KR20220076662A - Electric energy storage moulde - Google Patents

Abstract

The present invention relates to an electric energy storage and release module, the present invention relates to a plurality of supports; Pouch-type charging/discharging cells arranged in a line between the supports, each having a negative terminal on one side and a positive terminal on the other side, connected in series; a fastening unit for pressing and fixing the pouch-type charging/discharging cells by fastening the supports; and a pair of plate-type terminals provided between two pouch-type charge/discharge cells adjacent to each other of the pouch-type charge/discharge cells and are in contact with each other. According to the present invention, it not only reduces the volume and weight, but also efficiently discharges the heat generated inside, and replaces the malfunctioning pouch-type charge/discharge cell when any of the pouch-type charge/discharge cells fails. This is simple and minimizes electrical resistance.

Description

Electric energy storage and release module {ELECTRIC ENERGY STORAGE MOULDE}

The present invention relates to an electric energy storage and release module.

Secondary batteries, which are electrical energy storage and emission devices that store and release electrical energy using an electrochemical process, include lithium-ion batteries and supercapacitors. In general, lithium ion batteries generate, accumulate and release electricity through the oxidation-reduction reaction of Li+ ions, and supercapacitors accumulate and release electricity through the process of adsorption of electrolyte ions on the electrode surface. do. Therefore, a supercapacitor has a faster charging/discharging rate and high power output than a lithium-ion battery, but a supercapacitor has a relatively low energy density compared to a lithium-ion battery because ions are adsorbed only on the surface of the electrode.

Such lithium-ion batteries or supercapacitors are manufactured in the form of a module in which a plurality of unit cells (hereinafter referred to as charge/discharge cells) are stacked, or in the form of a pack in which a plurality of modules are connected, respectively, and are applied to storage batteries for energy storage, electric vehicles, etc. have.

The charge/discharge cell constituting the electric energy storage/discharge module includes a casing, a pair of electrodes and a separator provided inside the casing, and an electrolyte (liquid) filled in the casing. Charge/discharge cells are classified into pouch type and can type according to the shape of the casing. That is, in the case of a lithium ion battery (battery), it is classified into a pouch-type secondary battery cell and a can-type secondary battery cell, and in the case of a supercapacitor, it is classified into a pouch-type capacitor cell and a can-type capacitor cell.

The electric energy storage/discharge module is composed of charging/discharging cells in a series connection type or in a parallel connection type. When the electric energy storage/discharge module (battery module) is configured in a form in which a plurality of charge/discharge cells are connected in parallel, the electrode leads of the same polarity of the charge/discharge cells are respectively coupled to each other through a bus bar, and the combined state is determined. In order to keep it stable, the electrode leads are joined to the bus bar by high-frequency welding or laser welding, or by bolting. In such a configuration, since an electrically conductive object such as a bus bar is used, the configuration is complicated and the volume is increased, and the manufacturing cost is increased because the welding process is complicated. In addition, some of the charge/discharge cells are damaged and the replacement operation becomes very difficult due to the replacement bus bar.

On the other hand, in the case of an electric vehicle battery, a local temperature difference between charge and discharge cells occurs due to heat generated due to fast charging, high output, and the number of repeated charging, or thermal runaway (thermal runaway) that impairs the efficiency and stability of the battery , thermal runaway) occurs.

It is an object of the present invention to provide an electrical energy storage/discharge module that not only reduces the volume and weight but also efficiently discharges heat generated therein.

Another object of the present invention is to provide an electric energy storage/discharge module in which replacement of a faulty charging/discharging cell is simple when any of the charging/discharging cells fails.

Another object of the present invention is to provide an electrical energy storage and discharge module that minimizes electrical resistance.

In order to achieve the above object, a plurality of supports; Pouch-type charging/discharging cells arranged in a line between the supports, each having a negative terminal on one side and a positive terminal on the other side, connected in series; a fastening unit for pressing and fixing the pouch-type charging/discharging cells by fastening the supports; and a pair of plate-type terminals provided between two pouch-type charge-discharge cells adjacent to each other of the pouch-type charge-discharge cells and are in contact with each other is provided.

It is preferable that a pressure buffer member is provided between one of the supports and the pouch-type charging/discharging cell.

The pair of plate-shaped terminals includes a plate-shaped negative terminal in contact with the negative terminal of the pouch-type charging/discharging cell, and a plate-shaped positive terminal in contact with the positive terminal of a pouch-type charging/discharging cell adjacent to the pouch-type charging/discharging cell. , The plate-shaped negative electrode terminal includes a base plate portion having a set area, negative electrode-shaped grooves formed over one side of the base plate portion, and negative electrode-shaped projections formed by the negative electrode-shaped grooves, the plate-shaped positive electrode terminal includes a base plate portion having a set area, anode-type grooves formed over one side of the base plate portion, and anode-type mating protrusions formed by the anode-type grooves, and the cathode-type grooves of the plate-shaped negative electrode terminal It is preferable that the positive and negative junction protrusions are respectively joined to the positive poles and the positive junction grooves of the plate-shaped positive electrode terminal to be in contact with each other.

The negative electrode-type grooves of the plate-shaped negative electrode terminal are formed with straight unit grooves having uniform width and depth at uniform intervals, and the negative electrode-type grooves are unit projections formed between two adjacent unit grooves, the It is preferable that the anode-type grooves of the plate-type positive electrode terminal are formed with straight unit grooves having uniform width and depth at uniform intervals, and the negative-pole-type compound projections are unit projections formed between two adjacent unit grooves. .

It is preferable that a heat sink part bent and extended at one end of the base plate part of the plate-shaped negative electrode terminal is further provided.

It is preferable that a bent and extended heat sink portion is further provided at one end of the base plate portion of the plate-shaped positive electrode terminal.

The pouch-type charge/discharge cell is preferably a lithium ion battery cell.

The pouch-type charge/discharge cell may be a supercapacitor cell.

In the present invention, pouch-type charge/discharge cells are arranged in a line between two supports, and each of the pouch-type charge/discharge cells is provided with a negative terminal on one side) and a positive terminal on the other side, so that the bus is connected in series. By excluding the bar, not only the weight is reduced, but also the volume (volume) is reduced.

In addition, according to the present invention, pouch-type charge/discharge cells are arranged in a line between two supports, and each of the pouch-type charge/discharge cells is provided with a negative terminal on one side and a positive terminal on the other side, and is connected in series. Since the pouch-type charge/discharge cells are pressurized and fixed by fastening the two supports with the fastening unit, if any pouch-type charge/discharge cell among the pouch-type charge/discharge cells fails and needs to be replaced, loosen the fastening unit and fix the defective pouch-type charge/discharge cell. The discharge cell can be replaced with a new pouch-type charge/discharge cell, making it easy to replace a defective pouch-type charge/discharge cell.

In addition, in the present invention, a pair of plate-shaped terminals are provided between two pouch-type charge-discharge cells adjacent to each other of the pouch-type charge-discharge cells, and a plate-shaped negative terminal and a plate-shaped positive terminal constituting a pair of plate-shaped terminals are formed on the contact surface. Since the mating grooves and the mating protrusions are formed respectively, and the mating grooves and the mating protrusions are mated and contacted, the contact area is increased to minimize electrical resistance as well as to strengthen the fastening strength.

1 is a front view showing an embodiment of an electric energy storage and release module according to the present invention;
2 is a front view showing a pouch-type charging/discharging cell and a pair of plate-type terminals constituting an embodiment of the electric energy storage/discharging module according to the present invention separated;
3 is a side view of a pouch-type charging/discharging cell constituting an embodiment of an electric energy storage/discharge module according to the present invention;
4 is a disassembled front view of a pair of plate-shaped terminals constituting an embodiment of the electric energy storage and release module according to the present invention;
4 and 5 are front views each showing a heat sink portion of a pair of plate-shaped terminals constituting an embodiment of the electric energy storage and release module according to the present invention.

Hereinafter, an embodiment of the electric energy storage and release module according to the present invention will be described with reference to the accompanying drawings.

1 is a front view showing an embodiment of an electric energy storage and release module according to the present invention.

As shown in Figure 1, the embodiment of the electrical energy storage and release module according to the present invention, the support 10, pouch-type charging and discharging cells 20, a fastening unit 30, a pair of plate-shaped terminals ( 40) is included.

The supports 10 are spaced apart from each other. The supports 10 are preferably two. As an example of the support body 10, the support body 10 has a square plate-shaped support plate part 11 and a through hole ( 12) are included.

The pouch-type charging/discharging cells 20 are arranged in a line between the two supports 10, each provided with a negative terminal 21 on one side and a positive terminal 22 on the other side and connected in series. do.

As an example of the pouch-type charge/discharge cell 20, the pouch-type charge/discharge cell 20 includes a pouch-type casing, an electrode assembly provided inside the pouch-type casing, and a positive electrode plate and a negative electrode plate disposed with a separator interposed therebetween; The electrolyte solution provided inside the pouch-type casing, the cathode terminal provided on one wide surface of the pouch-type casing and connected to the negative electrode plate of the electrode assembly by an electrode tab, and the other wide surface of the pouch-type casing provided on the electrode assembly The positive plate includes a positive terminal connected by an electrode tab. That is, an example of the pouch-type charge/discharge cell 20 is a pouch-type secondary battery cell.

As another example of the pouch-type charge/discharge cell 20, a pouch-type casing, an element provided inside the pouch-type casing and provided with a pair of electrodes disposed on both sides of the separator, and a pouch-type casing filled inside Electrolyte, a negative terminal provided on one wide surface of the pouch-type casing and connected to the negative electrode of the device by an electrode tab, and a positive terminal provided on the other wide surface of the pouch-type casing and connected to the positive electrode of the device by an electrode tab includes That is, another example of the pouch-type charge/discharge cell 20 may be an example of a pouch-type supercapacitor cell.

The fastening unit 30 fastens the pouch-type charging/discharging cells 20 by fastening the two supports 10 . As an example of the fastening unit 30 , the fastening unit 30 includes four bolts 31 and nuts 32 each fastened to the bolts 31 . The four bolts 31 are provided with a uniform spacing between the supports 10 and the nuts 32 are respectively fastened to the bolts 31 in a state where they penetrate the two supports 10 to form the two supports 10 . conclude The bolts 31 and nuts 32 may be six or eight. When the two supports 10 are fastened by the fastening unit 30 , the pouch-type charge/discharge cells 20 positioned between the two supports 10 are pressed and fixed.

A pressure buffer member 50 may be provided between one of the two supports 10 and the pouch-type charging/discharging cell 20 . The pressure buffer member 50 includes an elastic material. The pressure buffer member 50 is capable of applying an elastic force when the two supports 10 are fastened by the fastening unit 30 to pressurize the pouch-type charging/discharging cells 20 . The pressure buffer member 50 may be further provided between the other support body 10 and the pouch-type charging/discharging cell 20 .

A pair of plate-shaped terminals 40 are provided between two pouch-type charge/discharge cells 20 adjacent to each other of the pouch-type charge/discharge cells 20 to be in contact with each other. That is, a pair of plate-shaped terminals are respectively provided between the pouch-type charging and discharging cells 20 . As an example of the pair of plate-shaped terminals 40, the pair of plate-shaped terminals 40 include a plate-shaped negative terminal 41 that is in contact with the negative terminal 21 of the pouch-type charge/discharge cell 20, and a pouch-type charge/discharge. and a plate-shaped positive terminal 42 in contact with the positive terminal 22 of the pouch-type charge/discharge cell 20 adjacent to the cell 20 . The plate-shaped negative terminal 41 preferably includes copper or aluminum. The plate-shaped positive electrode terminal 42 preferably includes aluminum.

The plate-shaped negative electrode terminal 41 is formed by a base plate portion 1 having a set area, negative electrode mold grooves 2 formed over one side of the base plate part 1, and the negative electrode mold grooves 2 . It includes the negative electrode type protrusions (3) to be formed. The base plate 1 is preferably a square plate having a uniform thickness. The negative electrode type grooves 2 are formed in a plurality of straight negative type grooves 2 having a uniform width and depth at uniform intervals, and the negative electrode type grooves 3 are two negative electrode type grooves adjacent to each other ( 2) is formed between them. It is preferable that the cathode-shaped grooves 2 are arranged in a horizontal direction.

The plate-shaped positive electrode terminal 42 is formed by a base plate portion 4 having a set area, positive electrode-type grooves 5 formed over one side of the base plate portion 4, and the positive electrode-type grooves 5. It includes the anode-type compound projections (6) to be formed. The base plate 4 is preferably a square plate having a uniform thickness. The anode-type grooves 5 are anode-type grooves 5 of a straight line having a uniform width and depth are formed at uniform intervals, and the anode-type grooves 6 are two anode-type grooves 5 adjacent to each other. formed between them. The anode-type grooves 5 are preferably arranged in a horizontal direction.

When the plate-shaped negative terminal 41 and the plate-shaped positive terminal 42 constituting the pair of plate-shaped terminals 40 are in contact with each other, the negative electrode-shaped grooves 2 and the negative electrode-shaped projections 3 of the plate-shaped negative terminal 41 are formed. Each of the plate-shaped anode terminals 42 is molded into the anode-type mating projections 6 and the anode-type mating grooves 5 to be in contact with each other. Due to this, the contact area between the plate-shaped negative terminal 41 and the plate-shaped positive terminal 42 constituting the pair of plate-shaped terminals 40 is increased and the fastening strength is strengthened. The anode mating grooves 2 and the cathode mating projections 3 of the plate-shaped cathode terminal 41 may be formed in various shapes, and also the anode mating grooves 5 and the anode of the plate-shaped cathode terminal 42 molded thereto. The mold protrusions 6 may also be formed in various shapes.

It is preferable that the cathode mating grooves 2 of the plate-shaped cathode terminal 41 and the anode mating grooves 5 of the plate-shaped anode terminal 42 are each formed by an etching process.

As shown in FIG. 5 , it is preferable that a bent and extended heat dissipation plate part 7 is further provided at one end of the base plate part 1 of the plate-shaped negative electrode terminal 41 . The heat sink is formed to extend to the end of the base plate (1) in the direction perpendicular to the longitudinal direction of the negative electrode type groove (2) of the plate-shaped negative electrode terminal (41).

In addition, as shown in FIG. 6 , it is preferable that a bent and extended heat sink portion 8 is further provided at one end of the base plate portion 4 of the plate-shaped positive electrode terminal 42 . It is preferable that the heat sink portion 7 of the plate-shaped negative terminal 41 and the heat sink portion 8 of the plate-shaped positive terminal 42 are located opposite to each other.

As described above, in the electrical energy storage/discharge module according to the present invention, pouch-type charge/discharge cells 20 are arranged in a line between two supports 10 , and each of the pouch-type charge/discharge cells 20 is one side. Since the negative terminal 21 is provided on the side and the positive terminal 22 is provided on the other side and connected in series, the bus bar is excluded to reduce the weight as well as the volume (volume).

In addition, the pouch-type charge/discharge cells 20 are arranged in a line between the two supports 10, and each of the pouch-type charge/discharge cells is provided with a negative terminal 21 on one side and a positive terminal on the other side ( 22) is provided and connected in series and the two supports 10 are fastened with the fastening unit 30 to pressurize and fix the pouch-type charge/discharge cells 20, so any pouch among the pouch-type charge/discharge cells 20 is provided. When a failure occurs in the charging/discharging cell 20 and it is replaced, the fastening unit 30 is loosened and the defective pouch-type charging/discharging cell 20 can be replaced with a new pouch-type charging/discharging cell 20. The replacement operation of the type charge/discharge cell 20 is simplified.

In addition, a pair of plate-shaped terminals 40 are provided between two pouch-shaped charging/discharging cells 20 adjacent to each other of the pouch-type charging/discharging cells 20 , and a plate-shaped negative electrode forming a pair of plate-shaped terminals 40 . Since mating grooves and mating protrusions are respectively formed on the contact surface of the terminal 41 and the plate-shaped positive electrode terminal 42, and the mating grooves and the mating protrusions are mated and contacted, the contact area is increased to minimize electrical resistance and fastening strength. strengthen the

10; support base member 20; lower jig
30; pressing member 40; upper jig
50; pressure measuring unit

Claims (4)

a plurality of supports;
Pouch-type charging/discharging cells arranged in a line between the supports, each having a negative terminal on one side and a positive terminal on the other side, connected in series;
a fastening unit for pressing and fixing the pouch-type charging/discharging cells by fastening the supports; and
An electrical energy storage/discharge module comprising a pair of plate-shaped terminals that are provided between two pouch-type charge-discharge cells adjacent to each other of the pouch-type charge-discharge cells and are in contact with each other. According to claim 1, wherein the pair of plate-shaped terminals are a plate-shaped negative terminal in contact with the negative terminal of the pouch-type charge/discharge cell, and the positive terminal of the pouch-type charge/discharge cell adjacent to the pouch-type charge/discharge cell is in contact with A plate-shaped anode terminal is included, wherein the plate-shaped cathode terminal includes a base plate having a set area, cathode-shaped grooves formed over one side of the base plate, and cathode-shaped protrusions formed by the cathode-shaped grooves. and the plate-shaped positive electrode terminal includes a base plate portion having a set area, positive electrode-type grooves formed over one side of the base plate portion, and positive electrode-type projections formed by the positive electrode-type grooves, the plate-shaped negative electrode An electrical energy storage/discharge module, characterized in that the negative electrode type grooves and the negative electrode type compound projections of the terminal are molded into the positive type type compound projections and the positive type type grooves of the plate-shaped positive electrode terminal, respectively, and are in contact with each other. According to claim 1, wherein the negative electrode type grooves of the plate-shaped negative electrode terminal is a straight unit groove having a uniform width and depth is formed at uniform intervals, and the negative electrode type grooves are formed between two adjacent unit grooves. It is a unit protrusion formed, and in the anode-type grooves of the plate-shaped positive electrode terminal, straight unit grooves having a uniform width and depth are formed at uniform intervals, and the cathode-type compound projections are formed between two adjacent unit grooves. Electrical energy storage and release module, characterized in that the unit projection. The electricity according to claim 2, further comprising a heat sink part bent and extended at one end of the base plate part of the plate-shaped cathode terminal, and a heat sink part bent and extended at one end of the base plate part of the plate-shaped anode terminal. Energy storage and release module.

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