KR20110020765A - Display device - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device for a storage battery that can display an electrolyte state with a simple structure and good precision and can be manufactured at low cost. The light incident from the proximal end 11 of the light transmitting member is reflected or transmitted at the inclined surface portion 13 depending on the state of the electrolyte, and is directed to the projected portion 15 at the tip only in the case of transmission, and at least a part of the transmitted light Since it is reflected from the colored surface of the sand | seat part 15 and reaches the base end part 11, the display aspect in the base end part 11 when the electrolyte solution is not in contact with the inclined surface part 13 due to lack of electrolyte solution is reflected. In addition, the color of the colored surface of the projected portion 15 can be displayed on the proximal end 11 when the colorless display according to the present invention is sufficient, and the amount of the electrolyte is in contact with the inclined surface portion 13. The difference with the display aspect of the base end part 11 in each case of excessive quantity is made large, and a user can recognize reliably the electrolyte shortage state reliably.

Description

Display device {DISPLAY DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device for a storage battery that optically displays the storage battery state, and more particularly to a display device that can externally distinguish whether or not the electrolyte state is normal.

Background Art Conventionally, display apparatuses that optically detect or display the amount and specific gravity of an electrolyte in a storage battery using a change in refractive index or the like in an electrolyte are used. As such a conventional display apparatus, there exist some which were disclosed by Unexamined-Japanese-Patent No. 3026745, for example.

In this conventional display device, by embedding a plurality of spheres of appropriate specific gravity in the end openings of the transparent columnar member, the specific gravity of the electrolyte is appropriate when the liquid amount and specific gravity of the electrolyte are appropriate and the discharge is appropriate. In the case of the following, in the case of lack of electrolyte solution, the positional relationship of each sphere changes, and the state in which the light from the upper side is projected to the sphere changes, so that when viewed from the upper display surface, Accordingly, three kinds of displays based on the color of the sphere are obtained, and thus the state of charge of the storage battery can be determined.

In addition, a display apparatus having a structure that does not use a movable member such as a sphere has been conventionally proposed, and one of them is disclosed in Japanese Patent Application Laid-open No. 2004-198215 as an example of allowing the amount of electrolyte to be identified.

Japanese Utility Model Registration 3026745 Japanese Patent Application Publication No. 2004-198215

Conventional display devices are as shown in the above-mentioned patent documents, and in the configuration illustrated in Patent Document 1, although the state of the electrolyte solution can be clearly identified by the change in the display color, a sphere which is irradiated with light from above Since the structure detects the amount and specific gravity of the electrolyte by the movement of, the vertical movement of the sphere may not be performed smoothly depending on the relationship with the electrolyte, and there is a problem that a detection error is likely to occur. Moreover, it consists of several members, such as a sphere, and has a problem that manufacturing cost becomes high because in addition to a complicated structure, strict processing precision for smoothly moving a sphere in an opening part is also required.

On the other hand, in the structure illustrated by the said patent document 2, there is no movable part, and it changes the display state at the time of seeing the inside of an apparatus from the upper side by changing the advancing state of light according to the liquid level height state of electrolyte solution, and it is suitable for the quantity of electrolyte solution Although it is necessary to discriminate the amount and quantity of electrolyte solution only by the difference of internal contrast, it is necessary to distinguish between the inside of the apparatus in the places where batteries are installed such as an engine room where external light is easily blocked by a bonnet or the like. There is a problem that the difference in contrast between the light and dark is easy to be obscured, and that there is a risk of overlooking the lack of electrolyte due to the inaccurate identification of the amount of electrolyte.

In addition, although the structure shown by each patent document mentioned above is equipped with the columnar light-transmitting material part, the thick columnar part which filled this inside is shape | molded unevenly with the transparent resin material which is supposed to use. It is extremely difficult in terms of the process of resin molding, in fact, it is very difficult to have a non-uniformity inside the resin after molding, which affects the path of incident light, and cannot be obtained as set by the display seen from above. Problems such as marks and voids are likely to occur, and yields deteriorate, leading to a cost increase.

This invention is made | formed in order to solve the said subject, It aims at providing the display apparatus of the storage battery which can display the electrolyte solution state with good precision with a simple structure, and can be manufactured at low cost.

The display device according to the present invention has at least a translucent member in which a proximal end is positioned on an upper surface of a casing of a storage battery and a proximal end is protruded into the casing, and at least within the casing. In the display device for a battery which displays the state of the stored electrolyte solution optically at the base end part using the light incident from the said translucent member base end part, WHEREIN: The continuous direction of a groove | channel is made in the predetermined part near the front-end | tip of the said translucent member. It is formed as one or a plurality of planes or horns which form a groove side surface close to the proximal end in a groove formed to be perpendicular to the protruding direction of the distal end, and are inclined by a predetermined angle with respect to the protruding direction of the distal end. Arranged in an inclined surface portion and a bottom surface portion in the groove of the light transmitting member in parallel with the protruding direction of the tip portion. And a projected portion formed as a portion on the front end side from the groove of the light transmitting member, wherein the inclined surface portion is incident from the proximal end side in contact with air. The light is totally reflected to form an inclined angle that is directed toward the direction in which the projected portion does not exist, and the projected portion is formed on a light-transmitting state on the surface of the projected surface near the tip of the groove. One or more surfaces which are not in contact with each other are made of a non-transparent colored surface that reflects at least a part of the light projected through the inclined surface portion.

As described above, according to the present invention, the light incident from the proximal end of the translucent member is reflected or transmitted at the inclined surface portion according to the state of the electrolyte, and only in the case of transmission, the light is directed toward the projected portion having the colored surface at the tip. At least a part of the reflected light is reflected from the colored surface of the projected portion to reach the proximal end, thereby making the display mode at the proximal end when the electrolyte solution is not in contact with the inclined surface part due to lack of electrolyte solution, while making the colorless display according to the reflection of light. In the case where the amount of the electrolyte is sufficient and the electrolyte is in contact with the inclined surface portion, the color of the colored surface of the projected portion can be displayed on the proximal end, and the display mode of the proximal end corresponding to the lack of electrolyte and the indication of the proximal end when the electrolyte is sufficient Increased the difference with the aspect, the user confirms the electrolyte shortage state irrespective of the brightness around the battery Can be recognized, it is possible to ensure safety and to take appropriate response such as an electrolyte replenishment. In addition, it can be made into a simple structure in which there is no movable portion moving according to the state of the electrolyte, and its manufacture is easy, and manufacturing cost can be reduced, and also, detection errors and display malfunctions caused by the movable portion can be prevented, The reliability of the display can be increased.

In addition, the display device according to the present invention has a surface shape such that the inclined surface portion reflects light from the base end a plurality of times in a contact state with air and is directed back to the base end side as necessary.

As described above, according to the present invention, when the light from the proximal end is reflected from the inclined surface portion, the light is reflected back and forth at the proximal end, whereby the amount of the electrolyte is insufficient and the electrolyte is not in contact with the inclined surface portion. The display mode is a bright colorless display in response to the return of incident light, thereby further widening the difference between the display mode of the base end portion corresponding to the lack of electrolyte and the display mode of the base end when there is sufficient electrolyte solution, thereby allowing the user to apply the amount of the electrolyte solution. Can be easily identified.

In addition, the display device according to the present invention may further include one or a plurality of planes having an inclination in which the projected portion becomes a groove side surface of the groove to be inclined toward the protruding direction of the tip portion as it is spaced apart from the groove bottom surface. Or as a horn face.

Thus, according to this invention, a predetermined inclination is given to the surface which contact | connects the groove of a to-be-projected part, and electrolyte solution flows out from the to-be-projected part in the state in which the liquid level of electrolyte solution fell below the to-be-projected part, and it is easy to separate, It is possible to prevent the drop of electrolyte solution from the dead part, that is, the groove part, and to prevent the electrolyte solution from being in contact with the inclined surface part. Therefore, the electrolyte solution does not come into contact with the inclined surface part to transmit light. In this case, it is possible to reliably totally reflect the light from the proximal end portion at the inclined surface portion, whereby the display mode in the case of lack of electrolyte at the proximal end can be obtained clearly, and the display reliability can be improved.

In addition, the display device according to the present invention is formed so that the projected portion corresponds to a projection portion that changes depending on the specific gravity of the electrolyte solution of the light passing through the inclined surface portion, and is formed by varying a plurality of colors to be colored. The optical display mode in the case also varies depending on the specific gravity of the electrolyte solution.

Thus, according to the present invention, in response to the path of the light transmitted through the inclined surface portion to change based on the specific gravity of the electrolyte, a plurality of colors to be colored to the projected portion are set, and the amount of the electrolyte is appropriate and light incident from the proximal end passes through the inclined surface portion. When reaching the dead part, the display mode at the base end is changed into a plurality of types in accordance with the change in the specific gravity of the electrolyte solution, whereby the user is assured of the detailed state of the electrolyte solution from the change in the display mode at the base end based on the change in the specific gravity of the electrolyte solution. It can be easily recognized, and it is possible to grasp the state of charge of the battery and take appropriate measures such as maintenance of the electrolyte or charging with the battery, thereby improving safety.

In the display device according to the present invention, if necessary, the tip side portion from the base end portion of the light transmitting member is formed into a substantially cylindrical shape, the inclined surface portion becomes a conical surface, and the columnar portion becomes a cylinder shape. A projected portion is substantially disk-shaped, and the light-transmitting member has a depth from the center of the projected portion on the tip side to the vicinity of the base end portion, and one or a plurality of holes passing from the inclined surface portion to a predetermined side position near the base end portion. It is made by forming through holes, respectively.

Thus, according to this invention, the hole which extends from the projected part to the vicinity of the base part is formed in the translucent member from which the proximal end part forms a circular cross-sectional shape, respectively, and the shape which avoided the state where the translucent member becomes excessively thick is employ | adopted, By forming, the temperature change at the time of molding can be made uniform in each part, the moldability can be improved, the quality and yield can be improved, and the manufacturing cost can be reduced. In addition, abnormalities such as residual unevenness after molding and detection errors or display abnormalities caused by the molding can be prevented, and the reliability of the display with respect to the electrolyte state can be further improved.

In the display device according to the present invention, if necessary, the projected portion and / or the columnar portion are formed to have a water-repellent property in the surface of the groove contacting the groove with respect to the electrolyte solution.

As described above, according to the present invention, the water-repellent property is imparted to the surface or the columnar portion in contact with the groove of the projected portion, and the electrolyte solution is easily leaked from the projected portion in a state where the liquid level of the electrolyte is lowered below the projected portion. In this case, it is possible to prevent the drop of electrolyte from remaining on the projected portion and bringing the electrolyte into contact with the inclined surface, so that the electrolyte does not come into contact with the inclined surface to transmit light, and in the case of insufficient electrolyte, the inclined surface It is possible to reliably totally reflect the light from the proximal end side, thereby to clearly obtain the display mode in the case of lack of electrolyte at the proximal end, and to further improve the reliability of the display.

1 is a plan view of a storage battery equipped with a display device according to a first embodiment of the present invention.
2 is a front view of a display device according to a first exemplary embodiment of the present invention.
3 is a left side view of the display device according to the first embodiment of the present invention.
4 is a plan view and a bottom view of a display device according to a first exemplary embodiment of the present invention.
5 is a cross-sectional view taken along line AA of FIG. 4.
6 is an explanatory diagram of an optical path and a display mode when the electrolyte solution is insufficient in the display device according to the first embodiment of the present invention.
FIG. 7 is an explanatory view of an optical path and a display mode at the time of electrolyte solution loading in the display device according to the first embodiment of the present invention. FIG.
8 is a bottom view of a display device according to a second exemplary embodiment of the present invention.
9 is an explanatory view of an optical path and a display mode at the time of specific gravity of the electrolyte in the display device according to the second embodiment of the present invention.
10 is an explanatory view of an optical path and a display mode at the time of proper specific gravity of an electrolyte solution in the display device according to the second embodiment of the present invention.

(First embodiment of the present invention)

Hereinafter, a first embodiment of the present invention will be described based on FIGS. 1 to 7. In this embodiment, the example applied to the display of the electrolyte state in a lead storage battery is shown. 1 is a plan view of a storage battery equipped with a display device according to the present embodiment, FIG. 2 is a front view of the display device according to the present embodiment, FIG. 3 is a left side view of the display device according to the present embodiment, and FIG. 4 is the present embodiment. 5 is a cross-sectional view taken along line AA of FIG. 4, FIG. 6 is an explanatory view of an optical path and display mode when the electrolyte is insufficient in the display device according to the present embodiment, and FIG. 7 is an embodiment of the present invention. It is explanatory drawing of the optical path at the time of electrolyte solution quantity in the display apparatus which concerns on the example, and a display aspect.

As shown in each of the above drawings, in the display device 1 according to the present embodiment, the proximal end 11 is positioned on the upper surface of the casing 51 of the storage battery 50 and the distal end 12 is formed. An inclined surface portion 13 formed of a transparent member as the translucent member provided to protrude into the casing 51 and formed as a conical surface in a predetermined portion near the distal end, and the distal end portion from the inclined surface portion 13 to the distal end side; It is comprised so that the column part 14 formed as the cylindrical part parallel to the protrusion direction of (12), and the projection part 15 formed as a substantially disc shaped body at the front-end side from this column part 14 is comprised. .

The display device 1 is formed of a transparent member such as a polycarbonate, an AS resin, an acrylic resin, and is formed so as to be formed by expanding the diameter of the base end portion 11 in a flange shape, and having an annular shape made of another elastic material. The proximal end portion 11 into which the seal body 52 is inserted, and is mounted on the upper surface of the casing 51 having the electrodes 53 and 54 serving as vent plugs and the other vent plugs 55, respectively. It is installed integrally with 50 (refer FIG. 1). In the mounting state on the casing 51 upper surface, the sealing body 52 is sealed so that the electrolyte solution (dilute acid) 56 stored in the casing 51 does not flow out.

On the other hand, the distal end portion 12 of the display device 1 has an inclined surface portion in an arrangement surrounding the groove 12a formed by making the continuous direction of the groove orthogonal to the protruding direction of the distal end portion 12 at a predetermined portion near the distal end portion. 13) and a columnar portion 14 and a projected portion 15, the lower end of the inclined surface portion 13 near the distal end with respect to the proximal end 11 is arranged in accordance with the lower limit level of the electrolyte 56, Usually, it is immersed in electrolyte 56. The intermediate portion 16 between the distal end portion 12 and the proximal end portion 11 is formed in a cylindrical shape and has a hole for facilitating molding of the transparent member portion from the distal end portion 12 toward the proximal end portion 11. 17 and the horizontal through-hole 18 are formed and comprised.

In this manner, a hole 17 having a predetermined diameter reaching the proximal end 11 from the center of the projected portion 15 is formed, and the shape is avoided by adopting a shape that avoids an excessively thick transparent columnar member. By doing so, it is possible to increase the moldability such that the temperature change at the time of molding is uniform in each part, and the molding quality and yield can be improved, and the manufacturing cost can be reduced, and the transparent member after molding It is possible to prevent abnormalities such as residual unevenness of the furnace, and thus detection errors and display abnormalities, and to improve the reliability of the display with respect to the electrolyte state.

The inclined surface portion 13 constitutes a groove side surface close to the proximal end 11 in the groove 12a of the distal end portion 12, and is configured as a conical surface having a conical central axis parallel to the protruding direction of the distal end portion 12. The light incident from the base end 11 side is refracted and transmitted to the projected part 15 side of the reflection or tip.

When the amount of the electrolyte solution 56 is sufficient and the electrolyte solution 56 contacts the inclined surface portion 13, the inclined surface portion 13 is a projected portion at the tip while accompanied by refraction of light from the base end 11 side. In the case where air is transmitted to the (15) side and air is in contact with the inclined surface portion 13 due to lack of electrolyte, the light from the proximal end 11 side is totally reflected at the outer inclined surface portion 13 so that the projected portion 15 exists. The conical busbar of the conical surface is made to have an inclination angle of 45 ° with respect to the protruding direction of the tip 12 (45 ° of the half-corner angle of the cone) so as to face in a direction not to be oriented.

Specifically, when polycarbonate is used as the material of the display device 1, the refractive index n ₁ of the polycarbonate is 1.585, and total reflection when light propagates in the outside air from the transparent member side of the display device 1 The critical angle φ , which is the boundary of whether or not it is, considers the refractive index of air, and sin φ = from n ₂ / n ₁ = 1 / 1.585, φ = 39.1 °. Therefore, by setting the inclination angle of the busbar to the inclined plane portion 13 so that light from the proximal end 11 side enters the inclined plane portion 13 at an incidence angle larger than this critical angle of about 39 °, the electrolyte 56 is insufficient and the inclined plane portion ( When not in contact with 13), the light from the base end 11 is totally reflected in the lateral direction at the inclined surface portion 13. In this case, the light is once reflected by the inclined surface portion 13, and then is reflected again by another portion of the inclined surface portion 13 to proceed to the base end portion 11, and the proximal end 11 has a colorless (approximately white) bright display. Appears.

On the other hand, when the electrolyte solution 56 is in contact with the inclined surface portion 13, the specific gravity of the electrolyte solution 56, that is, at the time of good state of charge of the dilute acid is in the range of 1.19 to 1.26, so that the lower limit of the range is employed and the specific gravity is 1.19. Since the refractive index n ₂ of the electrolyte solution 56 is 1.368, the critical angle φ becomes φ = 59.67 ° by n ₂ / n ₁ = sin φ . By setting the angle of inclination of the conical busbar to 45 °, the light from the proximal end 11 side enters the inclined surface portion 13 at an incidence angle (45 °) below this critical angle of about 60 °, and depends on the specific gravity of the electrolyte 56. It passes through the inclined surface portion 13 with the refraction at the refractive angle, and reaches the projected portion 15 through the electrolyte 56.

The columnar portion 14 forms a bottom surface in the groove 12a of the tip portion 12 and is a cylindrical portion disposed at a predetermined length in parallel with the protruding direction of the tip portion 12 from the lower end of the inclined surface portion 13. It is configured to be formed as. The columnar portion 14 is a groove 12a quickly in a state in which the electrolyte solution that enters the groove 12a surrounded by this and the inclined surface portion 13 and the projected portion 15 is lower than the inclined surface portion 13. It is formed as a length which ensures the sufficient groove width which prevents electrolyte solution from adhering to the inclined surface part 13 by flowing out from (). The length of this columnar portion 14 is preferably 3 mm.

The projected portion 15 is formed at the front end side than the groove 12a of the tip portion 12 and is substantially disk-shaped and integrally formed with other parts of the apparatus including the inclined surface portion 13 or the columnar portion 14, and the groove 12a The upper surface serving as the groove side in the vicinity of the distal end is formed as a conical surface having an inclination that goes toward the protruding direction of the distal end 12 as it moves away from the columnar portion 14 forming the groove bottom surface. However, the inclined state of the upper surface, which is the conical surface of the projected portion 15, is the so-called molding time in which the conical busbar of the conical surface is inclined at a very slight angle of less than 1 ° from the direction orthogonal to the protruding direction of the tip portion 12. It is in an inclined state corresponding to a subtraction gradient for releasing, and it looks almost planar with the naked eye. And the inclination of this upper surface is the maximum angle which does not totally reflect the return light to the base end part 11 side in electrolyte contact state from this subtraction grade grade (when the apparatus material is polycarbonate, with respect to the protrusion direction of the front end part 12). Up to about 59 °).

In addition, the upper surface of the projected portion 15 is in a transmissive state, and the light from the proximal end 11 side that has passed through the inclined surface portion 13 is projected on the upper surface to further advance the light to the tip side, while the groove 12a ) Is a non-transparent colored surface that reflects at least a portion of the projected light passing through the inclined surface portion 13, and at least a portion of the light is reflected from the colored surface to return to the proximal end 11. As a result, the color of the projected portion 15 is displayed on the proximal end 11.

The lower surface of the projected portion 15 becomes the blue surface 15a colored in blue, and the blue surface (at the proximal end 11 is formed in the proper amount of the electrolyte solution in which the inclined surface portion 13 contacts the electrolyte solution 56). A blue color 11a of 15a is displayed. As a result, the display mode at the base end 11 is greatly different from the case where the light from the base end 11 side is reflected by the inclined surface portion 13 due to lack of electrolyte solution.

Next, the display state in the display device according to the present embodiment according to the above-described configuration will be described. As a premise, the storage battery is standing, and the liquid level of the electrolyte is kept horizontal without vibrating due to vibration or tilting. First, when the electrolyte 56 is low in liquid, that is, when the liquid level of the electrolyte 56 is lowered and all of the inclined surface portions 13 of the display device 1 are exposed out of the electrolyte 56 (see FIG. 6). The light incident on the inclined surface portion 13 from the base end portion 11 side of the display device 1 is inclined surface portion 13 than the critical angle when light propagates in the outside air from the transparent member side of the display device 1. Since the angle of incidence of light with respect to) is large, it is totally reflected from the inclined surface portion 13 to the central axis side of the display device 1.

The totally reflected light travels toward the conical central axis of the inclined surface portion 13 when viewed from above, and enters another part of the inclined surface portion 13 beyond the center, so that the totally reflected light is totally newly reflected at the inclined surface portion 13, and the proximal end 11 ) To the side. Therefore, when looking at the end surface of the base end 11 side from above, the light is transmitted through the transparent portion as it is, so that a bright colorless (white) display state with no color appears.

In the case of lack of this electrolyte, even if the electrolyte penetrates into the groove 12a above the projected portion 15 due to the inclination or vibration of the storage battery, the columnar portion 14 is formed as a length to secure a sufficient groove width, A predetermined inclination is given to the upper surface of the projected portion 15 in contact with the groove 12a so that the excess electrolyte can be quickly removed from the groove 12a, and the electrolyte solution is miscontacted with the inclined surface portion 13. In this case, the inclined surface portion 13 can be totally reflected reliably without transmitting light from the base end portion 11 side, whereby the display mode in the case of lack of electrolyte at the base end portion 11 can be obtained clearly.

When the amount of the electrolyte is sufficient, that is, when the electrolyte 56 contacts the entire inclined portion 13 (see FIG. 7), the refractive index of the electrolyte 56 causes total reflection at the inclined surface portion 13. Since it is sufficiently larger than the refractive index, the light incident from the base end portion 11 side of the display device 1 passes through the inclined surface portion 13 at a refractive angle corresponding to the refractive index of the electrolyte solution 56. When the light transmitted through the inclined surface portion 13 is projected onto the projected portion 15, the light reaches the blue surface 15a from the upper surface side of the projected portion 15 through the transparent portion similar to the other portion of the apparatus. Then, part of the light is reflected by the blue surface 15a and returned to the base end portion 11, so that the blue 11a appears when the cross section of the base end portion 11 is viewed from above.

As the liquid level of the electrolyte is changed, the electrolyte and air enter and exit the hole 17 in the center of the display device 1, but the electrolyte and air can enter and exit from the upper through hole 18. The liquid level of the electrolyte in the hole 17 is also the same as the other parts in the casing, so that air, the electrolyte, and the like in the hole 17 do not affect the inclined surface portion 13 or the like.

As described above, the display device according to the present embodiment reflects or transmits the light incident from the proximal end 11 at the inclined surface portion 13 in accordance with the state of the electrolyte, and provides the blue surface 15a at the tip only in the case of transmission. Since at least a part of the transmitted light is directed toward the projected portion 15 to be reflected from the blue surface 15a of the projected portion 15 to reach the proximal end portion 11, the electrolyte solution is inclined surface portion 13 due to lack of electrolyte solution. Note that the display mode at the base end 11 when not in contact with) is a colorless display according to the reflection of light, while the base end 11 when the amount of the electrolyte is sufficient to contact the inclined surface portion 13. The blue 11a based on the blue surface 15a of the projected part 15 can be displayed, and the difference of each display aspect in the base end part 11 in the case of lack of electrolyte solution and sufficient electrolyte solution is made large. , User can check the electrolyte In fact, it is easy to recognize, and the reliability of the display with respect to the electrolyte state can be improved.

(2nd Example of this invention)

A second embodiment of the present invention will be described with reference to FIGS. 8 to 10. 8 is a bottom view of the display device according to the present embodiment, FIG. 9 is an explanatory view of the optical path and the display mode when the electrolyte solution is underweighted in the display device according to the present embodiment, and FIG. 10 is a display device according to the present embodiment. Explanatory drawing of the optical path at the time of electrolyte specific gravity in FIG.

As shown in each of the above drawings, the display device 2 according to the present embodiment, like the first embodiment, includes an inclined surface portion 23, a columnar portion 24, and a projection portion 25. On the other hand, the point which has the structure provided with the blue surface 25a and the red surface 25b as a non-transmissive colored surface in the lower surface of the to-be-projected part 25 is different.

As in the first embodiment, the display device 2 is formed of a transparent member, and the base end portion 21 formed in a flange shape is positioned on the upper surface of the casing 50 of the storage battery, and the tip end portion 22 is disposed in the casing 51. ) Is installed to protrude into, and detailed description thereof will be omitted.

The red part colored in red with the blue surface 25a colored blue as the non-transmissive colored surface in the lower surface part which does not contact the groove | channel 22a among the tip part 22 about the projected part 25 The surface 25b is configured to be installed. The outer periphery of the lower surface of the projected portion 25 becomes the blue surface 25a, while the portion near the center of the lower surface becomes the red surface 25b, and the light transmitted through the inclined surface portion 23 is projected onto the projected portion 25. Then, light passes through the transparent portion from the upper surface side of the projected portion 25 so that the light reaches the blue surface 25a or the red surface 25b, and some light is reflected by the blue surface 25a, the red surface 25b, or the like. By returning to the base end 21, the color of the blue surface 25a and / or the red surface 25b of the projected portion 25 is displayed on the base end 21.

And when the specific gravity of the electrolyte solution 56 which contacts the inclined surface part 23 is larger than a lower limit, and when the specific gravity of the electrolyte solution 56 is small in a insufficient state of charge, the inclined surface part ( The position projected on the projected portion 25 of the light transmitted through 23 is changed, and the projection area ratio between the blue surface 25a and the red surface 25b is changed, and the optical display at the base end 21 in each case described above is changed. The aspect becomes different. In this way, the change in the specific gravity of the electric field liquid can be recognized from the difference in the display mode by reflecting the change in the state of propagation of light due to the change in the specific gravity of the electric field liquid in the display mode at the base end 21.

Next, the display state in the display device according to the present embodiment according to the above-described configuration will be described. In the case where the electrolyte solution 56 is insufficient in the liquid amount and all of the inclined surface portions 23 of the display device 2 are exposed out of the electrolyte solution 56 (see FIG. 6), the proximal end 21 side is similar to that of the first embodiment. The light incident on the inclined surface portion 23 from the surface is totally reflected at the inclined surface portion 23, and totally reflected at another portion of the inclined surface portion 23, and is directed toward the base end portion 21 side. In this case, when looking at the end surface of the base end part 21 side from the top, the light passes through the transparent part as it is, and a bright colorless (white) display state with no color appears.

When the amount of the electrolyte is sufficient but the filling is insufficient, that is, when the specific gravity of the electrolyte 56 is less than the lower limit of 1.19 of the appropriate range (see FIG. 9), the refractive index of the electrolyte 56 in this specific gravity is inclined. Since the portion 23 is sufficiently larger than the refractive index generated by total reflection, the light incident from the base end portion 21 passes through the inclined surface portion 23 at a refractive angle corresponding to the specific gravity of the electrolyte solution 56. When light transmitted through the inclined surface portion 23 is projected onto the projected portion 25, the light passes through a transparent portion similar to the other portion of the apparatus from the upper surface side of the projected portion 25, and the light passes through the center of the projected portion 25. The projection is projected onto the red surface 25b closer to, but is not projected onto the blue surface 25a on the outside thereof. Then, part of the light is reflected by the red surface 25b and returned to the base end portion 21, so that the red 21b appears when the cross section of the base end portion 21 is viewed from above.

In addition, when both the amount and the state of charge of the electrolyte are good, that is, when the specific gravity of the electrolyte 56 is 1.19 or more (see FIG. 10), the light incident from the proximal end 21 side causes the inclined surface portion 23 to become the electrolyte ( 56 is transmitted through a smaller refraction angle corresponding to a specific gravity than the above-mentioned case, and is projected onto the red surface 25b of the projected portion 25, and is also projected on the outer blue surface 25a. As light is reflected from the blue surface 25a and the red surface 25b and returns to the base end 21, when looking at the cross section of the base end 21 side from above, the blue 21a on the outside is red toward the center. 21b will appear respectively.

As described above, in the display device according to the present embodiment, the path of the light passing through the inclined surface portion 23 is changed based on the specific gravity of the electrolyte, and the colored surface is arranged in the projected portion 25 in a plurality of colors. When the light incident from the base end portion 21 is a suitable amount and passes through the inclined surface portion 23 to reach the projected portion 25, the display mode at the base end portion 21 is changed in a plurality of ways in accordance with the specific gravity change of the electrolyte solution. Therefore, the user can reliably and easily recognize the detailed state of the electrolyte from the change of the display mode at the base end 21 based on the change in the specific gravity of the electrolyte. Appropriate response, such as charging with a storage battery, can be taken, and safety can be improved.

In the display devices according to the first and second embodiments, the inclined surface portions 13 and 23 are formed in a conical shape. However, the present invention is not limited thereto. It can also be configured so that the inclined surface portion, such as a wedge shape in which is disposed opposite to each other at a predetermined opening angle, is formed in another surface arrangement shape. In each of the above-described embodiments, the inclined surface portions 13 and 23 are used as horn surfaces to return the light to the proximal end during total reflection, but the present invention is not limited thereto. In this case, as long as the difference in display mode at the base end can be sufficiently provided, the inclined surface portion may be configured so that the light from the base end is reflected in a desired direction so as not to be returned directly to the base end side. It is also possible to provide a simple inclined plane of one plane without providing a plurality of inclined planes. In addition, the angle of the inclined surface portion is not limited to the inclination angle of 45 degrees in which the total surface reflection and the return light to the proximal end side can be expected in the case of the horn surface, and the angle where the total reflection of the light is reliably generated by the transmission of the light through contact with the electrolyte and non-contact. If so, it can be appropriately set to a desired angle value.

In addition, in the display apparatuses according to the first and second embodiments, the structure is formed of a transparent member other than the seal body 52, but is not limited thereto, and the engaging portion with the casing at the proximal end is not limited thereto. The member of another material may be comprised so that it may be used integrally with a transparent member. And it is not limited to the structure which uses a transparent member as a translucent member, If it is a material which transmits light, you may use an opaque thing as a translucent member.

In addition, in the display device according to the first and second embodiments, the columnar portions 14 and 24 have a sufficient length, a predetermined inclination is given to the upper surfaces of the projected portions 15 and 25, and the electrolyte is insufficient. In this case, even if the electrolyte solution penetrates into the grooves 12a and 22a by mistake, the excess electrolyte solution is quickly removed from the grooves 12a and 22a, so that the electrolyte solution is in a state in which the inclined surfaces 13 and 23 are in a wrong contact state. Although it is configured to prevent, in addition, it can be configured to impart water repellency to the surface in contact with the groove of the projected portion or to the surface of the columnar portion, and, as described above, the electrolyte is insufficient to flow out from the groove in the state of lack of electrolyte. In this case, it is possible to prevent the electrolyte solution from remaining in contact with the inclined surface portion by remaining on the projected portion, and allowing the electrolyte solution to contact the inclined surface portion to transmit light. If a does not occur, it can be obtained to thereby reliably totally reflected light from the proximal end side from the slope portion in the case of a lack of the electrolyte clearly the display mode in the case of the electrolyte shortage in the base end portion, thereby increasing the reliability of the display. In addition, in the case of each of the above-described configurations in which excess electrolyte is easily removed from the groove of the tip of the device, the inclined surface portion is provided with hydrophilicity on the surface thereof, and the electrolyte solution is easily adhered to the inclined surface portion. In the case of a proper amount of electrolyte solution, it is possible to remove the adhesion of bubbles and the like to the inclined surface portion reliably and to contact the electrolyte solution on the inclined surface portion, to prevent incorrect total reflection of light due to bubble adhesion, and to prevent the proximal end from the inclined surface portion. It is possible to reliably transmit the light from the projected portion side to obtain the display mode in the case where the amount of the electrolyte solution is appropriate at the proximal end.

1, 2: display device 11, 21: proximal end
11a, 21a: blue 12, 22: distal end
12a, 22a: groove 13, 23: inclined surface portion
14, 24: column 15, 25: the projection portion
15a, 25a: Blue side 16: Middle
17: hole 18: through hole
21b: red 25b: red side
50: storage battery 51: casing
52: seal body 53, 54: electrode
55: vent plug 56: electrolyte solution

Claims (11)

Electrolyte state in which the base end part is located in the upper surface of the casing of a storage battery, and has at least a translucent member installed so that a front end part may protrude into a casing, and is stored in the said casing. In the display device for a storage battery which displays optically in the said base end part using the light incident from the said translucent member base end part,
At a predetermined portion near the distal end of the light transmitting member, a groove is formed near the proximal end in a groove formed by orthogonal to the protruding direction of the distal end, and inclined by a predetermined angle with respect to the distal direction of the distal end. An inclined surface portion formed of one or a plurality of planes or horns;
A columnar portion of a predetermined length that is formed as a bottom surface portion in the groove of the light transmitting member in parallel with the protruding direction of the tip portion; And
Projected portion formed as a portion on the tip side from the groove of the light transmitting member
Including,
The inclined surface portion is an inclination angle that totally reflects the light incident from the proximal end side in contact with air and directs it in the direction where the projected portion does not exist,
The projected part makes a surface which becomes a groove side close to the tip end of the groove, while reflecting at least a part of the light projected through the inclined surface part to one or a plurality of surfaces not in contact with the groove. The display apparatus which consists of a non-translucent coloring surface to make. The method of claim 1,
The inclined surface portion has a surface shape in which light from the base end portion is reflected a plurality of times in a contact state with air to be directed back to the base end side. The method of claim 1,
And the projected portion is formed as one or a plurality of planes or horns having an inclination that extends toward the protruding direction of the tip portion away from the groove bottom surface. The method of claim 2,
And the projected portion is formed as one or a plurality of planes or horns having an inclination that extends toward the protruding direction of the tip portion away from the groove bottom surface. The method of claim 1,
The projected portion is formed in correspondence with a projection portion that changes according to the specific gravity of the electrolyte solution of the light passing through the inclined surface portion, and is formed by varying a plurality of colors to be colored. Display device. The method of claim 2,
The projected portion is formed in correspondence with a projection portion that changes according to the specific gravity of the electrolyte solution of the light passing through the inclined surface portion, and is formed by varying a plurality of colors to be colored, and the optical display mode at the proximal end varies depending on the specific gravity of the electrolyte solution. Display device. The method of claim 3,
The projected portion is formed in correspondence with a projection portion that changes according to the specific gravity of the electrolyte solution of the light passing through the inclined surface portion, and is formed by varying a plurality of colors to be colored. Display device. The method of claim 4, wherein
The projected portion is formed in correspondence with a projection portion that changes according to the specific gravity of the electrolyte solution of the light passing through the inclined surface portion, and is formed by varying a plurality of colors to be colored. Display device. The method according to any one of claims 1 to 8,
The tip side portion of the light transmitting member is formed into a substantially cylindrical shape, the inclined surface portion becomes a conical surface, the column portion becomes a cylinder shape, and the projected portion becomes a substantially disk shape.
The light-transmissive member is formed by forming a hole, which becomes a depth from the center of the projected portion on the tip side to the vicinity of the base end, and one or a plurality of through holes leading from the inclined surface portion to a predetermined side position close to the base end, respectively. Device. The method according to any one of claims 1 to 8,
The said projected part and / or the said columnar part are formed in the surface which contact | connects the said groove | channel with the property which shows water repellency with respect to electrolyte solution. 10. The method of claim 9,
The said projection part and / or the said columnar part are formed in the surface which contact | connects the said groove | channel with the property which shows water repellency with respect to electrolyte solution.

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