KR102618295B1 - Liquid leakage detector for electrolyte of battery - Google Patents

Abstract

The present invention relates to a battery electrolyte leak detection device that can easily and quickly determine electrolyte leakage through an inspection chamber accommodating an electric vehicle battery.
For this purpose, the battery electrolyte leak detection device includes a test chamber equipped with a space for accommodating the battery, a door for receiving and withdrawing the battery, and blocking contact between external air and the battery through the door, and the test chamber. A leakage detection sensor installed inside the chamber to detect volatile organic solvent leaking from the battery, an electric flow tester that receives a signal from the leakage detection sensor to inspect and determine whether the electrolyte of the battery is leaking and electrical stability, and the tester An intake unit installed at the lower end of one side of the chamber and sucking outside air into the inside of the test chamber using an intake fan, and an intake part installed at the upper center or upper part of one side of the test chamber and sucking the inside of the test chamber using each exhaust fan. It includes an exhaust unit that exhausts air to the outside.

Description

Battery electrolyte leak detection device {LIQUID LEAKAGE DETECTOR FOR ELECTROLYTE OF BATTERY}

The present invention relates to a device for detecting electrolyte leakage from a battery.

In general, secondary batteries refer to batteries that can be charged and discharged, unlike primary batteries that cannot be recharged.

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

Such secondary batteries can be manufactured in various shapes, and representative examples include pouch-shaped, cylindrical, and square shapes. Among them, the pouch-type shape is relatively free and light in weight, so it has recently been widely used in portable electronic devices that require slimming and lightweighting. In addition, it is also used in electric vehicles, etc.

The inner accommodation space of the secondary battery is filled with electrolyte. If the electrolyte filled inside the secondary battery leaks, a problem may occur.

In particular, lithium secondary batteries use volatile organic solvents, which are harmful to the human body when leaked or inhaled, and can cause safety accidents such as fire.

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

In particular, electrolyte leakage from a vehicle secondary battery can destroy insulation and cause corrosion of contacted parts, causing serious errors in the vehicle control system. As a result, if problems such as vehicle damage occur, it can lead to serious safety problems such as human disasters. Nevertheless, it was difficult for vehicle occupants to directly determine electrolyte leakage with the naked eye.

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

The present invention was created in consideration of the above points, and its purpose is to provide a battery electrolyte leak detection device that can easily and quickly determine electrolyte leakage through an inspection chamber accommodating an electric vehicle battery.

According to a preferred embodiment for achieving the object of the present invention described above, the device for detecting electrolyte leakage of a 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, and the door a test chamber that blocks contact between external air and the battery, a liquid leak detection sensor installed inside the test chamber to detect volatile organic solvent leaking from the battery, and a liquid leak detection sensor that receives a signal from the liquid leak detection sensor to determine the level of the battery. An electric flow tester that inspects and determines electrolyte leakage and electrical stability, an intake unit installed at the bottom of one side of the test chamber to suck outside air into the inside of the test chamber using an intake fan, and the upper center of the test chamber. Alternatively, it may include an exhaust unit installed at the upper end of one side to discharge 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 portion to guide the wearing of the battery.

The door can be folded to open or unfolded to close to open and close the inspection chamber.

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

The electric flow tester can set and control standards for inspection and judgment of electrolyte leakage and electrical safety in conjunction with the leakage detection sensor.

The intake unit may include a suction blower to which the intake fan is connected, and the suction blower may include a diffuser that diffuses the intake air into the interior of the test chamber.

The exhaust unit includes a monitoring exhaust fan and a ventilation exhaust fan connected to an external ventilation outlet of the building, and each of the monitoring exhaust fan and the ventilation exhaust fan may be equipped with a diffuser.

According to the battery electrolyte leak detection device according to the present invention, it is possible to easily and quickly determine electrolyte leakage through an inspection chamber accommodating an electric vehicle battery, thereby preventing economic loss due to electrolyte leakage from the battery.

In addition, by quickly detecting small amounts of electrolyte leakage from secondary batteries mounted on various devices of electric vehicles, the possibility of problems arising from large-scale leakage is prevented in advance. This prevents damage to the devices and also prevents damage to the electric vehicle. can improve safety.

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

Hereinafter, an embodiment of a battery electrolyte leak detection device according to the present invention will be described with reference to the attached drawings. At this time, the present invention is not limited or limited by the examples. Additionally, when describing the present invention, detailed descriptions of well-known functions or configurations may be omitted to make the gist of the present invention clear.

1 is a diagram illustrating a device for detecting electrolyte leakage of a battery according to an embodiment of the present invention. Figure 2 is a diagram showing the configuration of a device for detecting electrolyte leakage of a battery according to an embodiment of the present invention.

Referring to Figures 1 and 2, the battery electrolyte leak detection device 1 according to the present invention includes an inspection chamber 10, a leak detection sensor 20, an electric flow tester 30, an intake unit 40, and It includes an exhaust unit 50, and the electrolyte leakage state of the battery 2 can be inspected by inserting a battery pack or battery module (hereinafter referred to as battery) into the test chamber 10 of the electrolyte leak detection device 1. .

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

The leak detection sensor 20 is installed inside the test chamber 10 to detect volatile organic compounds (Volatile Organic Compounds) leaking from the battery 2. The leak detection sensor 20 is the main component of the electrolyte. Carbonate-based organic solvents can be detected. 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 electric flow tester 30 receives a signal from the liquid leak detection sensor 20 to inspect and determine whether the electrolyte of the battery 2 is leaking and the electrical safety. The electric flow tester 30 includes a control unit (not shown). It is connected to the control unit to determine the suitability of battery electrolyte leakage.

In addition, the intake unit 40 is installed at the lower end of one side of the test chamber 10 and sucks external air into the inside of the test chamber 10 using the intake fan 41, and the exhaust part 50 is used for inspection. It is installed at the upper center or upper end of one side of the chamber 10 and can exhaust the air inside the test chamber 10 to the outside using each exhaust fan 51.

That is, the electrolyte leak detection device 1 detects electrolyte leaking from the battery 2 while the battery 2 is accommodated inside the test chamber 10, and the battery (2) is stored in the test chamber 10. 2) After putting in, the door 11 is closed to block the inflow of outside air, and in this state, outside air is introduced into the test 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 includes an inclined step 12 installed at the front lower portion to guide the wearing of the battery 2, and the inclined step 12 has a height of at least 40 mm. At the same time, the problem of the test chamber 10 is eliminated, and through this, the battery 2 can be loaded into the test chamber 10 more effectively.

In addition, the door 11 is foldable and moves through hydraulic cylinders 13 installed on both sides to open and close the test chamber 10 by being folded open or unfolded.

In addition, the leak detection sensor 20 is a reference sensor 21 installed on the outer top of the test chamber 10 to record the state of electrolyte leak, and a reference sensor 21 installed at the upper center of the inner part of the test chamber 10 to detect electrolyte leak. It may include a monitoring sensor 22 that monitors the state.

By transmitting signals from the reference sensor 21 and the monitoring sensor 22 to the electric flow tester 30 and interconnecting them, various situations according to electrolyte leakage of the battery 2 can be stored, judged, and controlled.

That is, the electric flow tester 30 can establish and control standards for inspection and judgment of electrolyte leakage and electrical stability in conjunction with the leakage detection sensor 20. The electric flow tester 30 is connected to the control unit to store and manage the test results of electrolyte leakage.

In this embodiment, the intake unit 40 of the electrolyte leak detection device 1 includes a suction blower 42 to which an intake fan 41 is connected, and the suction blower 42 supplies the sucked air to the test chamber. It may include a diffuser 43 for diffusing the interior of (10).

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

A suction blower 42 and an exhaust blower 52 are installed in the intake unit 40 and the exhaust unit 50, and diffusers 43 and 53 are installed in the intake blower 42 and the exhaust blower 52, respectively. The air can be diffused by converting the air flow to low speed and high pressure.

In addition, the electrolyte leak detection device 1 uses a vision or a camera to find traces of electrolyte leakage. The vision or camera can be installed inside or outside the inspection chamber 10 to find traces of electrolyte leakage.

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

Referring to FIG. 3, the process of inspecting the electrolyte leakage of the battery 2 using the electrolyte leakage detection device 1 involves first opening the test chamber 10 by operating the door 11 of the test chamber 10. In this state, the battery 2 to be tested is placed inside the test chamber 10, and the door 11 is operated to close the test chamber 10, using the electric flow tester 30. An electrolyte leak test is performed.

The monitoring exhaust fan 51 of the exhaust unit 50 is operated for approximately 30 seconds to measure leaked liquid through the electric flow tester 30, the suitability of the electrolyte leaked liquid is determined, and the result is stored.

When the electrolyte leakage test is completed, the test chamber 10 is opened, the battery 2 is taken out of the test chamber 10, and the test chamber 10 is closed. In this state, the ventilation exhaust is turned on. The fan 51 is operated for approximately 1 minute to ventilate the inside of the test chamber 10.

Therefore, the electrolyte leak detection device 1 can easily and quickly determine electrolyte leakage through the inspection chamber 10 that accommodates the electric vehicle battery 2, thereby preventing economic loss due to electrolyte leakage of the battery 2. there is.

In addition, by quickly detecting small amounts of electrolyte leakage from secondary batteries mounted on various devices of electric vehicles, the possibility of problems arising from large-scale leakage is prevented in advance. This prevents damage to the devices and also prevents damage to the electric vehicle. can improve safety.

Although the present invention has been shown and described in connection with preferred embodiments for illustrating the principles of the invention, the invention is not limited to the construction and operation as shown and described. Rather, those skilled in the art will understand that numerous 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: inspection chamber 11: door
12: Inclined footrest 13: Hydraulic cylinder
20: Leak detection sensor 21: Reference sensor
22: Monitoring sensor 30: Electric 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 a battery and a door for receiving 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 volatile organic solvent leaking from the battery;
An electric flow tester that receives a signal from the leak detection sensor to inspect and determine whether the electrolyte of the battery is leaking and electrical stability;
an intake unit installed at a lower end of one side of the test chamber to suck external air into the test chamber using an intake fan; and
an exhaust unit installed at the upper center or upper end of one side of the test chamber to exhaust air inside the test chamber to the outside using each exhaust fan; Including,
The test chamber includes an inclined step installed at the front lower portion to guide the loading of the battery, and the inclined step has a height of at least 40 mm and eliminates the protrusion of the test chamber,
The door is foldable and opens and closes the test chamber by being folded open or unfolded while moving through hydraulic cylinders installed on both sides. delete delete According to claim 1,
The leak detection sensor detects electrolyte leakage in a battery, including a reference sensor installed on the outer top of the test chamber to record the electrolyte leakage state, and a monitoring sensor installed in the upper center of the inner part of the test chamber to monitor the electrolyte leakage state. Device. According to claim 4,
The electric flow tester is an electrolyte leak detection device for a battery, characterized in that it establishes and controls standards for inspection and judgment of electrolyte leakage and electrical safety in conjunction with the leakage detection sensor. According to claim 1,
The intake unit includes a suction blower to which the intake fan is connected, and the suction blower includes a diffuser that diffuses the sucked air into the test chamber. According to claim 1,
The exhaust unit includes a monitoring exhaust fan and a ventilation exhaust fan connected to an external ventilation opening of the building, and the monitoring exhaust fan and the ventilation exhaust fan each have a diffuser. A battery electrolyte leak detection device. . According to claim 1,
A battery electrolyte leak detection device characterized by finding traces of electrolyte leakage using vision or a camera.

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