KR20220135373A - Liquid leakage detector for electrolyte of battery - Google Patents

Abstract

The present invention relates to a device for detecting an electrolyte leakage in a battery that can easily and quickly determine an electrolyte leakage through an inspection chamber accommodating an electric vehicle battery. To this end, a device for detecting an electrolyte leakage in a battery includes: an inspection chamber in which a space for accommodating the battery is provided, a door for accommodating and withdrawing the battery is installed, and contact between external air and the battery is blocked through the door; a leakage detection sensor installed inside the chamber to detect a volatile organic solvent leaking from the battery; an electric flow tester receiving a signal from the leakage detection sensor to inspect and determine whether or not the electrolyte of the battery leaks and how electrically stable the battery is; an intake unit installed at one lower end of the inspection chamber to suck external air into the inspection chamber using a suction fan; and an exhaust unit installed at the center of the upper part or the upper end of one side of the inspection chamber to discharge the internal air in the inspection chamber to the outside using each exhaust fan.

Description

Electrolyte leak detection device for battery

The present invention relates to an electrolyte leak detection device for a battery.

In general, a secondary battery refers to a battery that can be charged and discharged, unlike a primary battery that cannot be charged.

As an example, in the case of a low-capacity battery in which one battery cell is packaged in a pack form, it is mainly used in portable small electronic devices such as portable terminals, notebook computers, computers, and camcorders. As another example, a large-capacity secondary battery in which a plurality of battery cells are connected in series or in parallel is used in the case of a power source for driving a motor such as a device requiring large power, for example, an electric vehicle.

Such a secondary battery can be manufactured in various forms, and as a representative example, it is manufactured in the form of a pouch type, a cylindrical shape, a prismatic shape, and the like. Among them, the pouch-type shape is relatively free and light in weight, so it is used a lot in portable electronic devices that require slimming and light weight in recent years. In addition, it is also used in electric vehicles.

An electrolyte solution is filled in the inner receiving space of the secondary battery. If the electrolyte filled inside the secondary battery leaks, a problem may be induced.

In particular, since a lithium secondary battery uses a volatile organic solvent, it is harmful to the human body during leakage and inhalation, and may cause safety accidents such as fire.

For example, when electrolyte leakage occurs in a local area, corrosion may occur as air is gradually introduced. This causes damage to the secondary battery and each part of the system device including the secondary battery. However, it takes a lot of time to systematically recognize the leakage of the electrolyte.

In particular, leakage of electrolyte in a secondary battery for a vehicle may cause a serious error in the vehicle control system by breaking insulation and causing corrosion of contacted parts. As a result, when a problem such as vehicle damage occurs, it may cause serious safety problems such as human disaster. Nevertheless, it was difficult for the vehicle occupant to determine the electrolyte leakage directly through the naked eye.

Republic of Korea Patent Publication No. 10-2018-0095257 (Title of the invention: electric vehicle battery pack and method for detecting coolant leakage of electric vehicle battery pack, published on August 27, 2018) Republic of Korea Patent Publication No. 10-1220485 (Title of the invention: battery electrolyte leakage blocking device, published on February 22, 2012)

The present invention was devised in view of the above points, and it is an object of the present invention to provide an electrolyte leakage detection device for a battery capable of quickly and easily determining an electrolyte leakage through an inspection chamber accommodating an electric vehicle battery.

According to a preferred embodiment for achieving the above object of the present invention, the electrolyte leakage detection device of the battery according to the present invention is provided with a space for accommodating the battery, and a door for accommodating and withdrawing the battery is installed, so that the door a test chamber that blocks contact between external air and the battery through a leak detection sensor installed inside the test chamber to detect a volatile organic solvent leaking from the battery An electric flow tester that inspects and determines whether electrolyte leakage and electrical stability, an intake part installed at a lower end of one side of the test chamber to suck outside air into the test chamber using an intake fan, and an upper center of the test chamber Alternatively, it may include an exhaust unit installed at an upper end of one side and discharging the internal air of the test chamber to the outside using each exhaust fan.

The test chamber may include an inclined footrest installed at the front lower end to guide the wearing of the battery.

The door may open and close the test chamber by being folded open or unfolded and closed.

The leak detection sensor may include a reference sensor installed at the upper end of the outer part of the test chamber to record an electrolyte leak state, and a monitoring sensor installed in the upper center of the inner part of the test chamber to monitor an electrolyte leak state.

The electricity flow tester may be linked with the leak detection sensor to set and control standards for testing and judging whether the electrolyte is leaking and electrical safety.

The intake unit may include a suction blower to which the intake fan is connected, and the suction blower may include a diffuser for diffusing the sucked air into the test chamber.

The exhaust unit may include an exhaust fan for monitoring and an exhaust fan for ventilation connected to a ventilation port outside the building, and a diffuser may be installed in each of the exhaust fan for monitoring and the exhaust fan for ventilation.

According to the apparatus for detecting electrolyte leakage of a battery according to the present invention, economic loss due to electrolyte leakage of the battery can be prevented by quickly and easily determining the leakage of electrolyte through the test chamber accommodating the electric vehicle battery.

In addition, by quickly detecting when a small amount of electrolyte has leaked from the secondary batteries installed in various devices of electric vehicles, it prevents the possibility of problems caused by large amount of leakage in advance, thereby preventing damage to the devices and electric vehicles. can improve the safety of

1 is a view showing an electrolyte leakage detection device of a battery according to an embodiment of the present invention.
2 is a diagram showing the configuration of an electrolyte leakage detection device of a battery according to an embodiment of the present invention.
3 is a diagram illustrating a procedure for inspecting a battery using an electrolyte leakage detection device according to an embodiment of the present invention.

Hereinafter, an embodiment of an apparatus for detecting electrolyte leakage of a battery according to the present invention will be described with reference to the accompanying drawings. At this time, the present invention is not limited or limited by the examples. In addition, in describing the present invention, detailed descriptions of well-known functions or configurations may be omitted to clarify the gist of the present invention.

1 is a view showing an electrolyte leakage detection device of a battery according to an embodiment of the present invention. 2 is a diagram showing the configuration of an electrolyte leakage detection device of a battery according to an embodiment of the present invention.

1 and 2, the electrolyte leak detection device 1 of the battery according to the present invention includes a test chamber 10, a leak detection sensor 20, an electric flow tester 30, an intake unit 40, and A battery pack or a battery module (hereinafter referred to as a battery) may be inserted into the test chamber 10 of the electrolyte leakage detection device 1 and the electrolyte leakage state of the battery 2 may be inspected. .

In this embodiment, the test chamber 10 of the electrolyte leak detection device 1 is provided with a space for accommodating the battery 2, and the door 11 for accommodating and withdrawing the battery 2 is provided at the front. It is installed to block the contact between the battery 2 and the outside air through the door 11, and the battery 2 is placed in the test chamber 10 to detect the electrolyte leakage of the battery 2 used in the electric vehicle. After that, the door 11 is closed to block the outside air. The test chamber 10 performs powder coating.

The leak detection sensor 20 is installed inside the test chamber 10 to detect volatile organic compounds leaking from the battery 2 , and the leak detection sensor 20 is the main component of the electrolyte. It is possible to detect a carbonate-based organic solvent, which is a component. The detection range of the volatile organic solvent is 0 to 32,000 ppb, and the detection range of carbon dioxide is 400 to 29,000.

The electricity flow tester 30 receives a signal from the leak detection sensor 20 to inspect and determine whether the electrolyte of the battery 2 has leaked and electrical safety, and the electric flow tester 30 is a control unit (not shown). not), it is possible to determine the suitability of the battery electrolyte for leaking through the control unit.

In addition, the intake unit 40 is installed at the lower end of one side of the inspection chamber 10 to suck outside air into the inspection chamber 10 using an intake fan 41 , and the exhaust unit 50 is inspected. The air inside the test chamber 10 may be discharged to the outside by using each exhaust fan 51 installed at the upper center or upper end of one side of the chamber 10 .

That is, the electrolyte leakage detecting device 1 detects electrolyte leaking from the battery 2 in a state in which the battery 2 is accommodated in the test chamber 10, and the battery ( 2) After wearing, the door 11 is closed to block the inflow of external air, and in this state, external air is introduced into the inspection chamber 10 through the intake fan 41 of the intake unit 40, and the The electrolyte leakage test is performed while the air inside the test chamber 10 is discharged to the outside through the exhaust fan 51 of the exhaust unit 50 .

In this embodiment, the test chamber 10 is installed in the front lower end to include an inclined footboard 12 to guide the wearing of the battery 2, the inclined footboard 12 has a height of at least 40mm while removing the jaws of the test chamber 10 , it is possible to more effectively put the battery 2 into the test chamber 10 .

In addition, the door 11 can be opened and closed by being folded and opened or unfolded and closed while moving through the hydraulic cylinders 13 installed on both sides because the door 11 is foldable.

In addition, the leak detection sensor 20 is installed at the upper end of the outer part of the test chamber 10 to record the electrolyte leak state, and the reference sensor 21 is installed in the inner upper center of the test chamber 10 to record the electrolyte leak. It may include a monitoring sensor 22 for monitoring the condition.

By transmitting the signals of the reference sensor 21 and the monitoring sensor 22 to the electricity flow tester 30 and interworking with each other, various situations according to the electrolyte leakage of the battery 2 can be stored, determined, and controlled.

That is, the electricity flow tester 30 may be linked with the leak detection sensor 20 to set and control criteria for testing and judging whether the electrolyte is leaking or not and electrical stability. The electricity flow tester 30 may be connected to the control unit to store and manage the test result of the electrolyte leakage.

In this embodiment, the intake part 40 of the electrolyte leakage detecting device 1 includes a suction blower 42 to which an intake fan 41 is connected, and the suction blower 42 receives the sucked air into the inspection chamber. (10) It may include a diffuser (43) to diffuse inside.

In addition, the exhaust unit 50 includes an exhaust fan for monitoring (51a), and an exhaust fan (51b) for ventilation connected to a ventilation port outside the building, and the exhaust fan for monitoring (51) and the exhaust fan for ventilation ( 51 , each diffuser 53 may be installed.

An intake blower 42 and an exhaust blower 52 are installed in the intake part 40 and the exhaust part 50, and diffusers 43 and 53 are installed in the intake blower 42 and the exhaust blower 52, respectively. It can diffuse the air by converting the flow of air to low speed and high pressure.

In addition, the electrolyte leakage detection device 1 uses a vision or a camera to find traces of electrolyte leakage, and by installing the vision or camera inside or outside the test chamber 10, traces of electrolyte leakage can be found.

3 is a diagram illustrating a procedure for inspecting a battery using an electrolyte leakage detection device according to an embodiment of the present invention.

Referring to FIG. 3 , in the process of inspecting the electrolyte leakage of the battery 2 using the electrolyte leakage detection device 1 , the inspection chamber 10 is opened by first operating the door 11 of the inspection chamber 10 . In this state, the battery 2 to be tested is put inside the test chamber 10, and the electric flow tester 30 is used in a state in which the door 11 is operated and the test chamber 10 is closed. An electrolyte leak test is performed.

After measuring leakage through the electricity flow tester 30 while operating the exhaust fan 51 for monitoring of the exhaust unit 50 for about 30 seconds, the suitability of electrolyte leakage is determined, and the result is stored.

When the electrolyte leakage test is completed, the test chamber 10 is opened, the battery 2 is withdrawn from the test chamber 10, the test chamber 10 is closed, and in this state, the ventilation exhaust The fan 51 is operated for about 1 minute to ventilate the inside of the test chamber 10 .

Therefore, the electrolyte leakage detection device 1 can prevent economic loss due to electrolyte leakage of the battery 2 by quickly and easily determining the electrolyte leakage through the test chamber 10 housing the electric vehicle battery 2 . have.

In addition, by quickly detecting when a small amount of electrolyte has leaked from the secondary batteries installed in various devices of electric vehicles, it prevents the possibility of problems caused by large amount of leakage in advance, thereby preventing damage to the devices and electric vehicles. can improve the safety of

In the foregoing, the present invention has been shown and described in connection with preferred embodiments for illustrating the principles of the present invention, but the present invention is not limited to the construction and operation as shown and described as such. Rather, it will be apparent to those skilled in the art that many changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims.

1: Electrolyte leak detection device 2: Battery
10: test chamber 11: door
12: inclined foot plate 13: hydraulic cylinder
20: leak detection sensor 21: reference sensor
22: monitoring sensor 30: electrical flow checker
40: intake unit 41: intake fan
42: suction blower 43: diffuser
50: exhaust unit 51: exhaust fan
51a: exhaust fan for monitoring 51b: exhaust fan for ventilation
52: exhaust blower 53: diffuser

Claims (8)

an inspection chamber provided with a space for accommodating the battery and provided with a door for accommodating and withdrawing the battery to block contact between external air and the battery through the door;
a leak detection sensor installed inside the test chamber to detect a volatile organic solvent leaking from the battery;
an electricity flow tester for receiving a signal from the leak detection sensor and inspecting and determining whether the electrolyte of the battery has leaked and electrical stability;
an intake unit installed at a lower end of one side of the inspection chamber to suck outside air into the inspection chamber using an intake fan; and
and an exhaust unit installed at the upper center or one upper end of the test chamber to exhaust the internal air of the test chamber to the outside using each exhaust fan. The method of claim 1,
The test chamber is installed in the lower front portion of the battery electrolyte leakage detection device including an inclined foot for guiding the wearing of the battery. The method of claim 1,
The door is opened by folding or unfolding and closing the test chamber, characterized in that the battery electrolyte leakage detection device. The method of claim 1,
The leak detection sensor includes a reference sensor installed at the upper end of the outer part of the test chamber to record an electrolyte leak state, and a monitoring sensor installed in the upper center of the inner part of the test chamber to monitor the electrolyte leak state. Device. 5. The method of claim 4,
The electric flow tester is an electrolyte leak detection device for a battery, characterized in that in conjunction with the leak detection sensor, the electrolyte leak detection device, characterized in that for setting and controlling the test and determination criteria for whether the electrolyte is leaking and electrical safety. The method of claim 1,
The intake part includes a suction blower to which the intake fan is connected, and the suction blower includes a diffuser for diffusing the sucked air into the test chamber. The method of claim 1,
The exhaust unit includes an exhaust fan for monitoring and an exhaust fan for ventilation connected to a ventilation port outside the building, wherein the exhaust fan for monitoring and the exhaust fan for ventilation are each provided with a diffuser. . The method of claim 1,
A battery electrolyte leakage detection device, characterized in that it finds traces of electrolyte leakage using a vision or a camera.

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