a side cross-sectional view of a sodium sulfur battery module according to another embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It will be apparent to those skilled in the art that the embodiments described below may be modified in various forms without departing from the spirit and scope of the present invention, .

The drawings are schematic and illustrate that they are not drawn to scale. The relative dimensions and ratios of the parts in the figures are shown exaggerated or reduced in size for clarity and convenience in the figures, and any dimensions are merely illustrative and not restrictive.

1 shows the configuration of the sodium sulfur battery module according to the present embodiment, Figure 2 shows a cross-sectional view of the assembled state of the sodium sulfur battery module.

As shown, the sodium sulfur battery module 10 (hereinafter referred to as a battery module for convenience of explanation) is a plurality of sodium sulfur battery (hereinafter referred to as a unit cell for convenience of description) in a high-capacity integrated, A container 14 in which the plurality of unit cells 12 is housed, and a cover 16 covering the open top of the container 14 to seal the inside thereof.

The container 14 may be formed of a metal material and a heat insulating material may be installed on the outer surface. The heat insulator is made of a material having heat resistance to insulate the battery module.

The cover 16 may also be formed of a metal material, such as the container 14, the heat insulating material of the heat-resistant material for insulation can be installed on the outer surface. For example, rock wool, vermiculite, perlite, carbon fiber, graphite fiber, and the like may be used, and are not particularly limited.

The container 14 and the cover 16 may be formed of a vacuum structure in addition to the heat insulating material or further include a vacuum structure in addition to the heat insulating material, and may have various heat insulating structures in addition to the structure.

Here, the battery module further includes a battery socket 20 for fixing the unit cell 12 in the container 14.

Accordingly, each unit cell 12 is arranged in a shape set in the container 14 through the battery socket 20, and does not flow in the container 14 to maintain the arranged state.

In the present embodiment, the battery socket 20 is accommodated in the container 14 and has a structure in which a plurality of receiving grooves 22 into which the sodium sulfur battery is inserted are arranged at intervals. Accordingly, the plurality of unit cells 12 are inserted into the receiving grooves 22 formed on the upper surface of the battery socket 20 housed in the container 14, thereby completing the arrangement and the storing in the container 14. Alternatively, the unit cell 12 is inserted into the receiving groove 22 formed on the upper surface of the battery socket 20, and the battery socket 20 in which the unit cell 12 is arranged and fixed in the container 14 is merely inserted into the container 14. By attaching, the unit cell 12 can be arranged and stored in the container 14.

As such, by storing the battery socket 20 in the container 14, it is possible to reduce the trouble of arranging and fixing the unit cells 12 in the container 14, and minimize the assembly time and the process of the battery module to a minimum. You can do it.

In addition, when one side battery 12 needs to be replaced for battery module follow-up management, it is necessary to take out the unit cell 12 from the receiving groove 22 of the battery socket 20 and insert the new unit cell 12 again. You can work conveniently. That is, the battery socket 20 has a structure in which the accommodating groove 22 is formed in a predetermined size, and when the unit cell 12 is removed from the accommodating groove 22, the accommodating groove 22 is empty. The area for the new unit cell 12 is to be secured. Therefore, the new unit cell 12 may be easily installed because the new unit cell 12 is inserted into the empty accommodating groove 22.

The battery socket 20 may be made of a plastic material. In this embodiment, the battery socket may be made of a fiber reinforced plastic (FRP) material having rigidity, insulation, and heat insulation. Accordingly, the battery socket 20 insulates the unit cell 12, insulates heat generated, and continuously supports the unit cell 12 with rigidity to prevent the flow of the unit cell 12 against external impact. You can do it.

In addition, the battery module further includes an insulating sheet 30 inserted into the receiving groove 22 of the battery socket 20 and disposed between the inner surface of the receiving groove 22 and the sodium sulfur battery. The insulating sheet 30 may be made of, for example, a mica material or a silicon material. The insulating sheet 30 may be installed to surround the unit cell in the form of a sheet, or may have a cylindrical shape so that the unit cell may be inserted.

The insulating sheet 30 is installed in contact with the receiving groove 22 and the unit cell 12 of the battery socket 20 surrounding the unit cell 12. The insulating sheet 30 insulates between the single cell 12 and the battery socket 20 and protects the battery socket 20 from the high heat generated in the single cell 12.

Here, the battery socket 20 is formed in a size and shape corresponding to the inside of the container 14, when the battery socket 20 is inserted into the container 14, the outer surface is in contact with the inner surface of the container 14 and does not flow in the container 14. It is supposed to be. In this embodiment, the container 14 has a rectangular shape, and the battery socket 20 also has a rectangular shape so as to correspond to the container 14. In addition, the accommodating groove 22 formed in the battery socket 20 may be formed in a shape or size such that the single cell 12 or the insulating sheet 30 and the single cell 12 can be sufficiently inserted. It is not specifically limited.

The height of the accommodating groove 22 formed in the battery socket 20 or the battery socket 20 may be less than or equal to the length of the unit cell 12. The unit cell 12 is provided with a terminal on the upper end of the container 14 to be electrically connected to each other between the terminals of the upper end. Accordingly, the height of the battery socket 20 or the height of the accommodating groove 22 into which the unit cell 12 is inserted is smaller than the length of the unit cell 12. Therefore, the unit cell 12 is exposed deeply above the upper end of the battery socket 20 without deeply entering the accommodating groove 22 of the battery socket 20, thereby making it easier to connect the upper terminals of the unit cell 12. It becomes possible.

In addition, as shown in Figure 2, each receiving groove 22 formed in the upper surface of the battery socket 20 of the present embodiment is formed from the top to the bottom and the bottom is a closed structure. That is, the accommodating groove 22 has a groove structure in which only an upper portion thereof is opened, and a lower end of the unit cell 12 is disposed at a lower end of the accommodating groove 22.

On the other hand, Figure 3 shows another embodiment of a battery module.

In the following description, the battery module of the present embodiment has the same configuration as the other embodiments except for the structure of the receiving groove 26 formed in the battery socket 24. The same reference numerals are used for the same configuration, and detailed description thereof will be omitted.

In this embodiment, the battery socket 24 has a structure in which the receiving groove 26 passes through the battery socket 24 from the top to the bottom thereof.

As shown in FIG. 3, when the unit cell 12 is inserted into the accommodating groove 26 of the battery socket 24, the lower end of the unit cell 12 is placed on the bottom surface of the container 14. do. In such a structure, it is easy to manufacture the battery socket 24, it is possible to transfer the heat directly to the unit cell 12 by installing a heater or the like on the bottom surface of the container 14, which is advantageous for thermal management of the unit cell 12 Has an advantage.

While the illustrative embodiments of the present invention have been shown and described, various modifications and alternative embodiments may be made by those skilled in the art. Such variations and other embodiments will be considered and included in the appended claims, all without departing from the true spirit and scope of the invention.

10: Battery module 12: Single cell
14 container 16: cover
20,24: Battery socket 22,26: receiving groove
30: insulation sheet

Claims (7)

A container in which a plurality of sodium sulfur cells are accommodated,
A cover provided at an open top of the container,
It is housed in the container and forms a shape corresponding to the sodium sulfur battery on the front surface, and the plurality of receiving grooves into which each sodium sulfur battery is inserted are arranged at intervals, and the plurality of sodium sulfur batteries are inserted into and fixed to the respective receiving grooves. Battery socket
Sodium sulfur battery module comprising a. The method of claim 1,
Sodium sulfur battery module further comprises an insulating sheet inserted into the receiving groove of the battery socket disposed between the inner surface of the receiving groove and the sodium sulfur battery. The method of claim 1,
The battery socket is a sodium sulfur battery module formed to a height corresponding to the length of the sodium sulfur battery. The method of claim 1,
The battery socket is a sodium sulfur battery module made of a plastic material. 3. The method of claim 2,
The insulating sheet is a sodium sulfur battery module made of mica or silicon material. 6. The method according to any one of claims 1 to 5,
The battery socket is a sodium sulfur battery module of the structure in which the receiving groove is formed from the top to the bottom is blocked. 6. The method according to any one of claims 1 to 5,
The battery socket is a sodium sulfur battery module structure of the receiving groove is formed penetrating from the top to the bottom.

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