KR20210016696A - Multi-stacked monopolar all solid stae battery - Google Patents

Abstract

The present invention relates to an all-solid-state battery comprising a plurality of monopolar units arranged in parallel within a pouch cell. Each of the monopolar units comprises: a solid electrolyte layer; a positive electrode layer adhered to one side of the solid electrolyte layer; and a negative electrode layer including a negative electrode metal body adhered to the other side of the solid electrolyte layer and a negative electrode current collector layer to which the negative electrode metal body is adhered. Both side surfaces of the positive electrode layer may be casted by a positive electrode active material to be shared with the adjacent monopolar unit. Thus, compared to a simple stacked bipolar stack all-solid-state battery, the size can be reduced, and the volume can be reduced. Thus, all-solid-state batteries can be used for a variety of purposes. Compared to a volume, electricity capacity can be increased. Also, ESS capacity is possible.

Description

Multi-stack monopolar all-solid-state battery {MULTI-STACKED MONOPOLAR ALL SOLID STAE BATTERY}

The present invention relates to an all-solid-state battery, and more particularly, to a multi-stack monopolar all-solid-state battery capable of up to the capacity of an ESS by stacking monopolars in multiple layers in a pouch cell.

Secondary batteries are widely used from large devices such as automobiles and power storage systems to small devices such as mobile phones, camcorders, and notebooks. Among them, lithium-ion secondary batteries have higher energy density than other secondary batteries and can operate at high voltages. I have. Therefore, as a secondary battery that is easy to achieve compact and lightweight, it is mainly used for information devices such as mobile phones, and recently, demand for large-sized power vehicles such as electric vehicles and hybrid vehicles is also increasing.

However, lithium secondary batteries have the advantage of high energy density and large capacity per unit area compared to nickel-manganese batteries or nickel-cadmium batteries, but they are easy to overheat and have poor output, so they are suitable as next-generation batteries that can be applied to automobiles. Not. Lithium ion secondary batteries have a positive electrode layer, a negative electrode layer, and an electrolyte layer interposed therebetween. When a liquid is used as an electrolyte, the interface resistance between the active material contained in the positive electrode layer or the negative electrode layer and the electrolyte solution is low. It is easy to improve, but since the electrolyte is flammable, a variety of additional complex systems are required to ensure safety.

Since the solid electrolyte is non-flammable, the complex system can be simplified, and a lithium ion secondary battery in the form of a solid electrolyte has been proposed, and interest in an all-solid battery having output and high energy density is increasing.

All-solid-state batteries have a theoretical energy density of about 2600 Wh/kg, which is about 7 times higher than that of conventional lithium secondary batteries, so they are suitable as power sources for electric vehicles, and it is better to form an all-solid battery by stacking unit cells of a certain structure. High operating voltage or capacity can be implemented.

In order to obtain the voltage of the desired capacity, several cells must be connected in series. There are largely a bipolar type and a monopolar type according to a stacking method for connecting cells in series. In the bipolar type, cathodes and anodes of individual unit cells are alternately stacked and a bipolar plate is interposed. In the monopolar type, the cathode and anode of the unit cell are arranged on both sides centering on the electrolyte membrane, and the cathode and anode are alternately arranged by wires. It is a way to connect.

The conventional all-solid-state battery is mainly a bipolar cell stack structure, and a structure in which a plurality of bipolar electrodes are stacked can obtain a high-power and large capacity of several tens of watts or more, and thus a bipolar cell stack structure is mainly used in the all-solid-state battery.

However, the conventional all-solid-state battery of the bipolar cell stack structure is a structure made by stacking multiple layers of bipolar electrodes, so it is possible to obtain a high output and large capacity, but it is inevitable to be bulky by the stacked electrodes and is a structure that must be stacked. There was a problem that it could only be limited.

On the other hand, in all-solid-state batteries, monopolar cell packs are mainly used for low-power, small-capacity less than a few watts, so it is difficult to obtain high-power and high-capacity in monopolar cell all-solid batteries. When stacking monopolar cell packs, it is difficult to miniaturize the entire battery. When a problem occurs in the unit battery, there is a problem that the entire battery must be disassembled.

Korean Patent Publication No. 10-2014-0009497 (Bipolar all-solid battery)

The present invention is to solve the problems of the prior art described above, and an object of the present invention is that it is possible to stack a plurality of layers of monopolar all-solid batteries in one pouch, while miniaturizing, and increasing electric capacity to volume. It is to provide a multi-stack monopolar all-solid-state battery.

Another object of the present invention is to provide a multi-stack monopolar all-solid-state battery capable of reducing the cost and time required for manufacturing by reducing the number of processes.

In order to achieve the above object, the multi-stack monopolar all-solid-state battery according to the present invention includes a plurality of monopolar units arranged in parallel in a pouch cell, and each of the monopolar units includes a solid electrolyte layer and the A cathode layer comprising an anode layer adhered to one side of the solid electrolyte layer, a cathode metal body adhered to the other side of the solid electrolyte layer, and a cathode current collector layer to which the anode metal body is adhered, wherein the anode layer is double-sided It is characterized in that it can be shared with the adjacent monopolar unit by casting as a positive electrode active material.

Here, in a position in which the plurality of monopolar units are disposed adjacent to each other, the anode metal body of the monopolar unit is adhered to both sides of the anode current collector, so that the adjacent monopolar units are arranged in parallel.

Here, the solid electrolyte layer is characterized in that it is formed by bonding a plurality of electrolyte plates.

Here, the negative electrode layer is characterized in that one side is scraped off and the scraped side is adhered to the negative electrode current collector.

Here, the anode layer is characterized in that the anode is cast on both sides of the aluminum foil pasted on both sides.

Here, the anode layer has an aluminum tab, and the cathode layer has a nickel tab.

According to the multi-stack monopolar all-solid-state battery of the present invention having the above-described configuration, by arranging a plurality of monopolar units in parallel in one pouch cell, it is possible to reduce the size and reduce the volume compared to the bipolar stack all-solid battery of a simple stack structure. Because of this, all-solid-state batteries can be used for various purposes.

In addition, according to the present invention, by arranging a plurality of monopolar units in parallel, it is possible to provide a multi-stack monopolar all-solid-state battery capable of increasing electric capacity to volume and up to the capacity of ESS.

In addition, since the monopolar units can be simply stacked in a pouch cell by arranging them in parallel, cost and time required for manufacturing can be reduced by reducing the number of processes.

1 is an exploded view schematically showing a multi-stack monopolar all-solid-state battery according to the present invention.
2 is a three-dimensional view showing a unit cell of the multi-stack monopolar all-solid-state battery of FIG. 1.
3 is a diagram showing another example of a multi-stack monopolar all-solid-state battery according to the present invention, and is a diagram illustrating that monopolar units are stacked in 5 stages in parallel.
FIG. 4 is a diagram showing another example of a multi-stack monopolar all-solid-state battery according to the present invention, and is a diagram illustrating that monopolar units are stacked in 6 stages in parallel.

Hereinafter, a multi-stack monopolar all-solid-state battery according to the present invention will be described as an example with reference to the accompanying drawings.

1 is an exploded view schematically showing a multi-stack monopolar all-solid-state battery according to the present invention, and FIG. 2 is a three-dimensional view.

1 and 2, a multi-stack monopolar all-solid-state battery 1 according to the present invention is characterized in that a plurality of monopolar units 10, 11, 12, 13 are arranged in parallel in a pouch cell. do. In this embodiment, it is an example that there are four monopolar units disposed in one pouch cell, but this is not necessarily limited to this, and a larger number of monopolar units may be disposed according to the needs of the user such as electric capacity. to be.

Each of the monopolar units 10, 11, 12 and 13 is formed by being connected in parallel with the adjacent monopolar units.

Since each of the monopolar units 10, 11, 12, and 13 has approximately the same configuration, any one monopolar unit 10 will be described as an example.

The monopolar unit 10 includes a solid electrolyte layer 100, an anode layer 101, and a cathode layer 102.

The solid electrolyte layer 100 includes a solid electrolyte, and allows ion transfer between electrodes while electrically separating the anode layer and the cathode layer from each other. In the present embodiment, the solid electrolyte layer 100 is formed by bonding two electrolyte plates to each other, but the present embodiment is not limited thereto, and may be formed by bonding a plurality of electrolyte plates.

The solid electrolyte layer 100 is cut slightly larger than the anode layer 101 and the cathode layer 102 to prevent contact between the anode layer and the cathode layer when manufacturing the monopolar unit, and at the same time The transfer of ions in the electrolyte layer 100 is made to be stably.

The positive electrode layer 101 is made of a positive electrode active material. In this embodiment, the anode layer 101 includes, for example, an aluminum foil, and is manufactured by casting after coating a cathode active material including PEO (Plasma Electrolytic Oxidation) and LLZO on the surface of the aluminum foil.

Here, it is preferable that the anode layer 101 is configured such that the cathode active material is not cast only on one side of the aluminum foil, but is anode cast on both sides. By anodic casting on both sides of the anode layer 101, when the two monopolar units are stacked adjacent to each other, adjacent monopolar units 10 and 11 share one anode layer 101 With one anode layer 101, two monopolar units may be connected in parallel.

The anode layer 101 includes an anode tab 101a protruding outward from the anode layer, and in this embodiment, the anode tab is formed of an anode tab made of aluminum to extract generated electricity to the outside. And the negative electrode tabs disposed on the negative electrode current collector are alternately alternately positioned to each other.

The negative electrode layer 102 is composed of a negative electrode metal body 103 and a negative electrode current collector 104. In this embodiment, a scratch surface 103a is formed by scraping off one surface of the metal plate forming the cathode metal body 103. The scratch surface 103a of the anode metal body 103 is bonded to the anode current collector 104 using a heater and a coated PET film. The negative electrode current collector 104 may be made of, for example, a copper material.

The negative electrode current collector 104 is provided with a negative electrode tab 104a. The negative electrode tab 104a is formed to protrude outward from the negative electrode current collector. In this embodiment, the negative electrode tab is formed of a negative electrode tab made of nickel, is disposed to extract the generated electricity to the outside, and is formed alternately with the positive electrode tab disposed on the positive electrode layer.

A plurality of monopolar units 10, 11, 12, and 13 having the above-described configuration are connected in parallel.

As shown in Fig. 1, the first monopolar unit 10 includes a first negative electrode layer 102 formed by bonding a first negative electrode current collector 104 and a first negative electrode metal body 103, and a first negative electrode layer. It consists of a first solid electrolyte layer 100 to which 102 is bonded, and a first anode layer 101 that is bonded to the other side of the first solid electrolyte layer 100.

As described above, the first anode layer 101 is commonly used as an anode layer of the first monopolar unit 10 and an anode layer of the second monopolar unit 11. That is, in the second monopolar unit 11, the second solid electrolyte layer 110 of the second monopolar unit 11 is bonded to the other side of the first anode layer 101, and the second cathode The second negative electrode layer 112 made of the metal body 113 and the second negative electrode current collector 114 is bonded.

Accordingly, both sides of one anode layer are anode-cast, so that two monopolar units share one anode layer 101 and are connected in parallel.

Meanwhile, in addition to the two monopolar units, another monopolar unit may be connected in parallel within one pouch. As shown in FIG. 1, in a position where a plurality of the monopolar units are disposed adjacent to each other, the negative electrode current collector is configured to be shared with the negative electrode current collector of the adjacent monopolar unit.

That is, in a position where the second monopolar unit 11 and the third monopolar unit 12 are disposed adjacent to each other, the second monopolar unit 11 is disposed on both sides of the second negative electrode current collector 114. The cathode metal body 113 is adhered, and the first cathode metal body 123 of the third monopolar unit 12 is disposed on the other side to be bonded.

In the present exemplary embodiment, four monopolar units are arranged in parallel in one pouch cell, but the present invention is not limited thereto, and five or more monopolar units may be arranged in parallel if necessary.

FIG. 3 is a diagram illustrating that monopolar units are stacked in 5 stages in parallel, and FIG. 4 is a diagram illustrating that monopolar units are stacked in 6 stages in parallel.

As shown in FIGS. 3 and 4, when one monopolar unit is additionally stacked in a pouch cell in which four monopolar units are stacked, first, the negative electrode current collector of the outermost monopolar unit 13 is It is configured to be shared with the negative electrode current collector of the monopolar unit to be added.

That is, in a position where the fourth monopolar unit 13 and the fifth monopolar unit 14 are disposed adjacent to each other, a fourth monopolar unit 13 is disposed on one side of the fourth negative electrode current collector 134. The cathode metal body is adhered, and the fifth cathode metal body 143 of the fifth monopolar unit 14 is disposed on the other side to be bonded. The fifth monopolar unit 14 includes a fourth negative electrode current collector 134, a fifth negative electrode metal body 143, a fifth solid electrolyte layer 140, and a fifth positive electrode layer 141. At this time, the fifth anode layer 141 may be configured to cast only one side without the need for double-sided casting.

Here, further connection of the sixth monopolar unit 15 is shown in FIG. 4. As shown in FIG. 4, connecting the sixth monopolar unit 15 is similar to the method of connecting the second monopolar unit to the first monopolar unit.

That is, the fifth anode layer 141 is commonly used as an anode layer of the fifth monopolar unit 14 and an anode layer of the sixth monopolar unit 15. At this time, the fifth anode layer is configured to be cast on both sides. In the sixth monopolar unit 15, the sixth solid electrolyte layer 150 of the sixth monopolar unit 15 is bonded to the other side of the fifth anode layer 141, and a sixth cathode metal body The sixth negative electrode layer made of 153 and the sixth negative electrode current collector 154 is bonded.

As described above, in this embodiment, the addition of 5 or 6 monopolar units has been described as an example of connecting 4 monopolar units in parallel, but in this manner, a plurality of monopolar units are Of course, it can be connected in parallel.

Accordingly, by arranging a plurality of monopolar units in parallel, it is possible to reduce the size and reduce the volume compared to the simple stacked bipolar stacked all-solid battery, increase the electric capacity to volume to the capacity of the ESS, Solid-state batteries can be used.

In addition, since the monopolar units can be simply arranged in parallel, a plurality of monopolar units can be arranged in parallel within the pouch cell, thus reducing the number of processes compared to the simple tandem stacked structure, thereby reducing the cost of manufacturing and You can save time.

This embodiment clearly shows only a part of the technical idea included in the present invention, and modifications and specific examples that can be easily inferred by those skilled in the art within the scope of the technical idea included in the specification of the present invention are It is obvious that all are included in the technical idea of the present invention.

1: Multi-stack monopolar all-solid-state battery
10, 11, 12, 13: monopolar unit
100: first solid electrolyte layer
101: first anode layer
102: first cathode layer
103: first cathode metal body
104: first negative electrode current collector

Claims (6)

Including a plurality of monopolar units arranged in parallel in the pouch cell,
Each of the monopolar units,
And a negative electrode layer comprising a solid electrolyte layer, an anode layer adhered to one side of the solid electrolyte layer, a cathode metal body adhered to the other side of the solid electrolyte layer, and a cathode current collector layer to which the anode metal body is bonded, ,
The positive electrode layer is a multi-stack monopolar all-solid-state battery, characterized in that the positive electrode active material is cast on both sides and can be shared with the adjacent monopolar unit.
The method of claim 1,
In a position where a plurality of the monopolar units are disposed adjacent to each other, the anode metal body of the monopolar unit is adhered to both sides of the anode current collector so that the adjacent monopolar units are arranged in parallel. Solid battery.
The method according to claim 1 or 2,
The solid electrolyte layer is a multi-stack monopolar all-solid-state battery, characterized in that formed by bonding a plurality of electrolyte plates.
The method according to claim 1 or 2,
The negative electrode layer is a multi-stack monopolar all-solid-state battery, characterized in that by scraping one side and bonding the scraped side to the negative electrode current collector.
The method according to claim 1 or 2,
The positive electrode layer is a multi-stack monopolar all-solid-state battery, characterized in that the positive electrode cast on both sides of the aluminum foil pasted on both sides.
The method according to claim 1 or 2,
Wherein the positive electrode layer has an aluminum tab, and the negative electrode layer has a nickel tab.

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