KR20100000569U - Battery condition indicator - Google Patents

Abstract

The present invention relates to a battery indicator that can smoothly flow the gravity ball and improve the visibility, strong deformation, excellent assembly and mounting, and maintain a firm mechanical coupling and sealing state. The battery state indicator of the present invention includes a transparent head member 100 in which a lower portion of the battery is inserted into the battery and a coupling head which is coupled to an upper portion of the transparent pillar member 100 and inserted into an insertion hole formed in a case of the battery. And a storage case 300 coupled to a lower portion of the transparent pillar member 100 and having a specific gravity ball 400 therein, wherein the transparent pillar member 100 has an upper surface. An expansion flange part 110 exposed to the outside of the case of the battery; A pillar portion 120 extending downwardly of the expansion flange portion 110; A peak portion 130 formed at a lower end of the pillar portion 120 in a tip cone shape or a truncated cone shape; A latching jaw portion 121 extending and extending from the outer diameter of the pillar portion 120 gradually toward the upward direction adjacent to the expansion flange portion 110; And a convex lens part 140 formed on an upper surface of the expansion flange part 110 to enlarge an image of the specific gravity ball 400 transmitted from the pillar part 120, and the coupling head 200. The plurality of annular projections (211) protruding to the outside of the body 210 to maintain the sealing by forcibly elastically pressed into the insertion hole of the battery case; The body is inserted from the lower end of the pillar portion 120 in an upward direction to pass through the locking jaw portion 121 formed in the pillar portion 120 forcibly and elastically and then stops on the upper surface of the locking portion 121. An elastic locking jaw 212 formed inside the sieve 210, wherein the storage case 300 includes: a hub 310 forcibly elastically fitted to the outer circumference of the lower end of the pillar 120; An edge guard 320 integrally extending from both left and right sides of the hub 310 and having a front and rear surface open; Guide the lower gravity ball 400 protruding downward from the center of the lower surface of the rim guard 320 to descend to the left or right, the rising gravity ball 400 is the peak of the transparent pillar member 100 130 Mountain protrusion 321 for guiding to the center of the; It is formed in the shape of crossing the inside of the rim guard 320 to form a passage for guiding the rise and fall of the gravity ball 400 with the mountain protrusion 321, the transparent pillar member 100 in the upper center A transverse plate portion 330 having a through-hole formed in a shape that allows the specific gravity ball 400 to pass through while coinciding with the center of the apex 130; An extension lower end portion forms an electrolyte access passage 341a together with the mountain protrusion 321 while preventing the specific gravity ball 400 from extending outward from the front and rear surfaces of the transverse plate part 330 on either side. A downwardly extending fence portion 341; And extending from the other side of the front and back to the top of the mountain protrusion 321 to prevent the specific gravity ball 400 from being separated out of the upper end portion of the extension plate along with the transverse plate portion 330. An upwardly extending fence portion 342 is formed.

Accumulator, State, Indication, Charge, Discharge, Electrolyte, Specific Gravity, Ball

Description

Battery condition indicator {Battery condition indicator}

The present invention relates to a battery state indicator for optically displaying the state of the battery, and more specifically, the flow of the specific gravity ball can be smooth and improve the visibility, and furthermore, it is resistant to deformation, excellent in assembly and mounting, firm mechanical The present invention relates to a battery state indicator capable of maintaining a coupled state and a sealed state.

The battery state indicator uses the relationship between the change of the refractive index in the process of transferring the image by projecting the specific gravity ball that rises or sinks according to the change of the specific gravity of the electrolyte, and the state of charge and discharge of the battery and By displaying the color of the electrolyte shortage in the optical color, the viewer can easily distinguish between the charge and discharge state of the battery.

Various conventional examples of such a battery state indicator, Korean Patent No. 10-0420966, Patent No. 10-0533074, Patent No. 10-0643651, Patent No. 10-0704949, Utility Model Japanese Patent Application Laid-Open No. 20-0406571.

Conventional battery state indicators disclosed in the above-described publications, the transparent pillar member is installed in the casing of the battery so that its upper surface is exposed, and the colored specific gravity ball is provided at the end of the transparent pillar member immersed in the casing. By allowing the specific gravity ball to float or settle according to the specific gravity of the electrolyte, whether or not the colored image of the specific gravity ball is transferred to the upper surface of the transparent pillar member as the gravity ball contacts or moves away from the transparent pillar member. Thus, it is possible to check a good charge state or a discharge state of the battery.

In the conventional battery state indicator including the above-mentioned publications, in addition to the form of the fastening screw of the upper end to be installed directly on the upper end of the pillar member for installation in the battery case, a separate coupling head is assembled to the pillar member (Eg, the above-mentioned Patent Publications Nos. 10-0643651 and 10-0704949), which not only have to be coupled in an axial-hole fitting manner by inserting the coupling head from the bottom of the pillar member and fitting it up. Under the circumstances that the outer diameter of the joining head should be minimized, the pillar member could only be configured in a straight shape with a constant diameter over the entire length, so the tapered pillar member with a larger diameter at the top was used. Small projection cross-sectional area and less diffuse reflection has the disadvantage that the image of the gravity ball is small.

In addition, the conventional battery state indicator is, for example, in the form disclosed in Utility Model Registration No. 20-0406571, the shape of the specific gravity ball moving passage inclined only to one side to the specific gravity ball storage case coupled to the lower end of the pillar member. In addition, an arc-shaped seating part (or a guide part) having a shape of the specific gravity ball is formed on the bottom of the passage near the completion point of the specific gravity ball floating operation. It is to be contacted. Therefore, after the specific gravity ball is injured, the specific gravity ball is stuck to the inner wall of the storage case due to unexpected force such as the viscosity or surface tension of the electrolyte, and the specific gravity of the electrolyte is lowered so that the specific gravity ball cannot be lowered and hangs as it is. However, since the gravity ball is lowered and the arcing-type seating part is prevented from falling further, the specific gravity of the electrolyte is lowered.

In addition, there is also known a form in which the specific gravity ball moving passages are formed in both the left and right sides of the specific gravity ball storage case, as shown in the Utility Model Registration No. 20-0406571, the lower gate for storing the specific gravity ball Since the gate and its opening and closing parts are structurally fragile and easily deformed by the temperature rise of the electrolyte, there is a problem of preventing the smooth flow of the specific gravity ball.

In addition, in the conventional storage case, both side guide plates for accommodating the specific gravity balls do not support the consideration for allowing the electrolyte to smoothly communicate (entry in and out) and the specific gravity balls flow smoothly. There is this.

In addition, in the conventional battery state indicator, since the mechanical coupling between the pillar member and the coupling head is not firm, and the structure is easy to generate a gap, the pillar member and the coupling head do not maintain a solid state or the pillar member and the coupling head. There is a fear that the electrolyte may leak due to a minute gap formed in between.

The present invention was developed in order to solve all the problems of the conventional battery state indicator as described above, the flow of the specific gravity ball can be smooth and improve the visibility, and furthermore, it is resistant to deformation, excellent assembly and mounting It is an object of the present invention to provide a battery state indicator which enables to maintain a firm mechanically coupled state and a sealed state.

In order to achieve the above object, the battery state indicator according to the present invention includes a transparent pillar member in which a lower portion of the battery penetrates into the interior of the battery, and is coupled to an upper portion of the transparent pillar member to be pressed into an insertion hole formed in a case of the battery. A battery status indicator comprising a head and a storage case coupled to a lower portion of the transparent pillar member and storing specific gravity balls therein,

The transparent pillar member may include an expansion flange part whose upper surface is exposed to the outside of the case of the battery; A pillar portion extending downwardly below the expansion flange portion; A peak formed at a lower end of the pillar part in a tip or truncated shape; A latching jaw extending and extending from the outer diameter of the pillar to gradually increase in an upward direction adjacent to the expansion flange; And a convex lens portion formed on an upper surface of the flange portion to enlarge an image of the specific gravity ball transmitted from the pillar portion,

The coupling head may include: a plurality of annular protrusions protruding outwardly of the body to forcibly elastically press-fit the insertion holes of the battery case to maintain a seal; And an elastic locking jaw formed inside the body to be caught on the upper surface of the locking jaw portion after passing through the locking jaw portion formed in the pillar portion by being pushed upward from the lower end of the pillar portion.

The storage case may include a hub that is forcibly elastically fitted to the outer circumference of the lower end of the pillar portion; Edge guards integrally extended from the left and right sides of the hub and the front and rear surfaces are open; A ridge projecting portion projecting upward from the center of the lower surface of the rim guard to descend to the left or right side, and guiding the rising gravity ball to be positioned at the center of the peak of the transparent pillar member; And a cross section inside the rim guard to form a passage for guiding the rising and falling of the specific gravity ball together with the mountain protrusion, and the specific gravity ball is located at the upper center while the center and the peak of the pillar member coincide with each other. A transverse plate portion having a through hole formed therethrough; A lower extension fence portion extending from the front and rear surfaces of the transverse plate portion to prevent the non-condensing ball from escaping out of the front and rear surfaces thereof to form an electrolyte access passage along with the mountain protrusion; And an extended upper end portion extending from the other side of the front and rear surfaces to prevent the specific ball from being separated out while the upper end portion of the extended upper portion forms an electrolyte access passage along with the transverse plate portion.

In the battery state indicator of the present invention, above the elastic engaging jaw of the coupling head is extended upwardly spaced radially inward from the inner surface portion of the body so that the extended end of the expansion of the transparent pillar member during assembly Preferably, an extended lip is formed to be elastically in close contact with the bottom surface of the flange to maintain a seal.

In the battery state indicator of the present invention, it is preferable that the electrolyte entrance hole for the electrolyte solution penetrating through the lower surface of the storage case of the point where the gravity ball is lowered and stopped to the left and right sides of the mountain projecting portion.

Conventional battery condition indicators require a straight, constant diameter over the entire length of the column member to be coupled in an axial-hole fitting manner that inserts the coupling head from the bottom of the column member while minimizing the outer diameter size of the coupling head. It is easy to make the specific gravity ball small because it can be configured only in the form, but according to the battery state indicator of the present invention, the annular flange portion of the pillar member is provided with a convex lens portion, thereby allowing the image of the specific gravity ball to be enlarged so that The state of charge or discharge becomes clearer and easier.

In addition, the assembly of the coupling head and the storage case to the column part is made simple by the batch fastening method, and thus the assembly is very simple, and the structure is firmly coupled mechanically, and thus the structure is very solid and the sealing property is excellent. Leakage can be effectively prevented.

In addition, the storage case is made of a structure that can smoothly guide the flow of the specific gravity ball, and in particular, the electrolyte is made evenly and very actively flowing structure throughout the specific ball flow path, thereby responding to the change in the specific gravity of the electrolyte As a result, the specific gravity ball can react more smoothly and move, and therefore, there is an advantage in that the specific gravity change of the electrolyte can be detected very accurately.

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

1 to 4 show the overall structure of the battery state indicator according to the present invention, FIG. 1 is a perspective view, FIG. 2 is an exploded view, and FIG. 3 is a perspective cross-sectional view of the assembled state, FIG. 4 is a front cross-sectional view.

As shown in Figure 1 to 4, the battery state indicator according to the present invention, the transparent pillar member 100, the coupling head 200 is coupled to the upper end of the transparent pillar member 100, and the transparent pillar The storage case 300 is coupled to the lower end of the member 100 and the colored gravity ball 400 is accommodated in a freely movable state inside the storage case 300.

The transparent pillar member 100, as shown in Figure 4, the lower portion is immersed in the interior of the battery and its upper surface is exposed on the surface of the battery case 10. As a material of such a transparent pillar member 100, it can comprise with transparent acrylic resin, polycarbonate, transparent AS resin, etc.

More specifically, as illustrated in FIG. 2, the transparent pillar member 100 includes an expansion flange part 110 having an upper surface exposed to the outside of the case 10 of the battery, and the expansion flange part ( Column portion 120 extending downward of the 110 and the tip of the column portion 120 (conical cone pointed or truncated cone shape) The tip part 130 is formed in a cone shape). In addition, the pillar portion 120, the engaging jaw portion 121 is formed to extend while increasing in diameter gradually toward the upper portion adjacent to the expansion flange portion 110. In addition, the pillar portion 120 is provided with a protruding ring 122 adjacent to the peak portion 130.

In particular, the convex lens part 140 is formed on the upper surface of the expansion flange part 110 of the transparent pillar member 100. The convex lens unit 140 may have a configuration in which the surface of the expansion flange unit 110 is raised in the form of a spherical shape, or may be configured to attach a separate convex lens.

According to the convex lens unit 140, by expanding the image of the colored specific gravity ball 400 transmitted from the lower end of the pillar 110 of the transparent pillar member 100 to make the viewer visible large and clear The observer can more clearly check the condition of the battery.

Coupling head 200 according to the present invention, is coupled to the upper portion of the transparent pillar member 100, the insertion hole 11 is formed in the battery case 10, the annular protrusion 211 protruding therefrom (Fig. 4).

And the storage case 300 is coupled to the lower portion of the transparent pillar member 100, while protecting the colored gravity ball 400 accommodated therein, the colored gravity ball 400 is free to respond to the change in the specific gravity of the electrolyte Keep and guide you to your injuries and descents.

In the present invention, the coupling head 200 is configured to be assembled not only to the battery case 10 but also to the transparent pillar member 100 in a so-called 'batch fastening method' (also referred to as 'pressing method'), and the storage case 300 is also configured to be assembled in a batch fastening method to the transparent pillar member (100). The collective fastening method (or press-fitting method) refers to a method in which a screw is pressed in a single step using a press or the like, rather than being screwed together or joined using a separate fastener. By assembling by the present invention, granulation, mounting and sealing can be improved.

The coupling head 200 and the storage case 300 may be made of a plastic material in order to improve the ease of pressing and sealing.

Next, as shown in detail in FIG. 5, the coupling head 200 has a configuration in which a plurality of annular projections 211 are formed outside the body 210. As described above with reference to FIG. 4, the plurality of annular protrusions 211 are forcibly elastically pressed into the insertion holes 11 of the battery case 10, and after being press-fitted, the plurality of annular projections 211 are in close contact with the insertion holes 11. By forming a plurality of barrier walls, a seal is kept to prevent leakage of the electrolyte solution.

In addition, an elastic locking jaw 212 is formed inside the body 210 of the coupling head 200. The coupling head 200 is fitted in the upward direction from the lower end of the transparent pillar member 100, that is, the peak portion 130 (see Fig. 2), wherein the elastic locking jaw 212, the pillar portion ( After passing through the locking jaw portion 121 formed in the 120 forcibly and elastically, the locking jaw portion 121 is caught on the upper surface thereof and is not detachable and maintains a solid binding state. Furthermore, an extended lip 213 is formed above the elastic locking jaw 212 of the coupling head 200. The extended end (upper end) of the extension lip 213 is elastically tightly adhered to the lower surface of the expansion flange 110 of the transparent pillar member 100 during assembly, thereby maintaining a sealing, thereby effectively blocking the leakage of the electrolyte. have.

Next, in the coupling relationship between the storage case 300 and the transparent pillar member 100 according to the present invention, the storage case 300, as shown in Figure 6, the pillar portion of the transparent pillar member 100 (120) The hub 310 is inserted into the outer periphery of the lower end forcibly elastically, and the edge guard 320 of the form in which the front and rear surfaces are integrally extended from both left and right sides of the hub 310. It includes.

An annular groove 311 is formed inside the hub 310, and the annular groove 311 maintains a firmly coupled state by being elastically inserted into the protruding ring 122 of the pillar member 100 by pressing. Done.

In addition, a mountain protrusion 321 protrudes upward from the center of the lower surface of the edge guard 320. The mountain protrusion 321 guides the descending gravity ball 400 to the left or the right. When the specific gravity ball 400 descends and descends to the left or right side, the specific gravity ball 400 is not visible from the outside by leaving the projection area of the transparent pillar member 100 so that the observer can know that the battery is in a discharged state. When the gravity ball 400 rises, it guides along the mountain protrusion 321 to a position coinciding with the center of the peak 130 of the transparent pillar member 100. At the time when the specific gravity ball 400 is the highest rise, the specific gravity ball 400 is to rise more than the top of the mountain projection 321 (the gravity ball with a dotted line in the left figure of Figure 6). Reference).

In addition, the transverse plate portion 330 is integrally formed in the middle of the edge guard 320 to cross the inside of the edge guard 320 from side to side. The transverse plate portion 330 is formed in the form of the middle is further upward, and together with the mountain protrusion 321 to form a passage for guiding the rise, fall of the gravity ball 400.

In addition, a through hole 331 having a size that allows the specific gravity ball 400 to pass through is formed at the center of the upper portion of the cross plate portion 330 and the center of the peak portion 130 of the pillar member 100. The through hole 331 serves as a doorway for putting the specific gravity ball 400 and when the specific gravity ball 400 is injured, a portion of the through hole 331 enters the through hole 331 so that Help the center and the center of the peak portion 130 of the pillar member 100 to match so that the image of the gravity ball 400 is better transmitted to the outside.

Furthermore, electrolyte solution access holes 322 are formed at left and right bottoms of the storage case 300, that is, left and right sides of the mountain protrusion 321, at the point where the specific gravity ball 400 is stopped and then stopped. If there is no entrance hole 322 at the point where the gravity ball 400 is lowered, the surface of the electrolyte on the bottom surface of the gravity ball 400 and the storage case 300 and / or the inner surface of the storage case 300. The phenomenon that the specific gravity ball 400 is temporarily stuck by the force, such as tension may occur, in the present invention, the electrolyte is well distributed to the inside with the specific gravity ball 400 through the access hole 322, as described above. There is no, thereby allowing the specific gravity ball 400 to respond sensitively to the charging and discharging state of the electrolyte to enable more accurate measurement.

7 to 9, a downwardly extending fence portion 341 (see FIGS. 7 and 9) is formed on one side of the front and rear surfaces of the storage case 300, and on the other side thereof. An upwardly extending fence portion 342 (see FIGS. 8 and 9) is formed. The downwardly extending fence portion 341 extends below the transverse plate portion 330 to block an upper portion of the non-concentration ball 400 so as not to be separated from the outside, and an extension lower portion thereof is formed together with the mountain protrusion 321. An access passage 341a is formed. On the contrary, the upwardly extending fence part 342 extends above the mountain protrusion 321 to block the lower part of the specific gravity ball 400 so as not to escape from the outside, and the extension upper part of the cross plate part 330. ) Together with the electrolyte solution access passage 342a. As such, by forming the downwardly extending fence portion 341 and the upwardly extending fence portion 342 on both sides, the separation of the gravity ball 400 is prevented and the gravity ball 400 is stably and freely moved within a predetermined passage. In particular, the downwardly extending fence portion 341 and the upwardly extending fence portion 342 are formed in an asymmetrical shape so that one downwardly extending fence portion 341 forms an electrolyte access passage 341a at a lower side thereof and an upper side on the opposite side thereof. The extended fence part 3332 is formed with an electrolyte access passage 342a on the upper side thereof, so that the electrolyte is evenly introduced into and out of the upper and lower portions of the gravity ball 400 flow passage. ) Is attached to the bottom of the edge guard 320 or the inner surface of the transverse plate portion 330 or the phenomenon that the movement is obstructed disappears.

As described above, the conventional battery status indicator is required to be coupled in a shaft-hole fitting manner in which the coupling head is pushed up from the bottom of the pillar member, while simultaneously minimizing the outer diameter of the coupling head over the entire length of the pillar member. It is easy to make the specific gravity ball small because it can only be configured in a straight shape with a constant diameter, but according to the battery state indicator of the present invention, the convex lens part is provided in the annular flange of the pillar member, thereby expanding the image of the specific gravity ball. The state of charge or discharge is clearer and easier to see.

In addition, the coupling of the coupling head to the pillar is structurally very robust, and leakage of the electrolyte can be effectively prevented.

In addition, the storage case is made of a solid body having no opening and closing portion to smoothly guide the flow of the specific gravity balls, as well as a structure in which electrolyte can flow evenly and very actively throughout the specific gravity flow path. Has Therefore, the specific gravity change of the electrolyte can be detected very accurately by moving the specific gravity ball in response to the change in the specific gravity of the electrolyte.

1 is an overall perspective view of a battery state indicator according to the present invention.

2 is an exploded view of FIG. 1.

3 is a perspective cross-sectional view of FIG. 1.

4 is a front cross-sectional view of FIG. 1.

Figure 5 is an enlarged cross-sectional view showing an enlarged coupling head portion of the battery state indicator according to the present invention.

Figure 6 is an enlarged cross-sectional view showing a portion of the storage case of the battery state indicator according to the present invention.

7 is an enlarged perspective view of the storage case according to the present invention.

FIG. 8 is a perspective view of the storage case of FIG. 7 viewed from the 'A' direction.

FIG. 9 is a cross-sectional view taken along the B-B direction of FIG. 7.

<Explanation of symbols for the main parts of the drawings>

10: battery case 11: insertion hole

100: transparent pillar member 110: expansion flange portion

120: pillar portion 121: locking jaw portion

122: protruding ring 130: peak

200: coupling head 210: body

211: yellow protrusion 212: elastic locking jaw

213: extension rib 300: storage case

310: hub 311: annular groove

320: rim guard 321: mountain protrusion

322: access hole 330: transverse plate

331: through hole 341: downward extension fence portion

341a: electrolyte access passage 342: upwardly extending fence portion

342a: electrolyte passage 400: specific gravity ball

Claims (3)

A lower portion of the transparent pillar member 100 that penetrates into the storage battery, a coupling head 200 coupled to an upper portion of the transparent pillar member 100 and inserted into an insertion hole formed in a case of the storage battery, and the transparent pillar member As the battery state indicator including a storage case 300 is coupled to the lower portion of the 100 and the specific gravity ball 400 is accommodated therein, The transparent pillar member 100, An expansion flange part 110 whose upper surface is exposed to the outside of the case of the battery; A pillar portion 120 extending downwardly of the expansion flange portion 110; A peak portion 130 formed at a lower end of the pillar portion 120 in a tip cone shape or a truncated cone shape; A latching jaw portion 121 extending and extending from the outer diameter of the pillar portion 120 gradually toward the upward direction adjacent to the expansion flange portion 110; And It includes a convex lens portion 140 formed on the upper surface of the expansion flange portion 110 in order to enlarge the image of the specific gravity ball 400 transmitted from the pillar portion 120, The coupling head 200, A plurality of annular protrusions 211 protruding to the outside of the body 210 to forcibly elastically press-fit the insertion holes of the battery case to maintain a seal; And The body is inserted into the upper direction from the lower end of the pillar portion 120 to forcibly and elastically pass through the locking jaw portion 121 formed in the pillar portion 120 to be caught and stopped on the upper surface of the locking jaw portion 121. An elastic locking step 212 is formed inside the 210, The storage case 300, A hub 310 which is forcibly elastically fitted to the outer circumference of the lower end of the pillar 120; An edge guard 320 integrally extending from both left and right sides of the hub 310 and having a front and rear surface open; Guide the lower gravity ball 400 protruding downward from the center of the lower surface of the rim guard 320 to descend to the left or right, the rising gravity ball 400 is the peak of the transparent pillar member 100 130 Mountain protrusion 321 for guiding to the center of the; It is formed in the shape of crossing the inside of the rim guard 320 to form a passage for guiding the rise and fall of the gravity ball 400 with the mountain protrusion 321, the transparent pillar member 100 in the upper center A transverse plate portion 330 having a through-hole formed in a shape that allows the specific gravity ball 400 to pass through while coinciding with the center of the apex 130; An extension lower end portion forms an electrolyte access passage 341a together with the mountain protrusion 321 while preventing the specific gravity ball 400 from extending outward from the front and rear surfaces of the transverse plate part 330 on either side. A downwardly extending fence portion 341; And On the other side of the front and rear surface extending above the mountain projecting portion 321 to prevent the specific gravity ball 400 is separated out of the extended upper end portion along with the transverse plate portion 330 to form an electrolyte access passage 342a The battery state indicator, characterized in that it comprises an upwardly extending fence portion 342. The method of claim 1, An elastic extension of the coupling head 200 is extended upwardly in a state spaced radially inward from the inner surface portion of the body 210 so that the extension end of the expansion of the transparent pillar member 100 during assembly The battery state indicator, characterized in that the extended lip (213) is formed elastically in close contact with the lower surface of the flange portion 110 to maintain the seal. The method of claim 1, Electrolyte access holes 322 for electrolyte access are formed in the lower surface of the edge guard 320 of the storage case 300 at the point where the specific gravity ball 400 descends to the left and right sides of the mountain protrusion 321. Battery status indicator, characterized in that.

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