KR20210014291A - Leakage prevention structure of lead-acid battery with labyrinth path - Google Patents

Abstract

The present invention relates to a leakage preventing structure of a lead-acid battery for providing a labyrinth leakage moving path, and more specifically, to a leakage preventing structure of a lead-acid battery for providing a labyrinth leakage moving path capable of making a path to a vent hole into a labyrinth structure when an electrolyte leaks from an injecting port and maximally delaying a reverse flow rate of the electrolyte when the lead-acid battery is tilted or vibrated. Provided is the leakage preventing structure of a lead-acid battery for providing a labyrinth leakage moving path capable of providing a structure which is more difficult to move than a conventional general vent path structure.

Description

Leakage prevention structure of lead-acid battery with labyrinth path}

The present invention relates to a leak-proof structure of a lead acid battery providing a path for a maze leakage, and more particularly, a path to a vent hole when an electrolyte leaks from an injection port is made into a labyrinth structure, so that the lead acid battery is inclined. It relates to a leakage prevention structure of a lead acid battery that provides a maze leakage movement path capable of delaying the reverse flow rate of an electrolyte solution to the maximum when it loses or vibrates.

Lead-acid batteries supply charged electricity by discharging, and because the process of charging and discharging is repeated for an allowed number of times, a secondary battery or storage battery that can be reused repeatedly (hereinafter referred to as'lead storage battery' It is called.).

Lead acid batteries are classified into various types according to the material used as the positive electrode, negative electrode, and electrolyte (hereinafter referred to as'electrolyte'), and the composition using lead as the electrode and sulfuric acid as the electrolyte is classified as a lead acid battery. .

Electrodes of lead acid batteries are largely divided into positive and negative electrode plates and poles, and contain separators and electrolytes that physically and electrically divide each electrode, and are stored or accommodated in the case, so they are built-in, and hydrogen generated during charging and discharging. In general, a gas exhaust port is provided in a sealed case in order to discharge gas generated by evaporation of gas and electrolyte.

As an example, a lead acid battery operates on the principle of repeating discharge and charging through a reversible reaction of the chemical reaction formula PbO2 + H2SO4 ↔ PbSO4 + 2H2O. The generated electricity is discharged and output, and the input electricity is charged and stored.

A lead acid battery uses a chemical reaction in which an electrode plate made of lead dioxide (PbO2) and an electrolyte containing a sulfuric acid solution (H2SO4) are converted into lead sulfate (PbSO4) and water (H2O), and lead sulfate (PbSO4) and water ( When it changes to H2O), it generates and discharges electricity, and when it is charged, it repeats the reverse substitution.

Whenever such a chemical reaction is carried out, heat is generated inside the lead acid battery, so that some of the electrolyte is evaporated and a small amount of hydrogen gas is generated, so the generated gas must be discharged to the outside to prevent explosion.

In addition, vehicle lead acid batteries are exposed to vibrations and inclinations generated while the vehicle is moving without filtration, and at this time, the electrolyte must be prevented from leaking to the outside through a gas exhaust port.

The technology for discharging the gas generated from the inside of the lead acid battery to the outside is based on the prior art, and patent application No. 10-2000-72402 (2000 Dec 01) of'evaporative gas emission structure of automobile battery' and patent application No. 10-2008 There are'Bent Plugs for Nickel-Hydrogen Batteries' in 20115 (2008 05 29).

1 is a functional configuration diagram of a device according to an example of the prior art, which blocks leakage of lead acid battery electrolyte and discharges gas.

Hereinafter, referring to the accompanying drawings, gas generated inside the lead acid battery is discharged through the housing 11, and the housing 11 is formed integrally with the case on the upper surface of the lead acid battery case.

At this time, the housing 11 has a cylindrical shape having a predetermined diameter and height, and the case 20 of the lead acid battery forms a cell and accommodates the positive electrode plate 21, the negative electrode plate 22, the separator 23 and the electrolyte. .

The housing 11 communicates with the cell of the case 20 through a vent hole, a valve 13 is inserted into the vent hole, and a packing 15 for enhancing adhesion with the valve 13 is provided around the upper end of the vent hole. do.

A thread is formed on the inner periphery of the housing 11, and the vent cap 12 and the spring 14 are threaded on the outer periphery to be screwed.

Another vent hole for discharging gas is formed at the upper end of the vent cap 12.

In the prior art, the gas generated inside the lead acid battery is discharged to the outside by the elasticity of the spring 14, and there is an advantage of automatically discharging the gas when it is generated above a predetermined pressure.

However, in the prior art, there is a problem in that gas is not smoothly discharged due to a defect in the spring 14.

In addition, since the overall configuration is complex and the number of parts is large, there is a problem that the production process is complicated and the manufacturing time is required, thereby increasing the manufacturing cost.

In addition, there is a problem that the gas discharge and electrolyte leakage blocking device according to the prior art must be provided in units of cells.

On the other hand, when the spring operates in a state in which vibration and inclination occurs and gas is discharged, there is a problem that the electrolyte leaks unprotected, and a part of the leaked electrolyte accumulates between the valve and the vent cap and corrodes the spring.

In addition, when the spring is corroded, the elasticity is weakened, so even when the pressure of the gas is low, the valve is opened and there is a problem that a malfunction in which the electrolyte leaks unprotected is repeated.

Therefore, although the gas inside the lead acid battery is discharged smoothly, leakage of the electrolyte is difficult and the number of components is not increased, so a structure capable of maintaining a constant manufacturing cost is required.

On the other hand, the Republic of Korea Patent Publication No. 10-1220485 discloses a battery electrolyte leakage blocking device.

When described in detail with reference to FIG. 2 attached to Patent Document 2, the lead acid battery 1000 includes a case 100, a lower cover 200, and an upper cover 300.

The case 100 is also referred to as a precursor, and is in the form of a box with one side open, and accommodates and contains an anode and a cathode plate, a separator, a pole and an electrolyte inside, and includes ABS resin, Beckrite resin, PP resin, etc. It is molded from a material selected from synthetic resin types.

The lower cover 200 is made of the same type of material as the case 100, and is configured to double-inject the positive and negative terminals 270 connected to the electrode plate and the pole by welding or fusion, and the case 100 Because it is bonded to the open part of the case 100 by fusion, the inner space of the case 100 is kept in a sealed state.

The upper cover 300 is made of the same type of material as the case 100 and the lower cover 200, and forms an exhaust port 304 through which gas generated inside the case 100 is naturally discharged, and the lower cover ( 200) and welded together in a sealed state.

The lead acid battery 1000 is composed of a plurality of cells, and is generally composed of six cells, and each cell generally includes a connection passage through which liquid and gas can flow in a case portion.

Hereinafter, the lower cover 200 will be described in detail with reference to FIG. 3, one side wall 201, a communication hole 202, a first blocking film 203, a first through hole 204, and a second blocking film ( 205, the lower wall 206, the second through hole 207, the third blocking film 208, the other side wall 209, the first labyrinth film 210, the second labyrinth film 211, the upper wall 212 ), a first inclined surface 213, a second inclined surface 214, a cell 250, and a chamber 260.

One side wall 201, the other side wall 209, the lower side wall 206, and the upper side wall 212 form a rectangular cell 250 in the lower cover 200.

The communication hole 202 is a hole that communicates the inner space formed by the case 100 and the space formed by the cell 250 and is formed in a circular shape.

The first blocking film 203 is formed to be connected to one side wall 201 and blocks a part of the periphery of the communication hole 202. In the drawing, the direction of the upper wall 212 of the communication hole 202 is blocked.

The second blocking film 205 forms a first through hole 204 between the first blocking film 203 while the first blocking film 203 is formed in an extended shape, and a part around the communication hole 202 is formed. In the drawing, the direction of the other side wall 209 is blocked.

The third barrier layer 208 is formed in a connection state with the lower wall 206 and is formed in parallel with the second barrier layer 205 at an interval to block a part of the periphery of the communication hole 202. In the drawing, the other side wall 209 ) Blocking direction.

The third blocking film 208 is formed in parallel with the second blocking film 205 at predetermined intervals to form a second through hole 207.

Therefore, the communication hole 202 is formed in a shape surrounded by the one side wall 201 and the lower side wall 206, the first blocking film 203, the second blocking film 205 and the third blocking film 208.

The first maze film 210 is connected to the second blocking film 205 adjacent to the first through hole 204 and is formed to extend obliquely in the direction of the other side wall 209, and extends obliquely toward the upper wall 212 in the drawing. It is shown as being.

The second labyrinth film 211 is connected to the other side wall 209 and extends in parallel with the first labyrinth film 210 at a predetermined interval, and in the drawing, it is formed to extend obliquely in the direction of the lower wall 206 to form a maze. maze) is shown as molding.

The first inclined surface 213 forms the bottom surface of the cell 250 and is formed in an inclination in which the direction of the lower wall 206 is low and the direction of the upper wall 212 is high.

At this time, the first inclined surface 213 may further form an inclined surface separated by a step while maintaining the same inclination.

The second inclined surface 214 is formed in a chamber 260 in which a part of the lower wall 206 communicates with an open portion and forms a separate space in a direction opposite to the first inclined surface 213.

In the configuration according to Patent Document 2, the electrolyte leaked through the communication hole 202 is first blocked by the first blocking film 203, the second blocking film 205, and the third blocking film 208, and at the same time, the first slope It is naturally returned to the communication hole by (213).

At this time, some of the electrolyte leaked through the first through hole 204 and the second through hole 207 passes through the long labyrinth formed by the first labyrinth film 210 and the second labyrinth film 211 and thus leaks. The resistance is increased to make it difficult to discharge, and at the same time, the leakage resistance is further increased by the first inclined surface 213, making it more difficult to discharge.

Therefore, leakage is secondarily blocked by the resistance of the maze and the first inclined surface 213, and the electrolyte that has not been discharged flows back through the first through hole 204 and the second through hole 207, and the communication hole 202 It is re-injected into the interior of the case 100 through the water exchange.

And the electrolyte that leaks through the maze and the resistance of the first inclined surface 213 moves to the chamber 260, and the chamber 260 has a second inclined surface 214 having an inclination opposite to the first inclined surface 213 Because of the molding, the electrolyte is subjected to a greater resistance and the leakage is blocked in the third order.

Above all, the location of the chamber 260 is located at the center in the width direction of the battery 1000, so even when the vibration and inclination applied in the width direction of the battery 1000 are large, leakage resistance of the electrolyte is increased to prevent leakage. It works.

That is, in the structure of the battery 1000, since the chamber 260 is formed at the center and upper side of the width, a structure is provided that prevents leakage of the electrolyte even at maximum vibration and inclination.

As described above, the prior art also provides various structures to prevent leakage of the electrolyte, but there is a need to develop a structure to provide a labyrinth structure that makes it more difficult to move the electrolyte. I came to propose.

Korean Patent Application No. 10-2000-72402 Korean Registered Patent Publication No. 10-1220485

Therefore, the present invention was devised to solve the above conventional problems,

An object of the present invention is to make the path to the vent hole in a labyrinth structure when the electrolyte is leaked from the injector, so that when the lead acid battery is inclined or vibrated, it is possible to delay the reverse flow rate of the electrolyte as much as possible.

In order to achieve the problem to be solved by the present invention, the leakage prevention structure of a lead acid battery providing a labyrinth leakage movement path according to an embodiment of the present invention,

The first circular portion 200 formed in a circular shape so as to surround the discharge portion 100, and having a first moving groove 210 formed on one side thereof; and

The second moving groove 310 is formed in a circular shape to be larger than the diameter of the first circular part at a location spaced apart from the first circular part by a predetermined distance, and is spaced a predetermined distance from the location of the first moving groove 210 The second circular portion 300 is formed; And

The third moving groove 410 is formed in a circular shape to be larger than the diameter of the second circular portion at a position spaced a predetermined distance from the outer side of the second circular portion, and is spaced a predetermined distance from the position of the second moving groove 310 The third circular portion 400 is formed; And

A first round part 500 formed under the third circular part to have a predetermined length, one side connected to the vent hole extension part 1100, and the other side separated by a predetermined distance from the vertical partition wall part 150; And

The first round part 500 is formed to have a certain length under the side, one side is connected to the vent hole extension part, the other side is connected to the vertical partition wall part, and a second round part groove 610 is formed at any one position. By being configured to include a second round portion 600 for forming a groove, the problem of the present invention is solved.

The leakage prevention structure of the lead acid battery providing the labyrinth leakage movement path according to the present invention,

When the electrolyte leaks from the injection port, the path to the vent hole is made into a labyrinth structure, and when the lead acid battery is inclined or vibrated, the reverse flow rate of the electrolyte can be delayed to the maximum.

As a result, a leakage prevention structure of a lead acid battery is provided that provides a labyrinth leakage movement path to provide a structure that is more difficult to move than a conventional conventional vent path structure.

1 is a functional configuration diagram of an apparatus for blocking leakage of a lead acid battery electrolyte and discharging gas according to the prior art.
Figure 2 is a perspective view of a case of a lead acid battery according to the prior art, a lower cover and an upper cover are assembled by fusion bonding.
3 is a plan view of a lower cover of a lead acid battery of the prior art.
4 is a plan view showing a conventional vent path structure.
5 is a perspective view showing a conventional vent path structure (Vent Path Design).
6 is a plan view showing a leakage preventing structure of a lead acid battery providing a maze leakage moving path according to an embodiment of the present invention.
7 is a perspective view showing a leakage preventing structure of a lead acid battery providing a labyrinth leakage movement path according to an embodiment of the present invention.

The leakage preventing structure of the lead acid battery providing a labyrinth leakage movement path according to an embodiment of the present invention,

The first circular portion 200 formed in a circular shape so as to surround the discharge portion 100, and having a first moving groove 210 formed on one side thereof; and

The second moving groove 310 is formed in a circular shape to be larger than the diameter of the first circular part at a location spaced apart from the first circular part by a predetermined distance, and is spaced a predetermined distance from the location of the first moving groove 210 The second circular portion 300 is formed; And

The third moving groove 410 is formed in a circular shape to be larger than the diameter of the second circular portion at a position spaced a predetermined distance from the outer side of the second circular portion, and is spaced a predetermined distance from the position of the second moving groove 310 The third circular portion 400 is formed; And

A first round part 500 formed under the third circular part to have a predetermined length, one side connected to the vent hole extension part 1100, and the other side separated by a predetermined distance from the vertical partition wall part 150; And

The first round part 500 is formed to have a certain length under the side, one side is connected to the vent hole extension part, the other side is connected to the vertical partition wall part, and a second round part groove 610 is formed at any one position. It characterized in that it is configured to include; a second round portion 600 for the groove configuration.

In this case, according to an additional aspect, the vent hole extension portion vertical partition wall portion 700 formed perpendicular to the lower side of the vent hole extension portion; characterized in that it is configured to further include.

At this time, on the left side of the vertical partition wall part 700 for the vent hole extension part,

By further including a first round portion 500a and a second round portion 600a for forming a groove, the leakage fluid moving path 2000 is further extended.

At this time, on the right side of the vertical partition wall part 700 for the vent hole extension part,

At least two groups are formed by combining the first round part 500 and the second round part 600 for forming a groove as a group, and the second round part 600 for forming a groove is formed downward based on the vent hole extension part 1100. First, by configuring the first round unit 500, it is characterized in that the leakage fluid moving path 2000 is further extended.

At this time, the first circular portion 200, the second circular portion 300, and the third circular portion 400 is characterized in that the electrolyte leakage is first blocked.

At this time, the leakage of the electrolyte is prevented by allowing the leaked liquid that has passed the primary blocking to flow along the first round part 500, and again passes through the second round part groove 610 formed in the second round part 600 for forming a groove. It is characterized in that the secondary blocking.

At this time, the leakage fluid that has passed through the secondary blocking is made to flow along the first round part 500 formed on the right side of the vertical partition wall part 700 for the vent hole extension part, and again, the second round part 600 By passing through the second round groove 610, it is characterized in that the electrolyte leakage is thirdly blocked.

At this time, a first moving groove 210 formed in the first circular portion 200, a second moving groove 310 formed in the second circular portion 300, and a third moving groove formed in the third circular portion 400 410 is characterized in that it is formed at a 120 degree angle obtained by dividing the 360 degree angle into three.

Hereinafter, it will be described in detail through an embodiment of a leakage preventing structure of a lead acid battery providing a labyrinth leakage movement path according to the present invention.

The vent hole of the lead acid battery is located in the upper cover.

At this time, in the case of the electrolyte stored inside the lead acid battery, when an inert material increases in the electrode plate due to long-term use, the performance of the battery is greatly reduced and heat is generated.

Due to this, electrolyte gas may be generated through the vent hole existing on the side of the cover. This is because H20 and H2SO4 coexisting in the electrolyte react by heat, so that the gas may leak to the outside. In severe cases, the smell of sulfur gas may occur outside, and when such sulfuric acid gas is generated, the occurrence of gas in the battery may even double inside the battery, and in severe cases, electrolyte leakage may occur, which greatly affects the performance and stability of the battery. Can affect.

Therefore, in the present invention, in order to prevent accidental accidents due to electrolyte leakage, the path to the vent hole when the electrolyte is leaked from the following injection port is made into a labyrinth structure, and when the lead acid battery is inclined or vibrated, the electrolyte is It provides a structure that can delay the backflow speed of the vehicle to the maximum.

4 is a plan view showing a conventional vent path structure.

5 is a perspective view showing a conventional vent path structure (Vent Path Design).

The leakage preventing structure of a conventional lead acid battery has a structure as shown in FIGS. 4 to 5, which is defined as a vent path structure.

Specifically, a first leakage path guide part 20 is formed on one side of the discharge part 10 to extend vertically from the upper wall 13, and a second leakage path guide part 20 is formed at a predetermined distance from the upper wall. As shown in the figure, the leakage path guide part 30 is formed.

That is, if the first leakage path guide part 20 is in the shape of a'b' shape, the second leakage path guide part 30 is formed in a'b' shape.

Through this, the leakage flow path is provided.

In addition, an inclined block 14 is formed on one side of the second leak path guide 30 to be inclined, and the other side of the inclined block is connected to one side wall 12 to provide an inclined fluid leakage moving path. The leakage that has passed through the first leakage path guide 20 and the second leakage path guide 30 moves to the vent hole extension 50 formed below the discharge part and prevents it from moving to the vent hole 40 as much as possible. It is done.

However, the conventional leakage prevention structure described above can delay the leakage as much as possible if the electrolyte leakage occurs in the vent hole when the battery is displaced from the vertical to a certain angle due to vibration from the engine or the state of the path due to the short leakage path. There is no structure.

Accordingly, various structures capable of delaying this have been studied, and a labyrinth structure capable of improving the above-described problems has been provided through the present invention.

In other words, in general, lead-acid batteries have a vent hole on the final cover so that hydrogen gas after chemical reaction can be discharged.

In addition, an electrolyte (sulfuric acid) is contained so that the current generated from the active material of the electrode plate can move.

Therefore, there cannot be a complete sealing between the electrolyte and the vent hole, so when the battery is laid at a certain angle from the vertical due to vibration from the engine or the condition of the road, electrolyte leakage occurs in the vent hole.

If a leak occurs, it can be dangerous to the driver due to vehicle damage and short circuit. Various structures are being studied to delay this.

6 is a plan view showing a leakage preventing structure of a lead acid battery providing a labyrinth leakage movement path according to an embodiment of the present invention.

7 is a perspective view showing a leakage preventing structure of a lead acid battery providing a labyrinth leakage movement path according to an embodiment of the present invention.

As shown in Figs. 6 to 7, the leakage preventing structure of the lead acid battery providing a labyrinth leakage movement path,

The first circular portion 200 formed in a circular shape so as to surround the discharge portion 100, and having a first moving groove 210 formed on one side thereof; and

The second moving groove 310 is formed in a circular shape to be larger than the diameter of the first circular part at a location spaced apart from the first circular part by a predetermined distance, and is spaced a predetermined distance from the location of the first moving groove 210 The second circular portion 300 is formed; And

The third moving groove 410 is formed in a circular shape to be larger than the diameter of the second circular portion at a position spaced a predetermined distance from the outer side of the second circular portion, and is spaced a predetermined distance from the position of the second moving groove 310 The third circular portion 400 is formed; And

A first round part 500 formed under the third circular part to have a predetermined length, one side connected to the vent hole extension part 1100, and the other side separated by a predetermined distance from the vertical partition wall part 150; And

The first round part 500 is formed to have a certain length under the side, one side is connected to the vent hole extension part, the other side is connected to the vertical partition wall part, and a second round part groove 610 is formed at any one position. It is configured to include; a second round portion 600 for forming a groove.

Specifically, the first circular portion 200 is formed in a circular shape so as to surround the discharge portion 100, and the first moving groove 210 is formed on either side.

For example, the first moving groove is formed in the 1 o'clock direction.

In addition, the second circular portion 300 is formed in a circular shape so as to be larger than the diameter of the first circular portion at a position spaced apart from the first circular portion by a predetermined distance.

At this time, it is characterized in that the second moving groove 310 is formed at a position spaced apart from the position of the first moving groove 210 by a predetermined distance.

For example, the second moving groove is formed at 11 o'clock.

In addition, the third circular portion 400 is formed in a circular shape to be larger than the diameter of the second circular portion at a position spaced apart from the second circular portion by a predetermined distance.

At this time, it is characterized in that the third moving groove 410 is formed at a position spaced apart from the position of the second moving groove 310 by a predetermined distance.

For example, the third moving groove is formed at the 6 o'clock position.

That is, a first moving groove 210 formed in the first circular portion 200, a second moving groove 310 formed in the second circular portion 300, and a third moving groove formed in the third circular portion 400 410 is to lengthen the leakage flow path as much as possible by forming a 360 degree angle to a 120 degree angle divided into three.

As a result, the first circular portion 200, the second circular portion 300, and the third circular portion 400 are characterized in that the electrolyte leakage is first blocked.

And, the leakage preventing structure of the lead acid battery providing the labyrinth leakage movement path of the present invention,

A first round part 500 formed under the third circular part to have a predetermined length, one side connected to the vent hole extension part 1100, and the other side separated by a predetermined distance from the vertical partition wall part 150; And

The first round part 500 is formed to have a certain length under the side, one side is connected to the vent hole extension part, the other side is connected to the vertical partition wall part, and a second round part groove 610 is formed at any one position. It is configured to further include; a second round portion 600 for forming a groove.

That is, the first round part 500 is formed to be rounded to a predetermined length under the third circular part, and one side is connected to the vent hole extension 1100, and the other side is separated from the vertical partition 150 by a certain distance. To be formed.

Through this, the flow path of the leakage fluid is maximized.

In addition, the second round portion 600 for forming a groove is formed to have a predetermined length under the first round portion 500, one side is connected to the vent hole extension portion, and the other side is formed to be connected to the vertical partition wall portion. .

At this time, the second round portion groove 610 is formed at any one position in order to provide a path for moving the leakage fluid.

By configuring as described above, the leakage liquid that has passed the primary blockage flows along the first round portion 500, and again passes through the second round portion groove 610 formed in the second round portion 600 for groove construction, It is characterized in that the secondary blocking electrolyte leakage.

On the other hand, according to an additional aspect, the vent hole extension vertical partition wall portion 700 formed perpendicular to the lower side of the vent hole extension portion; characterized in that it comprises a further.

As shown in FIGS. 6 to 7, by forming the vertical partition wall part 700 for the vent hole extension part, it is possible to design a structure to complicate the movement path on the left and right sides of the partition wall part.

That is, on the left side of the vertical partition wall part 700 for the vent hole extension part,

By further including the first round portion 500a and the second round portion 600a for forming a groove, the leakage fluid moving path 2000 can be further extended.

In addition, the first round portion 500a and the second round portion 600a for forming a groove may be formed as one group, and a plurality of groups may be arranged to be separated from each other at regular intervals downward.

This will allow the leakage flow path to be further extended.

On the other hand, according to another additional aspect, on the right side of the vertical partition wall portion 700 for the vent hole extension,

At least two groups are formed by combining the first round part 500 and the second round part 600 for forming a groove as a group, and the second round part 600 for forming a groove is formed downward based on the vent hole extension part 1100. First, by configuring the first round unit 500, it is characterized in that the leakage fluid moving path 2000 is further extended.

That is, a second round part 600 for forming a groove is formed immediately below the vent hole extension part 1100, and a first round part 500 is formed immediately below, and a second round part for forming a groove under it By configuring 600 and configuring the first round part 500 immediately below, the leakage fluid moving path 2000 is further extended.

By configuring as described above, the leakage liquid that has passed the secondary blockage is made to flow along the first round part 500 formed on the right side of the vertical partition wall part 700 for the vent hole extension part, and again, the second round part 600 for groove construction. ) By passing through the second round portion groove 610 formed in), it is characterized in that the electrolyte leakage is thirdly blocked.

In addition, although one maze structure is described in the exemplary embodiment of the present invention, it is natural that the maze structure is also formed in the left region based on the central side wall 3000.

At this time, it is natural that the vent hole extension 1100 and the vent hole are respectively formed on the left and right sides of the central side wall.

Through the present invention, when the electrolyte is leaked from the injection port, the path to the vent hole is made into a labyrinth structure, and when the lead acid battery is inclined or vibrated, the reverse flow rate of the electrolyte can be delayed as much as possible. Is done.

As a result, a leakage prevention structure of a lead acid battery is provided that provides a labyrinth leakage movement path to provide a structure that is more difficult to move than a conventional conventional vent path structure.

Those skilled in the art to which the present invention with the above contents pertains will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. Therefore, the embodiments described above are exemplified in all respects and should be understood as non-limiting.

100: discharge part
200: first circular part
210: first moving groove
300: second circular part
310: second moving groove
400: third circular part
410: 3rd moving groove
500, 500a: 1st round part
600, 600a: second round part for groove construction
700: Vertical bulkhead for vent hole extension
1100: Vent hole extension
2000: leakage flow path

Claims (5)

In the leakage prevention structure of the lead acid battery providing a labyrinth leakage movement path,
A first circular portion 200 formed in a circular shape so as to surround the discharge portion 100 and having a first moving groove 210 formed on one side thereof; and
The second moving groove 310 is formed in a circular shape to be larger than the diameter of the first circular part at a location spaced apart from the first circular part by a predetermined distance, and is spaced a predetermined distance from the location of the first moving groove 210 The second circular portion 300 is formed; And
The third moving groove 410 is formed in a circular shape to be larger than the diameter of the second circular portion at a position spaced a predetermined distance from the outer side of the second circular portion, and is spaced a predetermined distance from the position of the second moving groove 310 The third circular portion 400 is formed; And
A first round part 500 formed under the third circular part to have a predetermined length, one side connected to the vent hole extension part 1100, and the other side separated by a predetermined distance from the vertical partition wall part 150; And
The first round part 500 is formed to have a certain length under the side, one side is connected to the vent hole extension part, the other side is connected to the vertical partition wall part, and a second round part groove 610 is formed at any one position. A leak prevention structure of a lead acid battery that provides a labyrinth leakage movement path, comprising: a second round part 600 for forming a groove.
The method of claim 1,
A leak prevention structure for a lead acid battery that provides a labyrinth leakage movement path, characterized in that it further comprises a; vertical partition wall portion 700 for the vent hole extension portion formed perpendicular to the lower side of the vent hole extension portion.
The method according to claim 1 or 2,
On the left side of the vertical partition wall part 700 for the vent hole extension part,
By further including a first round part 500a and a second round part 600a for forming a groove, the leakage prevention of lead acid batteries providing a labyrinth leakage movement path further extends the leakage movement path 2000 rescue.
The method of claim 1,
The leakage prevention structure of a lead acid battery providing a maze leakage movement path, characterized in that the first circular portion 200, the second circular portion 300, and the third circular portion 400 block electrolyte leakage first .
The method of claim 4,
The leaked liquid that has passed the primary blocking flows along the first round part 500, and passes through the second round part groove 610 formed in the second round part 600 for forming a groove again, thereby preventing the leakage of the electrolyte. Leakage prevention structure of a lead acid battery providing a maze leakage movement path, characterized in that blocking.

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