KR20120134698A - Overcharge prevent apparatus for battery-cell of secondary battery - Google Patents

Abstract

PURPOSE: A device for preventing overcharge of a secondary battery cell is provided to be easily installed because of no limit for an install location of a switch for sensing expansion force of a battery cell. CONSTITUTION: A device for preventing overcharge of a secondary battery cell comprises a switch part(10) controlling a battery power by sensing expansion load of a secondary battery cell(20), and a switch bracket(30) installed inside a battery case and in which the switch part is fixed. The switch part comprises an elastic cover for sensing expansion load; a circuit board forming a via hole for transferring the load to the cover; a switch receiving the load transferred to the cover; a connector controlling battery power by on/off of the switch; and a case accommodating the cover, circuit board, switch and connector.

Description

Overcharge Prevent Apparatus for Battery-cell of Secondary Battery

The present invention relates to an overcharge preventing device for a secondary battery, and more particularly, a battery management system (BMS) malfunctions, or even if power is not supplied, secondary sensing of overcharging of a battery cell physically prevents charging power. The present invention relates to an overcharge preventing device for a secondary battery battery cell.

In general, secondary batteries are rechargeable and have a large capacity, such as nickel cadmium, nickel hydrogen, and lithium ion batteries. In particular, the lithium ion battery has attracted attention as a next generation power source due to its excellent characteristics such as long service life and high capacity. However, when the lithium ion battery is exposed to an abnormal use environment such as overcharging, short circuit, reverse connection, and heat exposure, gas due to electrochemical action is generated inside the battery, thereby increasing the battery internal pressure. Increasing the internal pressure of the battery causes the battery to expand and in particular, if abnormal use time such as overcharging continues, the electrolyte or the active material is partially decomposed, and the internal pressure and temperature of the battery may rise rapidly, causing an explosion or fire.

For the above reasons, in order to verify the safety of the secondary battery, various thermal stability tests such as a high temperature storage test, a thermal shock test, a heat exposure test, as well as tests of overcharge, overdischarge, short circuit, reverse connection, etc., are performed. Under these thermal safety test conditions, there should be no explosion or ignition of the battery.

Attempts have been made to improve the safety of the secondary battery so far, and discharge the gas generated in the secondary battery through the rupture portion of the battery case or directly discharge the battery circuit using the rupture disk inside the battery. Blocking methods have been developed. In this case, when gas is generated in the situation such as overcharging and the internal pressure exceeds the design value, the sealing part is ruptured or the battery power is cut off to secure the internal pressure and ensure safety, but the spark generated during the rupture acts as an ignition source and explodes and ignites. There is a problem that causes.

1 is a cross-sectional view of a conventional overcharge preventing device of a secondary battery. As shown in the drawing, the secondary battery 4 is composed of a case 2 and an electrode assembly 3 to be housed by the secondary battery pack 1. The needle-shaped protrusion 5 is provided inside the secondary battery pack 1, and when the secondary battery 4 is overcharged, shorted, reversed, or the like, a temperature inside the secondary battery 4 is increased. As a result, the electrolyte, the active material, and the like inside the secondary battery 4 change to a gas state, causing the expansion of the secondary battery 4 to occur, and the secondary battery 4 swells.

When the secondary battery 4 is expanded beyond the set value, the needle-shaped protrusion 5 may rupture the sealing of the secondary battery 4 to prevent explosion and ignition of the secondary battery.

The prior art of protecting the secondary battery 4 as the protrusion 5 has a problem that additional production processes are required, resulting in low productivity and difficult to guarantee reliability of rupture. In addition, there is a problem in that the laminated part has a contradictory contradiction, which must simultaneously have a sealability and a rupture property. In addition, the rupture of the sealing portion due to the internal pressure of the battery has a problem that the harmful gas is discharged to adversely affect the damage to the electronic circuit and the human body installed in the vicinity.

In particular, in the case of a pouch type secondary battery battery cell, since the case is made of a flexible thin plate in which a metal material such as aluminum and a resin material such as a polymer resin are mixed, there is a problem in that a safety device according to the prior art is difficult to construct.

In order to solve the above problems, an overcharge preventing device of a secondary battery as shown in FIG. 2 has been known.

Referring to FIG. 2, the switch 160-1 is installed on the side of the battery cell 21 to detect the expansion force of the battery cells 21 and 22, and the charging power is turned on / off by the switch 160. Will be connected or disconnected.

The configuration of the overcharge preventing device of the secondary battery as shown in FIG. 2 still has the following problems.

First, since the configuration of the switch 160-1 is attached to the battery cell 21, it is difficult to control the charging power by sensing an appropriate inflation force of the battery cells 21 and 22. In other words, since it detects and controls a predetermined expansion force, it is not easy to apply to various battery cells having different operating voltages.

Second, since the outer surface of the battery cell is made of a flexible material, it is not easy to install the switch, and there is a problem in that the switch is separated when the cell is severely deformed.

Third, once a battery cell is expanded, it cannot be reused. However, since a conventional switch can be restored by elasticity, when the cell is reduced after expansion, there is a possibility of reactivation.

The present invention has been made to solve the above problems, an object of the present invention, adjacent to the secondary battery battery cell, it is configured by the switch bracket is fixed by the switch bracket there is no installation space constraint of the switch and easy to fix The present invention provides a battery cell overcharge preventing device for a secondary battery.

In addition, the present invention provides a battery cell overcharge preventing device for a secondary battery, which prevents reoperation even when the battery cell is reduced after expansion by applying a switch that does not return once the expansion of the battery cell is sensed.

In the overcharge preventing device of the present invention, the overcharge preventing device of a secondary battery battery cell comprising a switch unit for controlling the battery power by sensing the expansion load of the secondary battery battery cell, the prevention device, the switch unit is fixed, A switch bracket installed inside the battery case; And a control unit.

At this time, the switch unit, the cover of the elastic material for the expansion load detection; A circuit board positioned at a rear end of the cover and having a via hole for transmitting a load of the cover; A switch located at a rear end of the circuit board and receiving a load transferred to a cover; A connector for controlling battery power by on / off of the switch; A case accommodating the cover, the circuit board, the switch, and the connector; . ≪ / RTI >

In this case, the switch is characterized in that the non-return type does not return even if removed after the load is applied.

In addition, the switch unit, characterized in that fixed to the switch bracket via a guide pin provided on the case.

The overcharge preventing device of the secondary battery battery cell of the present invention according to the above configuration is easy to install because there is no restriction in the installation position of the switch for detecting the expansion force of the battery cell, and the separation distance from the outer surface of the battery cell is easy to control It is possible to accurately detect the expansion force of the various battery cells.

In addition, once the expansion of the battery cell is sensed, there is an effect of preventing the secondary risk due to the operation of the expanded battery cell by applying a switch that does not return.

1 and 2 is a conventional overcharge preventing device
3A is a schematic front view of a battery cell of a secondary battery;
3B is a side view of a battery cell in normal
3B is a side view of the battery cell when inflated
4 is a side view of the overcharge preventing device of the present invention
5 is an exploded perspective view of the switch unit of the present invention
6 is an exploded perspective view of the overcharge preventing device of the present invention
7 is an operation state diagram of the overcharge preventing device of the present invention

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

3A shows a front schematic view of a secondary battery of a pouch-type battery cell, FIG. 3B shows a side schematic view of the pouch-type battery cell, and FIG. 3C shows that the pouch-type battery cell is overcharged, short-circuited, and reversed. The pouch-type battery cell is inflated due to an expansion phenomenon due to a malfunction.

The battery cell 20 has a sealed structure. When the battery cell 20 is placed in an excessive state such as overcharge, short circuit, reverse connection, or heat exposure due to the characteristics of the sealed structure, gas is generated inside the battery cell 20 and expands. 20) may ignite or explode if chemicals such as electrolytes leak out or are severe.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

Referring to Figure 4, the overcharge preventing device of the present invention, the switch unit 10 and adjacent to the side of the battery cell 20 provided in the secondary battery, the switch unit 10 is fixed, It is configured to include a switch bracket 30 is fixed inside the secondary battery.

Referring to FIG. 5, the switch unit 10 includes a cover 11, a circuit board 12, a switch 13, a connector 14, and a case 15. The cover 11 is disposed on one side surface of the battery cell 20 adjacent to the side surface, and is made of an elastic rubber material. The cover switch 11a protrudes from one surface of the cover 11 toward the side surface of the battery cell 20. Therefore, when the battery cell 20 is expanded, the first contact with the cover switch 11a. When the cover 11 is made of an elastic material, not only the expansion of the battery cell 20 is detected but also the elasticity of the cover switch 11a is caused by the elasticity of the cover switch 11a when the battery cell 20 is contracted. The contraction of the can be detected. Therefore, even if the battery cell 20 is contracted after expansion, the cover 11 detects the contraction of the battery cell 20 to prevent the secondary battery from restarting.

The circuit board 12 is disposed on the other surface of the cover 11. The via hole 12a may be formed in a portion of the circuit board 12 corresponding to the cover switch 11a. The load of the cover switch 11a is transmitted to the switch 13 through the via hole 12a. The switch 13 is coupled to the rear end of the circuit board 12. The switch 13 is formed to protrude so that the sensing unit 13a is slidable on one surface of the switch 13 and is configured to be exposed on the via hole 12a. Therefore, when the end of the sensing unit 13a is exposed to the outside of one surface of the switch 13, the switch 12 is kept in an on state, and the sensing unit 13a is loaded by the sensing unit 13a by a load. When the end of the switch is located on the same line as one side of the switch 13, the switch 13 is turned off.

 At this time, the switch 13 receives the load due to the expansion of the battery cell 20 and the end of the sensing unit 13a is not affected even when the battery cell 20 contracts after the sensing unit 13a is operated. It is preferable that the switch 13 is configured of a non-return type switch that protrudes outward and does not return. Therefore, even when the battery cell 20 is expanded and contracted, there is an advantage that reactivation is prevented. The switch 13 can be manually turned on for reuse in the off state.

The connector 14 is disposed adjacent to the switch 13 at the rear end of the circuit board 12, and supplies or cuts off battery charging power according to on / off of the switch 13. The circuit board 12 and the connector 14 are applied to the conventional configuration to supply or cut off the power by the on / off of the switch 13, a detailed description thereof will be omitted.

The cover 11, the circuit board 12, the switch 13, and the connector 14 are accommodated in a case 15 having an enclosure and open on one side thereof, and assembled. Guide pins 15a are provided on the case 15 to facilitate coupling with the switch bracket 30 to be described later. The guide pin 15a may be formed in a hook type, and a plurality of guide pins 15a may be formed on the side surface of the case 15. Therefore, the switch unit 10 is fixed by fitting to the switch bracket 30 without the need for a separate bolt or screw.

Referring to FIG. 6, the switch bracket 30 has a plate shape. The switch bracket 10 is fixedly installed on the switch bracket 30, and the switch bracket 30 is fixedly installed inside the case of the secondary battery. Therefore, the overcharge preventing device of the present invention has an advantage that there is no position restriction of the switch unit 10 because it can be installed if only the space for fixing the switch bracket 30 is secured. The switch bracket 30 includes a switch via hole 31. One surface of the switch unit 10 is coupled to the switch via hole 31 so as to be exposed, and is fitted and fixed by the guide pin 15a. The switch via hole 31 is formed through the switch bracket 30. The cover switch 11a may be configured to protrude outwardly one surface of the switch bracket 30.

As shown in FIG. 7, the overcharge preventing device having the above configuration can freely adjust the distance L between the battery cell 20 and the switch unit 10, and thus can be applied to various battery cells having different operating voltages. There is.

The technical spirit should not be interpreted as being limited to the above embodiments of the present invention. Various modifications may be made at the level of those skilled in the art without departing from the spirit of the invention as claimed in the claims. Therefore, such improvements and modifications fall within the protection scope of the present invention, as will be apparent to those skilled in the art.

10 switch portion 11 cover switch
12: circuit board 13: switch
14 connector 15 case
20: battery cell
30: switch bracket 31: switch via hole

Claims (4)

In the overcharge preventing device of a secondary battery battery cell comprising a switch unit for controlling the battery power by sensing the expansion load of the secondary battery battery cell,
The prevention device,
A switch bracket fixed to the switch unit and installed inside the battery case; To include, Overcharge preventing device of a secondary battery battery cell.
The method of claim 1,
The switch unit,
An elastic cover for detecting an inflated load;
A circuit board positioned at a rear end of the cover and having a via hole for transmitting a load of the cover;
A switch located at a rear end of the circuit board and receiving a load transferred to a cover;
A connector for controlling battery power by on / off of the switch;
A case accommodating the cover, the circuit board, the switch, and the connector;
Consisting of, overcharge preventing device of a secondary battery battery cell.
The method of claim 2,
Wherein the switch comprises:
The secondary battery battery cell overcharge preventing device, characterized in that the non-return type does not return even if the load is removed after being applied.
The method of claim 2,
The switch unit,
The overcharge preventing device of the secondary battery battery cell is fixed to the switch bracket through a guide pin provided on the case.

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