The present disclosure relates to the field of batteries, and in particular, to a device with a sheet structure for detecting liquid leakage of battery.
With the rapid development of new energy fields, such as electric vehicles and energy storage power stations, lithium-ion power batteries, lead-acid storage batteries, and other electrochemical batteries are put to use. For electric vehicles, energy storage power stations, and other environments, it is necessary to use a large number of batteries connected in parallel and/or series to form high-voltage battery packs. However, due to the huge number of batteries, unqualified technologies, abuse, and other reasons, the safety problems of batteries are increasingly prominent, and liquid leakage of battery is common. The liquid leakage of battery means that a liquid inside the battery flows out from a gas safety valve or other joints of the battery. The liquid leakage of battery has a great impact on performance of the battery, and severe liquid leakage of battery may cause a short circuit of the battery. The short circuit of the battery is the most dangerous battery failure mode, which may cause battery combustion or even explosion. Therefore, detection of liquid leakage of battery is very important for safe operation of the battery.
In the prior art, in order to ensure the safe and effective operation of the battery, a state of the battery is detected and managed mainly by a battery management module. At present, the battery management module mainly measures a voltage, a temperature, and a charging/discharging current of the battery, and monitors insulation of a system. Only when the battery leaks to a certain extent, for example, when the battery is short-circuited with a battery box, an early warning against system insulation reduction is given, so as to inform relevant personnel to repair the battery. However, this method has some limitations on timeliness of liquid leakage detection of the battery. That is to say, an early warning is not given before the battery is short-circuited with the battery box, and detection results lag behind, which makes it impossible to give an early warning against liquid leakage of battery in time.
In order to solve the above problems, an objective of the present disclosure to provide a device with a sheet structure for detecting liquid leakage of battery, to quickly detect a liquid leakage state of the battery, reduce lag of a detection result, and feed back detection information in time.
To achieve the objective of the present disclosure, the following technical solutions are used:
A device with a sheet structure for detecting liquid leakage of battery includes a housing made of an insulating material, and a first detection element and a second detection element that are arranged in the housing and each are made of a conductive material, where the first detection element and the second detection element are spaced apart by the housing and thus are not in contact with each other; multiple detection channels are provided in a bottom surface of the housing, and a layer of gap extending in a horizontal direction is provided inside the housing, and an inner end of each detection channel is in communication with the gap; a first collecting end of the first detection element is provided on an outer surface of the housing, and a first detection end of the first detection element is provided in the gap and is adjacent to the detection channel; a second collecting end of the second detection element is provided on the outer surface of the housing, and a second detection end of the second detection element is provided in the gap and is adjacent to the detection channel.
Preferably, the housing includes a bottom plate and a cover plate provided above the bottom plate, the bottom plate comprises a detection area, and the multiple detection channels are located in the detection area; a bottom surface of the cover plate is provided with an accommodating area recessed upward, and a shape of the accommodating area is adapted to a shape of the detection area and the accommodating area is located above the detection area, so that the gap is formed between the bottom plate and the cover plate.
Preferably, the housing is in a shape of a thin plate or a slice; and the detection area in the bottom plate has a thickness not greater than 2 mm.
Preferably, the detection channels each has a height not greater than 2 mm; and multiple detection channels are densely provided in the detection area to cover most of a surface of the detection area.
Preferably, the first detection element has a plurality of first detection ends, the second detection element has a plurality of second detection ends, two sides of each detection channel is provided with one first detection end and one second detection end, and the plurality of first detection ends and the plurality of second detection ends extend along a lengthwise direction of the detection channels.
Preferably, the first detection element and the second detection element are respectively provided at two ends of the detection channels, and the first detections end and the second detection ends extend in opposite directions.
Preferably, the first detection element includes a first trunk provided on a side of the bottom plate, a plurality of first branches are provided on a side of the first trunk, and the plurality of first branches are the plurality of first detection ends; each first branch extends along of the lengthwise direction of the detection channels, and an end portion of the first branch terminates on an end portion of the detection channel; a first collecting member is provided at an end of the first trunk, and an end portion of the first collecting member extends out of the outer surface of the housing.
Preferably, the second detection element includes a second trunk provided on a side of the bottom plate, a plurality of second branches are provided on a side of the second trunk, and the plurality of second branches are the second detection ends; each second branch extends along a side of the detection channel, and an end portion of the second branch terminates on an end portion of the detection channel; a second collecting member is provided at an end of the second trunk, and an end portion of the second collecting member extends out of the outer surface of the housing.
To sum up, the present disclosure has the advantages that detection channels are provided at a bottom of a housing, so that a leaked liquid can enter a gap inside the housing from the detection channels, and then a first detection end and a second detection end on two sides of each detection channel are connected together. Therefore, when liquid leakage of battery occurs, a first detection element is connected to a second detection element, and resistance between a first collecting end and a second collecting end is hence reduced, and it is hence determined that liquid leakage of battery occurs. The device can improve timeliness and accuracy of a detection result.
The present application provides a device with a sheet structure for detecting liquid leakage of battery, which is usually provided on a safety valve of a battery or at a joint of a battery housing. The device is configured to detect liquid leakage of battery at these positions.
In order to facilitate assembly between the bottom plate 200 and the cover plate 100, the bottom plate and the cover plate may be connected in a detachable manner such as insertion or snap-fit connection, or the bottom plate 200 and the cover plate 100 may be integrally formed. For example, in this embodiment, the bottom plate 200 and the cover plate 100 are connected to each other in an inserted manner through concave-convex fitting. Specifically, an upper surface of the bottom plate 200 is provided with a plurality of cylindrical protruding points 210, and a lower surface of the cover plate 100 is provided with grooves (not shown) corresponding to the protruding points 210. During assembly, the protruding points 210 are inserted into the grooves to assemble the cover plate 100 and the bottom plate 200 together. Obviously, the positions of the protruding points 210 and the grooves can be interchanged, which does not affect assembly of the bottom plate 200 and the cover plate 100.
As shown in
As shown in
As shown in
In this embodiment, these detection channels 230 are distributed in a length direction of the bottom plate 200 and extend in a straight line in a width direction, so that the detection channels 230 are densely distributed in the bottom plate 200. Therefore, the detection channels 230 can cover most of the surface of the bottom plate 200, so that the leaked liquid from each position on the bottom plate 200 can enter a detection channel 230 at a corresponding position. It should be noted that the detection channel 230 may alternatively extend in a curved manner, for example, the detection channel 230 is in the shape of an arc or a crease line.
As shown in
The first detection element 300 and the second detection element 400 each have a plurality of detection ends, and these detection ends are distributed on two sides of the detection channel 230 and are located in the gap 500. That is, an upper surface of each detection end is in contact with the gap 500. When there is a leaked liquid in the detection channel 230, the leaked liquid flows into the gap 500 and then flows into the detection end. When the detection end of the first detection element 300 is connected to the detection end of the second detection element 400 by the leaked liquid, the first detection element 300 is connected to the second detection element 400. At this time, the resistance between the first detection element 300 and the second detection element 400 is measured, and it is found that the resistance is significantly reduced, which is used as a standard for detecting liquid leakage of battery. For example, a battery management system can monitor a resistance value between the first detection element 300 and the second detection element 400 in real time, and monitor the resistance value between the first detection element 300 and the second detection element 400 while detecting information such as a voltage, a temperature and a current of the battery.
As shown in
Similarly, the second detection element 400 has a second collecting end 401, and the second collecting end 401 also extends out to the surface of the housing. Specifically, in this embodiment, the second collecting end 401 extends out to the top surface of the cover plate 100. The second detection element 400 further has multiple second detection ends 402. The second detection ends 402 are distributed on a side of the detection channel 230, and extend in the same direction around the detection channel 230, so as to ensure that the leaked liquid at any position in the detection channel 230 can be in contact with the second detection ends 402.
Further, as shown in
Optionally, as shown in
More specifically, as shown in
The second detection element 400 includes a second trunk 410, and the second trunk 410 is provided on the other side (lower side in
During use of the device, the bottom surface of the bottom plate 200 is provided on the battery housing. Under normal circumstances, the first detection element 300 and the second detection element 400 are spaced apart by the bottom plate 200, so that a resistance value between the first collecting end 301 and the second collecting end 401 is infinite. When liquid leakage of battery occurs, the leaked liquid flows into the gap 500 along the detection channel 230, and finally flows into the first detection end 302 and the second detection end 402 on two sides of the detection channel 230. Therefore, the first detection element 300 is connected to the second detection element 400, so that the resistance value between the first collecting end 301 and the second collecting end 401 is significantly reduced, thereby determining that liquid leakage of battery occurs.
To sum up, the present disclosure has the advantages that detection channels 230 are provided at a bottom of a housing, so that a leaked liquid can enter a gap 500 inside the housing from the detection channels 230, and then a first detection end 302 and a second detection end 402 on two sides of each detection channel 230 are connected together. Therefore, a first detection element 300 is connected to a second detection element 400, and resistance between a first collecting end 301 and a second collecting end 302 is reduced, thereby determining liquid leakage of battery. The device can improve timeliness and accuracy of a detection result.
The above is the description of the embodiments of the present disclosure. The above description of the disclosed embodiments enables those skilled in the art to achieve or use the present disclosure. Multiple modifications to these embodiments are readily apparent to those skilled in the art. The general principles defined herein may be practiced in other embodiments without departing from the spirit or scope of the present disclosure. Therefore, the present disclosure is not limited to these embodiments shown herein, but falls within the widest scope consistent with the principles and novel features disclosed herein.
Number | Date | Country | Kind |
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202211633946.2 | Dec 2022 | CN | national |
This application is a continuation of International Patent Application No. PCT/CN2023/138804 with a filing date of Dec. 14, 2023, designating the United States, now pending, and further claims priority to Chinese Patent Application No. 202211633946.2 with a filing date of Dec. 19, 2022. The content of the aforementioned application, including any intervening amendments thereto, is incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/CN2023/138804 | Dec 2023 | WO |
Child | 18749323 | US |