KR20090124113A - Rechargable cell - Google Patents

Abstract

PURPOSE: A rechargable cell is provided to appropriately maintain a temperature by radiating heat created in charge, to increase charging capacity, and to implement the large-size of the battery. CONSTITUTION: A rechargable cell(10) comprises: a casing(100) which is a cube having at least two flat sides, is formed to be longer than the thickenss, and has hollow thereinside; at least two cell units which are arranged in the hollow and respectively has a positive electrode current collector and a negative electrode collector; and at least one divider which divides the hollow of casing and communicates electrolyte between at least two unit cells.

Description

Secondary Battery {RECHARGABLE CELL}

The present invention relates to a battery, and more particularly, to a secondary battery capable of facilitating heat dissipation and increasing charging capacity.

A battery is a device that generates voltage and current from chemical reactions, and a current is formed by a reaction of sending and receiving electrons at the ends of each conductor. These batteries are classified into primary batteries that cannot be recharged at the end of their lifetime and rechargeable secondary batteries.

Such secondary batteries include lead acid batteries, alkaline storage batteries, gas batteries, lithium ion batteries, nickel-cadmium batteries, nickel-hydrogen batteries, polymer batteries, and the like.

Lead acid batteries are electrochemical reactions that use lead peroxide as the positive electrode and lead as the negative electrode. Dilute sulfuric acid having a specific gravity of about 1.2 is used as the electrolyte. Chemical reactions are reversible and can be used as rechargeable secondary batteries. Widely used as automobile storage battery.

Alkaline batteries are made of strong alkaline solution as electrolyte, nickel hydroxide as positive electrode, iron or cadmium as negative electrode, and are light and have a long service life.

Nickel-cadmium batteries are alkaline batteries that use a hydroxide of nickel for the positive electrode and cadmium for the negative electrode. It is used for safety light inside the tunnel, lighting for train, communication power, electric vehicle power, starting of diesel engine, and other high rate discharge.

A nickel-hydrogen battery is a secondary battery using nickel as a positive electrode, a hydrogen storage alloy as a negative electrode, and using alkaline aqueous solution or water as an electrolyte. It is widely used because of its high capacity, small size, light weight, overdischarge and overcharge, and the number of chargeable cycles. Nickel-hydrogen batteries have an energy density per unit volume close to twice that of nickel-cadmium batteries, and are capable of higher capacity than nickel-cadmium batteries, and withstand overdischarge and overcharge. In addition, rapid charging and discharging, miniaturization and weight reduction are possible, and the charge / discharge cycle life is long, so that charging and discharging can be performed more than 500 times.

These various types of secondary batteries generate exothermic reactions during charging, and when the temperature rises due to such exothermic reactions, the charge capacity decreases as well as the charge / discharge cycles decrease. There is a need for a structure that effectively radiates to the outside.

In particular, the amount of hydrogen charged in the hydrogen storage alloy as a negative electrode active material in a nickel-hydrogen battery has a characteristic of decreasing as pressure increases and temperature decreases. Accordingly, the secondary battery has a temperature increase due to an exothermic reaction at the time of charging, and when the temperature rises in this manner, the hydrogen storage alloy decreases the amount of hydrogen charged.

In conclusion, a secondary battery such as a nickel-hydrogen battery can efficiently increase the charge capacity by dissipating heat generated at the time of charging and maintaining the temperature appropriately.

The present invention has been made in view of the above, and an object thereof is to provide a secondary battery capable of effectively dissipating heat generated during charging and significantly increasing a charging capacity.

A secondary battery according to a preferred embodiment of the present invention for achieving the above object,

A casing having at least two flat surfaces and having a width greater than the thickness thereof, the casing having a hollow portion therein;

Two or more cell units disposed in the hollow portion of the casing and separately having a positive electrode current collector and a negative electrode current collector connected in parallel; And

And at least one compartment for partitioning the hollow portion of the casing and communicating electrolyte between the at least two unit cells.

The compartment is a hexahedron having a width capable of preventing a short between adjacent unit cells, the lower end of the compartment is characterized in that the communication path is formed by being spaced apart from the lower end of the casing.

A guide groove and a guide protrusion may be formed to correspond to each other at portions in which the casing and the partition contact each other.

The guide groove and the guide protrusion is characterized in that the dovetail structure.

The compartment has a hollow portion therein, the hollow portion is characterized in that the upper and lower openings.

The casing has an opening, the opening is sealed by a first cap, and the positive electrode collector and the negative electrode collector of each of the unit cells are drawn out through the first cap, and the positive electrode collector of the two or more unit cells. The anode collectors are connected through at least one anode connector, and the cathode collectors of the at least two unit cells are connected through at least one cathode connector. .

The anode connector and the cathode connector include two or more connections electrically connected to each of the positive electrode current collector and the negative electrode current collector, and one or more connection portions connecting the connection portions.

The connecting portion is bent at a right angle to the connecting portion, and a partial cutout is formed at a lower end of the connecting portion.

The first cap further includes a vent in communication with the hollow portion of the casing.

The vent,

A sidewall extending upward from an upper surface of the first cap and having upper and lower portions thereof open;

A horizontal wall formed inside the sidewall in a horizontal direction and having a first through hole communicating with a hollow portion of the casing;

A vent cap detachably coupled to an upper inner diameter surface of the side wall and having a second through hole at an upper surface thereof;

A valve body installed to be movable up and down in the first through hole; And

It includes; an elastic body for deflecting the valve body downward.

A sealing ring is installed at a portion of the valve body in contact with the first through hole.

A second cap is mounted on an upper portion of the first cap, and the second cap is configured to conceal the first cap, the positive and negative electrode connectors.

The second cap has a receiving groove for receiving the connecting portion of the connector on the inner side.

An assembly groove and an assembly protrusion may be formed to correspond to each other at a portion where the second cap and the first cap are coupled to each other.

According to the present invention as described above, by forming a wide flat wall of the casing it is possible to more effectively discharge the high heat generated during the filling to the outside, thereby preventing the hydrogen charge amount of the hydrogen storage alloy of the negative electrode active material is lowered. There is an advantage.

In addition, the present invention has the advantage that the charging capacity of the battery can be increased by disposing two or more unit cells disposed in the casing, and connecting two or more unit cells in parallel.

In addition, the present invention can more easily implement a large capacity of the battery by sharing the electrolyte and the casing in two or more unit cells.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 7 illustrate a secondary battery according to an embodiment of the present invention.

As shown, the secondary battery 10 of the present invention includes a casing 100 and two or more unit cells 21, 22, and cell units installed in the casing 10.

The battery 10 of the present invention has at least two flat opposing sides facing each other, and preferably consists of a cuboid.

As shown in FIGS. 4 and 5, the casing 100 includes a pair of first flat walls 101 and 102 facing each other, a pair of second flat walls 103 and 104 facing each other, a closed surface (105, closed end) with an opening (106) open end opposite the closed surface.

3 and 4, the thickness t of the casing 100 is defined as the distance between the pair of first flat walls 101 and 102, and the width w of the casing 100 is one pair. Is defined as the distance between the second flat walls 103 and 104, and the height h of the casing 100 is defined as the vertical length of the first and second flat walls 101, 102, 103 and 104. . The casing 100 is formed to have a longer width w than its thickness t. Accordingly, the first flat walls 101 and 102 have a larger area than the second flat walls 103 and 104. In particular, the ratio t / w of the thickness t and the width w may be 1/10 or more. Accordingly, the casing 100 has a large area of the first flat walls 101 and 102 facing each other, so that the heat dissipation area generated when the battery 10 is charged increases, thereby increasing the heat dissipation efficiency. have.

The casing 100 has a hollow portion 107 therein, and the hollow portion 107 has a pair of first flat walls 101 and 102 and a pair of second flat walls 103 and 104. And the closing surface 105 and the opening 106.

Two or more unit cells 21 and 22 are disposed in the hollow part 107 of the casing 100, and each unit cell 21 and 22 is connected in parallel to increase its charging capacity.

Each of the unit cells 21 and 22 includes a plurality of separators 21c interposed between the plurality of positive electrode plates 21a and 22a, the plurality of negative electrode plates 21b and 22b, the positive electrode plates 21a and 22a and the negative electrode plates 21b and 22b. 22c) and the like.

Lead wires 21d and 22d are provided at upper ends of the plurality of positive electrode plates 21a and 22a, and each of the lead wires 21d and 22d is connected to the positive electrode current collectors 21p and 22p, respectively. Through-holes 21g and 22g are formed in the upper portion.

Lead wires 21e and 22e are provided at the upper ends of the plurality of negative electrode plates 21b and 22b, and each lead wire 21e and 22e is connected to the negative electrode current collectors 21n and 22n and the negative electrode current collectors 21n and 22n. Through-holes 21f and 22f are formed in the upper portion of the through hole.

One or more compartments 110 are installed in the hollow part 107 of the casing 100, and the compartment 110 corresponds to the number of unit cells 21 and 22 of the internal space of the hollow part 107. Partition into zones. For example, as shown in FIGS. 3 and 4, when there are two unit cells, one compartment 110 is installed to divide the hollow part 107 into two regions, and when the unit cell is three or more, two or more compartments 110. ) Is installed to partition the hollow portion 107 into three or more regions.

In addition, the partition body 110 is an insulating material, and each of the unit cells 21 and 22 is installed in each partitioned region of the hollow part 107 so that two or more unit cells 21 and 22 are partitioned.

Particularly, the partition body 110 has a hexahedron shape extending in the height direction of the casing 100, and the pair of first surfaces 111 and 112 contacting the inner surfaces of the first flat walls 101 and 102 and It has a pair of second surfaces 113 and 114 facing the inner surfaces of the second flat walls 103 and 104.

The thickness t1 of the compartment 110 is defined as the distance between the first surfaces 111 and 112, and the width w1 of the compartment 110 is defined as the distance between the second surfaces 113 and 114. do. The width w1 of the compartment 110 may be formed to have a minimum length to prevent shorts occurring between adjacent unit cells 21 and 22.

The first surfaces 111 and 112 of the partition 110 may be brought into close contact with the first flat walls 101 and 102, and the guide protrusions 101a may be provided on the inner surfaces of the first flat walls 101 and 102. , 102a may extend in the height direction, and guide grooves 111a and 112a may be formed in each of the first surfaces 111 and 112 of the partition 110. Accordingly, the guide grooves 111a and 112a of the compartment 110 are assembled in the state where the guide grooves 111a and 112a are determined along the guide protrusions 101a and 102a to precisely partition the two or more unit cells 21 and 22. have.

In addition, the guide protrusions 101a and 102a and the guide groove 111a may be formed in a dovetail structure to precisely assemble and separate the compartment 110.

A stopper 109 is formed below each inner side surface of the first flat walls 101 and 102, specifically, below the guide protrusions 101a and 102a, and the partition body 110 is formed by each stopper 109. The lower end of the casing 100 is spaced apart from the closing surface 105 by a predetermined interval is formed in the lower portion of the compartment 110, a communication passage 29 for communicating between the adjacent unit cells (21, 22) is formed By using the communication passage 29, the two or more unit cells 21 and 22 share electrolytes in a single casing 110, thereby facilitating the large capacity of the battery more easily and promoting efficient use of the electrolytes. can do.

In addition, the communication passage 29 is a minimum space for preventing electrolyte between the two or more unit cells 21 and 22 and communicating electrolyte between the two or more unit cells 21 and 22. It would be desirable to do so.

The partition 110 may have a hollow portion 115 therein, and the hollow portion 115 may be partially stored in the hollow portion 115 by opening the upper and lower portions thereof. The excess electrolyte solution stored in the hollow part 115 of the compartment 110 may partially replenish the electrolyte solution consumed by the charging or discharging of the unit cells 21 and 22, and further, to the hollow part 115. Since the stored excess electrolyte does not react and its temperature is relatively low, it may be used as a cooling water to cool the high heat generated in each of the unit cells 21 and 22.

An opening 106 is disposed above the casing 100, and a first cap 120 is mounted on the casing 100 to seal the opening 106, and the first cap 120 is casing 100. The top surface of) may be sealed after being preassembled by the assembling groove and the assembling protrusion.

The first cap 120 has a plurality of through holes 121 through which the positive electrode current collectors 21p and 22p and the negative electrode current collectors 21n and 22n of each unit cell 21 and 22 pass. In addition, a vent 125 is provided at one side of the first cap 120, and when the amount of gas generated in each of the cells 21 and 22 is excessive, some gas may be discharged to the outside through the vent 125. .

The vent 125 is separated from the side wall 125a extending upward from the top surface of the first cap 120, the horizontal wall 125b formed horizontally inside the side wall 125a, and the upper inner diameter surface of the side wall 125a. It has a vent cap 125c that is possibly coupled.

The upper and lower sides of the sidewall 125a are opened, and the vent cap 125c is detachably coupled to the upper inner diameter surface thereof by screwing or the like. The horizontal wall 125b has a first through hole 125d that communicates with the hollow portion 107 of the casing 100, and the valve body 125e is provided to be movable up and down in the first through hole 125d. In addition, the vent cap 125c has a second through hole 125h, and an elastic body 125f is interposed between the valve body 125e and the vent cap 125c, whereby the valve body 125e is lowered by the elastic body 125f. Is biased. And the sealing ring 125g is provided in the part which the valve body 125e and the 1st through hole 125d contact, and the sealing property is ensured.

By such a configuration, when excessive gas is generated in each of the unit cells 21 and 22 in the casing 110, the vent 125 may generate a spring force of the elastic body 125f due to the pressure of the gas. By moving upward while overcoming, the first through hole 125d is opened, whereby a part of the gas is discharged to the outside through the first through hole 125d and the second through hole 125h, thereby preventing the explosion of the battery and the like. .

The positive electrode current collectors 21p and 22p and the negative electrode current collectors 21n and 22n drawn from the unit cells 21 and 22 are connected in parallel through one or more positive electrode connectors 31 and one or more negative electrode connectors 32. Is connected. The positive electrode connection body 31 interconnects the positive electrode current collectors 21p and 22p of the unit cells 21 and 22, and the negative electrode connection body 32 is the negative electrode current collector 21n of each unit cell 21 and 22. , 22n are connected to each other so that the unit cells 21 and 22 adjacent to each other are connected in parallel. As described above, the battery 10 of the present invention can increase the charging capacity by connecting two or more unit cells 21 and 22 in parallel in terms of energy density.

Each of the connectors 31 and 32 is connected to the positive electrode current collectors 21p and 22p and the negative electrode current collectors 21n and 22n of the unit cells 21 and 22 through the fasteners 51 and 52 made of a conductive material. Two or more connections 31a and 32a to be joined and one or more connections 31b and 32b to connect across between the connections 31a and 32a.

Through holes 31f and 32f are formed in the connection portions 31a and 32a, and fasteners 51 and 52 pass through the through holes 31f and 32f to allow the positive electrode current collectors 21p and 22p and the negative electrode current collector ( It is fastened to the through-holes 21g, 22g, 21f, and 22f of 21n and 22n.

The connecting portions 31b and 32b are bent in the direction orthogonal to the connecting portions 31a and 32a, and in particular, the connecting portions 31b and 32b are designed to have an optimized allowable area to allow the maximum flow of current. Would be preferred. As described above, the connection portions 31b and 32b have a certain allowable area, thereby making it easier to charge and discharge large currents.

In addition, cutouts 31c and 32c are partially formed at lower ends of the connection portions 31b and 32b, and the cutout portions 31c and 32c have connection portions 31b and 32b, and fasteners 51 and 52 made of a conductive material. This is to prevent contact with).

The second cap 130 is mounted on the upper portion of the first cap 120, and the upper surface of the first cap 120, the anode and cathode connectors 31 and 32, and the vent 125 are disposed by the second cap 130. Side walls 125a and the like are concealed.

The second cap 130 corresponds to the first flat walls 131 and 132 corresponding to the first flat walls 111 and 112 of the casing 110 and the second flat walls 113 and 114 of the casing 110. 2nd planar wall 133,134, the closing surface 135, and the opening 136 which opposes this closing surface 135 are shown.

Each of the first flat walls 131 and 132 is formed to have a relatively thin thickness, and thus has accommodation grooves 131a and 132a, and the connection portion of the positive electrode connector 31 described above in the accommodation grooves 131a and 132a. 31b and the connecting portion 32b of the cathode connector 32 can be accommodated. In this way, the connecting portions 31b and 32b of the connecting bodies 31 and 32 are accommodated in the receiving grooves 131a and 132a of the second cap 130, thereby increasing the degree of freedom of design for the allowable area of the connecting portions 31b and 32b. Can be.

The second cap 130 has a first through hole 135a through which the upper end of the vent 125 passes, and has two or more second through holes 135b on its closed surface 135, and a second through hole ( The positive electrode terminal 41 and the negative electrode terminal 42 pass through 135b). The positive electrode terminal 41 and the negative electrode terminal 42 are electrically connected to the positive electrode connector 31 and the negative electrode connector 32.

The second cap 130 has one or more assembly protrusions 137 at the bottom edges of the first and second flat walls 131, 132, 133, and 134, and at least one assembly portion at the top edge of the first cap 120. It has a groove 127. As a result, assembling of the second cap 130 and the first cap 120 becomes very easy.

Meanwhile, in the exemplary embodiment illustrated in FIGS. 1 to 7, only two unit cells 21 and 22 are shown, but the present invention is not limited thereto. As illustrated in FIG. 8, four unit cells 21 and 22 are illustrated. , 23 and 24 may be installed in the casing 100. In addition, the number of unit cells 21 and 22, such as three, five, six, seven, etc., may be variously changed.

As such, when the number of unit cells 21 and 22 is changed to three, four, five, etc., correspondingly, the number of connecting portions 31a and 32a of the connecting bodies 31 and 32 is also three or four. Dog, five, and so on.

1 is a perspective view illustrating a rechargeable battery according to an exemplary embodiment of the present invention.

2 is an exploded perspective view illustrating a rechargeable battery according to an exemplary embodiment of the present invention.

3 is a bottom perspective view showing a second cap according to the present invention.

4 is a plan view of the casing according to the present invention.

5 is a front sectional view showing a casing according to the present invention.

6 is a front sectional view showing a secondary battery according to the present invention.

FIG. 7 is a detailed cross-sectional view illustrating an enlarged arrow A of FIG. 6.

8 illustrates another embodiment of the present invention.

Brief description of symbols for the main parts of the drawings

10: secondary battery 21, 22: unit battery

100: casing 110: compartment

120: first cap 130: second cap

Claims (14)

A casing having at least two flat surfaces and having a width greater than the thickness thereof, the casing having a hollow portion therein; Two or more cell units disposed in the hollow portion of the casing and separately having a positive electrode current collector and a negative electrode current collector connected in parallel; And And at least one compartment for partitioning the hollow part of the casing and for communicating electrolyte between the at least two unit cells. The method of claim 1, The compartment is a hexahedron having a width that can prevent a short between the adjacent unit cells, the lower end of the compartment is characterized in that the secondary battery to form a communication path by being spaced apart from the lower end of the casing. The method of claim 1, A secondary battery according to claim 1, wherein a guide groove and a guide protrusion are formed to correspond to each other at portions of the casing and the partition. The method of claim 3, The guide groove and the guide protrusion is a secondary battery, characterized in that the dovetail structure. The method of claim 1, The compartment has a hollow portion therein, the hollow portion is a secondary battery, characterized in that the upper and lower portions are opened. The method of claim 1, The casing has an opening, the opening is sealed by a first cap, and the positive electrode collector and the negative electrode collector of each of the unit cells are drawn out through the first cap, and the positive electrode collector of the two or more unit cells. The anode collectors are connected through at least one anode connector, and the cathode collectors of the at least two unit cells are connected through at least one cathode connector. Secondary battery. The method of claim 6, The anode connector and the cathode connector may include two or more connections electrically connected to each of the positive electrode current collector and the negative electrode current collector, and one or more connection portions connecting the connection portions. Secondary battery. The method of claim 7, wherein The connection part is bent in a direction perpendicular to the connection portion, the secondary battery, characterized in that a partial cutout is formed at the lower end of the connection portion. The method of claim 6, The first cap is a secondary battery, characterized in that further comprises a vent communicate with the hollow portion of the casing. The method of claim 6, The vent, A sidewall extending upward from an upper surface of the first cap and having upper and lower portions thereof open; A horizontal wall formed inside the sidewall in a horizontal direction and having a first through hole communicating with a hollow portion of the casing; A vent cap detachably coupled to an upper inner diameter surface of the side wall and having a second through hole at an upper surface thereof; A valve body installed to be movable up and down in the first through hole; And And a resilient body biasing the valve body downward. The method of claim 10, The secondary battery, characterized in that the sealing ring is provided in the contact portion between the valve body and the first through-hole. The method of claim 8, The second cap is mounted on the upper portion of the first cap, the second cap is a secondary battery, characterized in that concealing the first cap, the positive electrode and the negative electrode connector. The method of claim 12, The second cap has a secondary battery, characterized in that it has an accommodating groove for receiving the connecting portion of the connector on the inner side. The method of claim 12, Secondary battery, characterized in that the coupling groove and the assembly protrusion is formed to correspond to each other in the portion coupled to the second cap and the first cap.

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