KR101699719B1 - Signpost using bi-facial solar cell - Google Patents

Abstract

The present invention relates to a signpost structure using a bifacial solar cell, capable of selectively installing a signpost and a solar cell panel on each surface of a pillar, so as to improve a basic role as the signpost and light reception efficiency of the solar cell panel. According to the signpost structure comprises: the pillar formed by a vertical shaft and a pillar member; and the signpost and the solar cell panel installed on the pillar. A protrusion pattern with a shape extended in the longitudinal direction of the vertical direction is installed on each surface of the vertical shaft, a slide groove part is installed in the protrusion pattern, the signpost or the solar cell panel is installed in a shape inserted between two guide frames, and a slide bracket integrated with the guide frame is installed in the bottom of the guide frame. Since the slide bracket is combined with the slide groove part of the protrusion pattern in a sliding style, the signpost or the solar cell panel is installed on the pillar, and the solar cell panel is formed by including bifacial solar cells.

Description

Signpost using bi-facial solar cell using double-sided light-

The present invention relates to a milestone structure using a double-sided light receiving solar cell, and more particularly, to a milestone structure capable of selectively mounting a milestone and a solar cell panel on each side of a strut, The present invention relates to a milestone structure using a double-sided light receiving type solar cell.

The milestone is installed in the city center, the park, the trail, etc., and informs the direction and the distance of the target point. Conventional milestones are a useful guide during the daytime, but there is a problem that visibility is reduced at night after sunset. There is an example in which a reflective sheet is applied to improve visibility at night, but the reflective sheet may be discolored when used for a long time and the reflective sheet may be damaged by the external environment.

On the other hand, technologies applying solar cells to road guide plates have been recently applied. Specifically, a road marking is shaped into a light emitting diode (LED) and a solar cell is used as a power source of a light emitting diode, thereby improving night visibility (see Korean Patent No. 1088766).

However, in the case of the road sign board, it is possible to form the mark with the LED according to the size of the mark, but the size of the phrase displayed on the milestone is smaller than the mark of the road signboard,

In addition, in the case of a road sign board to which a solar cell is applied, a cross sectional light receiving solar cell which can receive light only on one side is generally used, and there is a disadvantage that the light receiving efficiency is variable according to the movement of the sun, There is a problem in applying to the milestones installed on the trail where time is short.

Korean Patent No. 1088766

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a milestone and a solar cell panel that can be selectively mounted on each side of a support, And to provide a milestone structure using a light receiving solar cell.

In addition, the present invention provides a structure for coupling a milestone or a solar cell panel to a pillar by way of a guide frame and a slide bracket, through which a double-sided light receiving type Another goal is to provide a milestone structure using solar cells.

In order to accomplish the above object, a milestone structure using a double-sided light receiving type solar cell according to the present invention includes: a columnar structure including a vertical shaft and a strut member; And a solar cell panel mounted on the strut, and a protruding pattern extending in the longitudinal direction of the vertical shaft is provided on each surface of the vertical shaft, and a slide groove portion is provided in the protruding pattern And the slide bracket is integrally formed with the guide frame at a lower end of the guide frame, and the slide bracket is mounted on the slide groove of the protruding pattern, Wherein the milestone or the solar cell panel is mounted on the strut, and the solar cell panel comprises a double-side light receiving solar cell.

The vertical shaft has a prismatic shape, and a protrusion pattern is provided on each surface of the vertical shaft. The protrusion pattern extends in the longitudinal direction of the vertical shaft, And a groove portion.

The strut member is provided in a space between neighboring protruding patterns and is provided with a fixed pattern protruding on both sides of the protruding pattern for fixing the strut member, And a groove is formed in the strut member at a position corresponding to the fixed pattern so that the fixed pattern can be inserted into the groove.

Wherein the slide bracket is composed of a body plate and a slide plate which are orthogonally coupled to each other and the body plate is connected to and fixed to the guide frame and serves as a support for supporting a milestone or solar panel mounted on the guide frame, The slide plate is slidably engaged with the slide groove portion provided in the protruding pattern of the vertical shaft.

A space for drawing out wiring is provided in the vertical shaft, and wirings of the solar cell panel and milestones are drawn into the wiring drawing space.

The milestone includes a light guide plate for guiding surface emission of light generated from the light emitting member, a light emitting member mounting groove provided along one edge of the light guide plate, a light emitting member provided in the light emitting member mounting groove, And a reflective sheet, a marking sheet, and a transparent panel sequentially stacked on the lower surface and the lower surface, respectively.

Wherein the double-sided light receiving solar cell panel comprises two transparent substrates bonded together, and a double-sided light receiving solar cell provided on the two transparent substrates, wherein a double-side light receiving solar cell A solar cell mounting groove is provided.

A terminal box is further provided at an upper end of the strut, and a battery and a control device are provided in the terminal box. The battery stores electric power produced by the solar panel and outputs electric power to the light emitting member, the luminescent marker panel, And the control device controls operation of the solar panel, the light emitting member of the milestone, the luminescent marker panel, and the illumination.

Wherein the light emitting display panel further comprises a light emitting member that emits light using power generated by the double sided light receiving solar cell as a power source, And a lower housing coupled to the lower housing to isolate the light emitting member and the light guide plate from the external environment, wherein the light guide plate includes a light guide plate, A first scattering inducing pattern and a second scattering inducing pattern having concavo-convex shapes are formed on the side surface and the bottom surface, respectively, and scattering protrusions are provided on the upper portion of the upper housing.

The milestone structure using the double-sided light receiving solar cell according to the present invention has the following effects.

Since milestones and solar panels can be selectively mounted on protruding patterns provided in a plurality of directions on the supporting surface, not only the basic functions as milestones, but also the efficiency of light reception of the solar panels can be improved. In addition, since the milestone and the solar cell panel are coupled to the support via the guide frame and the slide bracket, the milestones and the solar cell panel can be easily mounted and the stability of the mount can be improved.

In addition to this, it is possible to improve the light-receiving efficiency and photoelectric conversion efficiency by applying the double-sided light-receiving solar cell, and by interposing the double-sided light-receiving solar cell between the two transparent substrates, Can be effectively protected. In addition, since the light emitting member is provided at a certain depth of the light guide plate along the rim of the light guide plate and the scattering inducing pattern is provided on the upper and lower surfaces of the light guide plate, the brightness of the light guide plate can be uniformly maintained.

1 is a perspective view of a milestone structure using a double-sided light receiving solar cell according to an embodiment of the present invention.
Fig. 2 is an exploded perspective view showing a joining structure of the strut and milestones; Fig.
3 is an exploded perspective view showing a joining structure of a strut and a solar cell panel.
4 is a sectional view taken along the line AA 'in Fig. 1;
5 is an exploded perspective view of milestones;
6 is a cross-sectional view of a solar cell panel.
Figs. 7 to 9 are block diagrams of a luminescent marker panel. Fig.

The present invention proposes a milestone structure capable of selectively mounting a milestone and a solar cell panel on each side of a strut, thereby improving the fundamental role as a milestone and the light receiving efficiency of the solar cell panel.

In addition, the present invention provides a structure in which a milestone or a solar cell panel is coupled to a pillar via a guide frame and a slide bracket, thereby enhancing ease of mounting of the milestone and the solar cell panel and stability of the stationary mount.

In addition, the present invention provides a technology in which a double-side light receiving solar cell is applied to a milestone structure. A double-sided light-receiving solar cell is a device that can receive light through both sides of a solar cell. By applying a double-sided light-receiving solar cell, it can receive a constant amount of light irrespective of the position of the sun. Specifically, the present invention provides a double-sided light-receiving solar cell that protects a double-sided light-receiving solar cell from an external environment by interposing a double-sided light-receiving solar cell between two transparent substrates (for example, tempered glass) Provide a technique that can be kept constant.

Hereinafter, a milestone structure using a double-sided light receiving type solar cell according to an embodiment of the present invention will be described in detail with reference to the drawings.

Referring to FIGS. 1 to 4, a milestone structure using a double-sided light receiving solar cell according to an embodiment of the present invention includes a strut 10, a milestone 30, and a solar cell panel 40.

The column 10 is vertically fixed to the ground to provide a mounting space for the milestones 30 and the solar cell panel 40. The struts 10 are made up of a vertical shaft 11 and a strut member 12 in detail. The vertical shaft 11 constitutes a skeleton of the column 10 and substantially fixes the milestone 30 and the solar cell panel 40 and provides a seating space for the column 12. The vertical shaft 11 is provided with a wiring drawing space 17 in which the wiring of the solar cell panel 40 and the wiring of the milestone 30 are drawn into the wiring drawing space 17 .

The vertical shaft 11 is in the form of a rod having a cross sectional shape and the vertical shaft 11 is provided with a slide groove portion 14 to which a slide bracket 22 described later is coupled. A protruding pattern 13 is provided on each surface of the vertical shaft 11 having a rectangular columnar shape and the protruding pattern 13 has a shape extending in the longitudinal direction of the vertical shaft 11, The pattern 13 has a slide groove portion 14 to which the slide bracket 22 is coupled. The slide bracket 22 is integrally formed with the milestone 30 or the guide frame 21 on which the solar cell panel 40 is mounted and is connected to the slide groove 14 of the slide bracket 22, And the solar cell panel 40 can be fixed to the support 10. The coupling structure between the slide bracket 22 and the slide groove 14 will be described later in detail.

The number of the protruding patterns 13 may be varied according to the sectional shape of the vertical shaft 11. The number of the protruding patterns 13 may be determined depending on the cross sectional shape of the vertical shaft 11, Can be designed differently. For example, in the case where the vertical shaft 11 is in the form of a triangular prism, protruding patterns 13 may be provided on three sides of the triangular prism, and five protruding patterns 13 may be provided in the case of a pentagonal prism. can do.

The strut member 12 forms an outer shape of the strut 10 and is mounted in a cross-shaped hollow space of the vertical shaft 11. That is, the strut member 12 is provided in the space between the adjacent protruding patterns 13. The support member 12 is in the form of a rectangular parallelepiped extending in the longitudinal direction of the vertical shaft 11 and a fixed pattern 15 is provided on one side of the protrusion pattern 13 for fixing the support member 12 . The fixed pattern 15 is provided on both side portions of the protruding pattern 13 and protrudes on both side portions of the protruding pattern 13. The strut member 12 is fitted in a space between neighboring protruding patterns 13 and a fixing pattern 15 is inserted into the strut member 12 at a position corresponding to the fixed pattern 15 Grooves 16 are provided.

The milestone 30 and the solar cell panel 40 are fixed to the struts 10 via the guide frame 21 and the slide bracket 22 and the guide frame 21 and the slide bracket 22, (22) forms an integral type.

Specifically, the guide frame 21 provides a mount space for the milestone 30 or the solar cell panel 40, and has a cross-section of a 'C' shape. Two guide frames 21 are provided opposite to each other and mounted in such a manner that the milestones 30 or the solar cell panels 40 are sandwiched between the two guide frames 21.

The slide bracket 22 is provided at the lower end of each guide frame 21 and is composed of a body plate 22a and a slide plate 22b in detail. Both the body plate 22a and the slide plate 22b have a flat plate shape and are coupled in an orthogonal shape. The body plate 22a is connected to and fixed to the guide frame 21 and serves as a support for supporting the milestone 30 or the solar cell panel 40 mounted on the guide frame 21. [ Here, the body plate 22a and the guide frame 21 may be connected and fixed via bolts or rivets. The slide plate 22b is slidably coupled to the slide groove 14 provided in the protruding pattern 13 of the vertical shaft 11. The slide plate 22b and the slide groove 14 have a shape corresponding to . The slide plate 22b of the slide bracket 22 is coupled to the slide groove portion 14 of the protrusion pattern 13 of the vertical shaft 11 so that the slide plate 22b It is possible to mount the fixed guide frame 21, that is, the guide frame 21 on which the milestone 30 or the solar cell panel 40 is mounted, on the support 10.

Next, the detailed configuration of the milestone 30 and the solar cell panel 40 will be described.

The milestones 30 are mounted in the two guide frames 21 and mounted on the protruding patterns 13 of the vertical shaft 11 precisely on the pillars 10 via the slide brackets 22, (See FIG. 2). In the embodiment of the present invention, the solar cell panel 40 is mounted on one protruding pattern 13, but when mounted on all four protruding patterns 13 or in the case of a triangular prismatic vertical shaft 11 It is also possible to mount it on the three protruding patterns 13.

The milestones 30 and 30 include a light guide plate 31, a light emitting member 32, a reflection sheet 33, a mark sheet 34 and a transparent panel as shown in FIG. The light guide plate 31 guides surface light emission of the light emitted from the light emitting member 32 and provides a mounting space for the reflective sheet 33 and the marking sheet 34. The plane shape of the light guide plate 31 may take the form of a square, a triangle, a circle, an arrow, a triangle, a circle, or the like.

A light emitting member mounting groove 31a is formed at one side of the light guide plate 31 and has a light guide plate 31 having a predetermined depth. The light emitting member mounting groove 31a may be provided along one edge of the light guide plate 31. A light emitting member 32 is provided in the light emitting member mounting groove 31a. As the light emitting member 32, an LED module may be used and operated by the power produced by the solar cell panel 40. In one embodiment, a band-shaped LED module may be provided in the light emitting member mounting groove 31a.

In the state that the LED module is provided in the light emitting member mounting groove 31a, the light emitted by the LED module moves along the medium (the inside of the light guide plate 31) and ultimately diverges through the upper and lower portions of the light guide plate 31. It is preferable that the LED module is positioned at the center of the light guide plate 31 so that the light of the LED module is uniformly emitted through the upper and lower portions of the light guide plate 31. [

In order to increase the luminance of the light emitted through the upper and lower surfaces of the light guide plate 31 and to uniform the luminance on the front face of the light guide plate 31, scattering of concave- An induction pattern 31b is provided. The scattering inducing pattern 31b is for increasing the light transmittance. As the scattering inducing pattern 31b has a concave-convex shape, the contact area of light is increased and the light path is varied variously, The amount of light emitted from the upper surface and the lower surface can be increased.

The reflective sheet 33 and the indicia sheet 34 are sequentially stacked on the upper surface and the lower surface of the light guide plate 31, respectively. The reflective sheet 33 reflects light and the mark sheet 34 indicates a mark or a phrase to be guided. The mark 34 or the mark is to be guided by the mark sheet 34, So that the sheet 33 is exposed. The transparent panel (not shown) is provided on the upper surface of the light guide plate 31 and on the underside marking sheet 34 and includes the light guide plate 31, the light emitting member 32, the reflection sheet 33, From the external environment.

The solar cell panel 40 is mounted in the two guide frames 21 and mounted on the projecting pattern 13 of the vertical shaft 11 precisely on the support 10 via the slide bracket 22 (See FIG. 3). In the embodiment of the present invention, the solar cell panel 40 is mounted on the two protruding patterns 13, but it may be mounted on all four protruding patterns 13 or in the case of the triangular prism vertical shaft 11 It is also possible to mount it on the three protruding patterns 13.

The solar cell panel 40 is composed of a double-sided light receiving solar cell 42 and two transparent substrates 41 as shown in FIG. The double-sided light receiving solar cell 42 is provided between two transparent substrates 41, and the two transparent substrates 41 are bonded together. The light receiving characteristics of the double-sided light receiving solar cell 42 are maintained and the double-sided light receiving solar cell 42 is removed from the external environment as the double-sided light receiving solar cell 42 is provided between the bonded transparent substrates 41 It becomes possible to protect it. In order to prevent complete adhesion of the transparent substrate 41 due to the thickness of the double-sided light receiving solar cell 42, a double-side light receiving solar cell 42 is formed on the inner side surface of each transparent substrate 41 A solar cell mounting groove is provided. In addition, the solar cell panels 40 and 40 may be formed by vacuum-bonding two transparent solar cells 42 between two transparent substrates 41 in the form of plates, in addition to the structure described above.

In addition, the terminal box 80 is further provided at the upper end of the strut 10, in addition to the above-described configuration. The terminal box 80 is provided with a battery and a controller (not shown). The battery stores electric power produced by the solar cell panel 40 and supplies electric power to the light emitting member of the milestone 30, the luminescent marker panel described later and the illumination. The control device controls the solar cell panel 40, , The light emitting member of the milestone 30, the luminescent marker panel, and the illumination. The light 70 may be provided on the terminal box 80.

Further, a light emitting panel 50 is provided on one side of the terminal box 80. The luminescent marker panel 50 plays a role of night-time illumination through light emission of the light emitting element, and clearly shows a specific mark or pattern, and has the following structure.

7 and 8, the light emitting display panel 50 includes a light emitting member 51, a light guide plate 52, an upper housing 53, and a lower housing 54.

The light emitting member 51 emits light using the power generated by the double-sided light receiving type solar cell as a power source, and the light guide plate 52 serves to induce surface light emission of the light generated from the light emitting member 51 do. The light guide plate 52 may be formed in a rectangular parallelepiped shape. Each corner of the light guide plate 52 is chamfered, and the light emitting member 51 is formed in a chamfered shape. That is, the light emitting member 51 is provided at each corner of the light guide plate 52.

On the side surface of the light guide plate 52, a first scattering inducing pattern 52a having a concave-convex shape is repeatedly arranged. The first scattering inducing pattern 52a is for increasing light transmittance to the side surface. As the first scattering inducing pattern 52a has a concavo-convex shape, the contact area of light is increased, The amount of light that ultimately emits light to the side of the light guide plate 52 can be increased. Such a side light emission can improve the discrimination degree.

In addition, a specific mark or pattern may be provided on the upper surface of the light guide plate 52, and a second scattering inducing pattern 52b may be provided on the lower surface of the light guide plate 52 so that the pattern may be clearly seen at the time of light emission. do. The second scattering inducing pattern 52b has a shape corresponding to the specific pattern. That is, a second scattering inducing pattern 52b having a concave-convex shape is provided on the lower surface of the light guide plate 52 at a position corresponding to the pattern, and the second scattering inducing pattern 52b has a convex- As the area increases and the light path changes in a variety of ways, the transmittance of light can be increased and ultimately the pattern is clearly visible.

Meanwhile, the lower housing 54 provides a space in which the light emitting member 51 and the light guide plate 52 are provided. The upper housing 53 is coupled with the lower housing 54 to isolate the light emitting member 51 and the light guide plate 52 from the external environment and a scattering protrusion 53a To guide the light transmitted through the light guide plate 52 to be radiated in various directions.

The above-described luminescent marker panel may be configured as shown in Fig. That is, the reflective film 61, the light guide plate 62, the translucent marker plate 64, and the transparent plate 65 may be sequentially stacked, and a linear light emitting member (not shown) may be disposed on one side of the light guide plate 62 63 may be provided. The laminated structure of the reflective film 61, the light guide plate 62, the translucent marker plate 64 and the transparent plate 65 is provided in the upper housing 53 and the lower housing 54.

10: support 11: vertical shaft
12: strut member 13: protruding pattern
14: slide groove part 15: stationary pattern
16: groove 17: space for drawing wiring
21: guide frame 22: slide bracket
22a: body plate 22b: slide plate
30: milestone 31: light guide plate
31a: light emitting member mounting groove 31b: scattering inducing pattern
32: light emitting member 33: reflective sheet
34: Marking sheet
40: double-sided light receiving solar cell panel 41: transparent substrate
42: double-sided light receiving solar cell 50: luminescent marker panel
50: luminescent marker panel 51: luminescent member
52: light guide plate 52a: first scattering inducing pattern
52b: second scattering inducing pattern 53: upper housing
53a: scattering protrusion 54: lower housing
70: Lighting 80: Terminal box

Claims (9)

A strut comprising a vertical shaft and a strut member; And
A milestone mounted on the support and a solar cell panel,
A protrusion pattern extending in a longitudinal direction of the vertical shaft is provided on each surface of the vertical shaft, a slide groove portion is provided in the protrusion pattern,
The milestone or the solar cell panel is mounted in a form sandwiched between two guide frames, and a slide bracket integrated with the guide frame is provided at a lower end of the guide frame,
Wherein the slide bracket is coupled to the slide groove portion of the protruding pattern so that the milestone or the solar panel is mounted on the support,
The solar cell panel includes a double-side light-receiving solar cell,
The strut member is provided in a space between neighboring protruding patterns,
A fixed pattern protruding on both sides of the protruding pattern for fixing the strut member is provided,
Wherein the support member is fitted in a space between neighboring protruding patterns and is provided with a groove in which a fixing pattern can be fitted to a strut member at a position corresponding to the fixed pattern. Cell - based milestone structures.
2. The apparatus of claim 1, wherein the vertical shaft is in the form of a polygonal column,
Wherein a protrusion pattern is provided on each side of the vertical shaft and the protrusion pattern extends in the longitudinal direction of the vertical shaft and the protrusion pattern includes a slide groove portion to which the slide bracket is coupled, A milestone structure using solar cells.
delete [3] The apparatus of claim 2, wherein the slide bracket comprises a body plate and a slide plate,
The body plate is connected to and fixed to the guide frame, and serves as a base for supporting the milestone or the solar panel mounted on the guide frame,
Wherein the slide plate is slidably engaged with a slide groove portion provided in a protruding pattern of the vertical shaft.
2. The solar cell according to claim 1, wherein a wiring drawing space is provided in the vertical shaft, and the wirings of the solar cell panel and milestones are drawn into the wiring drawing space. Milestone structure.
delete The solar cell module according to claim 1, wherein the double-sided light receiving solar cell panel comprises two transparent substrates bonded together, and a double-sided light receiving solar cell provided on the two transparent substrates,
And a solar cell mounting groove on which a double-sided light receiving solar cell is mounted is provided on an inner surface of each of the transparent substrates.
The battery charger according to claim 1, further comprising a terminal box at an upper end of the strut, a battery and a control device in the terminal box,
The battery stores electric power produced by the solar panel and supplies electric power to the light emitting member, the luminescent marker panel and the illumination of the milestone.
Wherein the control device controls the operation of the solar cell panel, the light emitting member of the milestone, the luminescent marker panel, and the illumination.
delete

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