KR101868816B1 - Road boundary stone for safety guide with solar cell - Google Patents

Abstract

The present invention relates to a safety-induction type solar photovoltaic block.
In the safety-inducing type solar cell building of the present invention, the lighting installation groove 110 is formed at the center of the upper surface, and the solar unit installation groove 120, which is deeper than the lighting installation groove 110, A vertical groove 130 is formed at the bottom of the end of the lighting installation groove 110 facing the solar unit installation groove 120 in the vertical direction deeper than the bottom surface of the solar unit installation groove 120, A stone block member 100 having an inclined groove 140 communicating with a lower end of the vertical groove 130 is formed at the bottom of the end of the solar unit installation groove 120, The upper portion of the upper surface of the printing unit 220 is covered with a lower acrylic sheet 210 having a bonding portion 230 to which an adhesive is applied, A plate 200; The bottom of the lower acrylic plate 200 is adhered and fixed to the adhesive portion 230 of the lower acrylic plate 200 and the depressed groove 310 is formed at the center of the bottom portion at a position corresponding to the boundary line of the image of the printing portion 220 A plurality of chip mounting grooves 320 are formed on the sidewall surface and a transparent upper acrylic plate 300 having a ring seating portion 330 formed at a lower height than the center of the upper surface is formed around the upper surface, ; A ring-shaped reflection plate 400 adhered and fixed to the upper acrylic plate 300 through an adhesive to the ring seating portion 330; A solar panel 920 is installed on the upper surface of the case 910 and a battery for storing the electric power produced by the solar panel 910 is installed inside the case 910 And a first power line 930 protrudes from the case 910 to one side of the case 910 and is connected to the circuit portion of the lower case 910 so that the inclined groove 140 is formed. And a solar unit (900) continuously inserted into the vertical groove (130); An LED chip 1000 installed in the chip mounting groove 320 and connected to a second power line 1010 connected to the first power line 930 to receive power from the solar unit 900, ; ≪ / RTI >
According to the present invention, it is possible to prevent troubles such as electric leakage due to water infiltration of the solar unit, prevent deterioration of image visibility due to adhesive penetration, A safety-guided solar photovoltaic board is provided.

Description

[0001] The present invention relates to a safety boundary-

The present invention relates to a safety-induction type solar photovoltaic apparatus using a lighting device driven by a solar cell, wherein a boundary between a roadway and a sidewalk is uniformly displayed at night, thereby inducing safety. Thereby increasing the lifetime of the parts and improving the visibility by being brighter than in the prior art.

Boundary stones are usually used to separate roadways and sidewalks. In recent years, they have been installed on the boundary of a traffic island installed at the middle of a wide-width road, on the shoulder of a motorway, It is mainly used as a boundary mark of safety area of pedestrian.

However, marble or cement materials have the disadvantage that it is difficult for pedestrians or vehicle drivers to easily identify them at night because of the nature of the marble or cement material.

As a means for solving the disadvantages of the prior art barrier seats, it has been made easy to identify the barrier seams by attaching reflection paper that can be reflected by the light of the vehicle to the front of the barrier seams. However, The reflection performance is deteriorated and the conventional problems are directly obtained, and there is a problem that the boundary stones are blurred by the separated reflection paper.

As a technique for solving such a problem, "a light boundary stone using a solar cell" (Korean Patent Registration No. 10-0555413, Patent Document 1) is disclosed.

In Patent Document 1, a groove is formed in a cubic stone block, while a solar cell unit and a lighting unit are installed in the grooves, and the lighting unit and the solar cell unit are connected to each other through electric wires to power the solar cell So that the lighting unit can be illuminated at night so that the walker can be guided in the sidewalk.

Fig. 1 shows the main structure of the patent document 1.

Referring to the drawing, the block body 20 is provided with a solar cell unit 30 at the upper center thereof, and the hypotenuse 27, which is inclined in the center at a central portion thereof, is machined while the corner of the block body 20 is chamfered A hole 25 is formed in the hypotenuse 27 and an acrylic plate 55 provided with a high intensity reflection sheet 60 is provided on the hypotenuse 27. An illumination plate A structure in which a transparent acrylic plate 52 is provided while installing a transparent acrylic plate 53 is shown.

At this time, the wiring construction for connecting the solar cell unit 30 and the illumination light 53 can be easily performed through hole piercing.

In addition, when the plate member is provided on the corner surface of the block, the hole for the wiring is inclined downward, or the depth of the solar cell unit is not relatively deep, so that the electric leakage problem is relatively small.

However, in the case where the position of the illumination light 53 is located on the upper surface rather than the sidewall surface or the inclined surface of the block, in particular, when the sidewall surface of the block does not project over the road surface, the depth of the solar cell unit is deeper .

2 and 3 show such a construction example. The solar cell unit 30 is thicker than the lighting unit 50 because the battery and the circuit unit 40 are installed in the interior of the solar cell unit 30, ) Is made deeper than the depth of the lighting unit mounting portion (60).

In FIG. 2, reference numeral 70 denotes an electric wiring. As shown in FIG. 3, a hole is drilled downward at a lower edge of the lighting unit mounting portion 60 by a drill or the like so that the lower end corner of the solar unit mounting portion 65 The holes 71 are formed so that the electric wires are inserted into the holes 71. As shown in FIG.

Since the solar unit 30 has a built-in storage battery and a circuit, it needs to be protected from moisture from the outside. The structure of the solar unit 30 allows water to flow into the interior through the hole 71 inclined from the lighting unit mounting portion 60, There is a problem that can occur.

The solar cell unit 30 is relatively smaller in size than the lighting unit 50 while the lighting unit 50 is large in size so that the space between the outer circumferential surface of the lighting unit 50 and the inner circumferential surface of the lighting unit- A gap is likely to be generated due to an impact load or the like, so that the wiring structure as described above easily penetrates moisture into the solar cell unit 30 and causes a failure, which increases the maintenance cost.

The printed material 54 and the bottom of the acrylic sheet 55 are adhered and fixed to each other while the printed material 54 is adhered to the acrylic sheet material 55. The adhesive can not be adhered to the printed material 54 with a constant width, There is a problem in that the image 58 of the printed matter 54 becomes unsealable because it penetrates into the center side of the printed matter 54. [

In addition, the periphery of the transparent acrylic plate 52 can be protected by providing the metal plate 51 around the transparent acrylic plate 52. However, since the metal plate 51 and the transparent acrylic plate 52 are adhered through the adhesive agent, The light of the light 53 is remarkably deteriorated in performance by the metal frame 51 and can not reach the central portion of the illumination light 53 and the central portion of the printed material 54, There were problems.

In addition, since the printed material 54 is adhered to the upper portion of the acrylic plate material 55, printing, cutting, and bonding of the printed material 54 must be performed.

KR 10-0555413 (2006.02.20)

In order to solve the above-described problems, the safety-induction type solar cell building of the present invention is characterized in that vertical grooves perpendicular to the bottom surface of the lower central lighting installation groove, The bottom of the groove of the solar unit installation groove is formed at the floor bottom so that the lower portion of the vertical groove and the lower portion of the inclined groove are naturally lower than the bottom of the solar unit installation groove by forming the inclined groove communicating with the vertical groove, Water entering from the upper part to the inside, moisture formed by the condensation, moisture that flows through the gap of the block made of stone, etc. are prevented from being primarily accumulated in the solar unit installation groove, To minimize the occurrence of failures in the system.

In addition, the image to be expressed is formed by printing on the lower acrylic plate, thereby minimizing the manufacturing cost and forming the overflow preventing groove between the peripheral portion and the adhesive portion, thereby preventing the adhesive from penetrating into the printed image area .

In addition, a reflection plate is installed around the upper acrylic plate so that the light can reach the central area without fail, and an anti-adhesive groove, which is an area where the adhesive is not applied, is formed so that the performance of the reflection plate can be exerted smoothly .

In addition, a plurality of through holes and bottom grooves are formed in the lower portion of the solar unit, thereby preventing the solar unit from secondarily contacting the moisture, thereby further preventing the life of the solar unit due to moisture contact.

In order to solve the above-described problems, the safety-induction type solar cell building of the present invention is provided with a lighting installation groove 110 at the center of the upper surface, and a solar unit installation with a depth deeper than the lighting installation groove 110 A vertical groove 130 is formed in the bottom of the end portion of the lighting installation groove 110 facing the solar unit installation groove 120 so as to be vertically deeper than the bottom surface of the solar unit installation groove 120 And a slope groove 140 communicating with the lower end of the vertical groove 130 is formed at the bottom of the end of the solar unit installation groove 120 facing the lighting installation groove 110 )Wow; The upper portion of the upper surface of the printing unit 220 is covered with a lower acrylic sheet 210 having a bonding portion 230 to which an adhesive is applied, A plate 200; The bottom of the lower acrylic plate 200 is adhered and fixed to the adhesive portion 230 of the lower acrylic plate 200 and the depressed groove 310 is formed at the center of the bottom portion at a position corresponding to the boundary line of the image of the printing portion 220 A plurality of chip mounting grooves 320 are formed on the sidewall surface and a transparent upper acrylic plate 300 having a ring seating portion 330 formed at a lower height than the center of the upper surface is formed around the upper surface, ; A ring-shaped reflection plate 400 adhered and fixed to the upper acrylic plate 300 through an adhesive to the ring seating portion 330; A solar panel 920 is installed on the upper surface of the case 910 and a battery for storing the electric power produced by the solar panel 910 is installed inside the case 910 And a first power line 930 protrudes from the case 910 to one side of the case 910 and is connected to the circuit portion of the lower case 910 so that the inclined groove 140 is formed. And a solar unit (900) continuously inserted into the vertical groove (130); An LED chip 1000 installed in the chip mounting groove 320 and connected to a second power line 1010 connected to the first power line 930 to receive power from the solar unit 900, ; ≪ / RTI >

The overflow preventing groove 210 is formed at the boundary between the printing unit 220 and the adhesive unit 230 to prevent the adhesive applied to the adhesive unit 230 from flowing into the printing unit 220 .

The ring seating part 330 is formed with a bonding prevention groove 331 on the plane where the chip mounting groove 320 is located and the reflection plate 400 is fixed to the ring seating And is adhered and fixed to the upper acrylic plate 300 through an adhesive agent.

A plurality of through holes 810 are formed in the bottom of the solar unit installation groove 120 so as to be vertically penetrated through the drainage member 800 And a moisture retention groove 820 is formed at a bottom portion of the bottom of the solar unit installation groove 120 so as to be separated from a bottom surface of the solar unit installation groove 120.

Most preferably, the lighting installation groove 110 is formed at the center of the upper surface, and a solar unit installation groove 120 having a deeper depth than the lighting installation groove 110 is formed on the upper surface of the upper surface, Vertical grooves 130 are formed at the bottoms of the end portions of the lighting installation grooves 110 so as to face the lamp installation recesses 120. The vertical grooves 130 are formed in a vertical direction deeper than the bottom surface of the solar unit installation recesses 120, A stone block member (100) having an inclined groove (140) communicating with a lower end of the vertical groove (130) is formed at the bottom of the end of the unit installation groove (120). The overflow prevention groove 210 is formed on the upper surface of the lighting fixture groove 110 so as to be spaced apart from the outer circumference of the lighting fixture groove 110. The upper surface of the center of the overflow prevention groove 210, A lower acrylic plate 200 on which an adhesive portion 230 to which an adhesive is applied is formed on an upper side of the outer side of the overflow prevention groove 210; The bottom of the lower acrylic plate 200 is adhered and fixed to the adhesive portion 230 of the lower acrylic plate 200 and the depressed groove 310 is formed at the center of the bottom portion at a position corresponding to the boundary line of the image of the printing portion 220 A plurality of chip mounting grooves 320 are formed on the sidewalls and a ring mounting portion 330 is formed around the upper surface of the ring mounting portion 330. The ring mounting portion 330 has a lower height than the center of the upper surface, A transparent upper acrylic plate 300 having a bonding preventing groove 331 formed on a plane where the chip mounting groove 320 is located; A ring-shaped reflection plate 400 adhered and fixed to the upper acrylic plate 300 through an adhesive to the ring seating portion 330 excluding the adhesion preventing groove 331; A plurality of through holes 810 are formed in the bottom surface of the solar unit installation groove 120 and a moisture stay groove 820 is formed at a bottom portion of the bottom 820 to be spaced apart from the bottom surface of the solar unit installation groove 120. A formed drainage material 800; A solar panel 920 is installed on the upper surface of the case 910 and the solar panel 910 is installed inside the case 910. The solar panel 920 is installed in the solar panel installation groove 120, A first power line 930 protrudes from the case 910 to the outside of the case 910 while one side of the case 910 is connected to the bottom of the case 910, A solar unit 900 continuously inserted into the inclined grooves 140 and the vertical grooves 130; An LED chip 1000 installed in the chip mounting groove 320 and connected to a second power line 1010 connected to the first power line 930 to receive power from the solar unit 900, ; ≪ / RTI >

According to the present invention, vertical grooves perpendicular to the bottom surface of the end portion of the central illumination installation groove where the illumination device is installed are drilled deeper than the bottom surface of the solar unit installation groove. The lower part of the vertical groove and the lower part of the inclined groove are naturally lower than the bottom of the solar unit installation groove so that water flowing into the interior from the upper part through the gap and water formed by condensation, It is possible to prevent the phenomenon that the water entering through the gap is piled up in the solar unit installation groove in the first place, thereby reducing the occurrence of a failure such as a short circuit due to moisture contact with the solar unit.

In addition, the image to be expressed is formed by printing on the lower acrylic plate, thereby minimizing the manufacturing cost and forming the overflow preventing groove between the peripheral portion and the adhesive portion, thereby preventing the adhesive from penetrating into the printed image area .

In addition, the reflection plate is installed around the upper acrylic plate so that the light can reach the central area without fail, and the anti-adhesive groove, which is an area where the adhesive is not applied, is formed, so that the performance of the reflection plate can be exerted smoothly.

In addition, since a plurality of through holes and bottom grooves are formed in the lower portion of the solar unit, it is possible to prevent the solar unit from secondarily making contact with water, thereby further preventing shortening of life due to moisture contact.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exploded perspective view showing an example of a conventional safety induction type solar light boundary sheet. FIG.
Fig. 2 is a sectional view showing the installation state of Fig. 1; Fig.
3 is a schematic cross-sectional view showing an example of hole drilling for the block construction of FIGS.
4 is a partially cut exploded perspective view showing the safety-guided solar photovoltaic boundary sheet of the present invention.
5 is an exploded cross-sectional view of a safety-guided solar photovoltaic boundary sheet of the present invention.
6 is a cross-sectional view and a perspective view showing a gap material in the present invention.
7 is an exploded perspective view showing a state in which an LED chip is connected to an upper acrylic plate in the present invention.
8 is a perspective view of a safety-induction type solar photovoltaic boundary stone of the present invention.

The safety induction type solar cell boundary stover includes a block member 100, a lower acrylic plate 200, an upper acrylic plate 300, a reflector 400, a solar unit 900, and an LED chip 1000 .

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, components of a safety-guided solar photovoltaic boundary of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 4, the block member 100, which is a component of the present invention, is a portion corresponding to the longitudinal direction of the road, and is formed of a stone having a hexagonal shape having a rectangular shape having a relatively long length.

The lighting device according to one of the claims 1 to 3, wherein the lighting unit comprises a lighting unit, a lighting unit, and a lighting unit. (Not shown).

Although an example in which two solar unit installation grooves 120 are formed is shown in the drawing, the present invention is not limited thereto.

Unlike the related art, the block member 100 is formed with vertical grooves 130 in the vertical direction deeper than the bottom surface of the solar unit installation groove 120 on the bottom side of the end of the lighting installation groove 110 facing the solar unit installation groove 120, Is formed.

An inclined groove 140 communicating with a lower end of the vertical groove 130 is formed at the bottom of the end of the solar unit installation groove 120 facing the lighting installation groove 110.

At this time, the portion where the vertical groove 130 and the inclined groove 140 meet is rounded so that insertion of a wire to be described later can be facilitated.

In addition, by forming the vertical grooves 130 to have a diameter larger than the inclined grooves 140, it is possible to facilitate the insertion of the electric wires and to make the water storage capacity larger.

It is obvious that the diameter of the vertical grooves 130 and the inclined grooves 140 are larger than the diameters of the first power source line 930 and the second power source line 1010.

As shown in FIG. 4, the lower acrylic plate 200, which is a component of the present invention, is inserted and installed in the illumination installation groove 110.

The lower acrylic plate 200 is formed with a printing unit 220 formed by printing an image on a central side thereof.

This is different from the conventional method in which an image-printed sheet is adhered to an acrylic sheet. By adopting a direct printing method, it is possible to reduce manpower and cost of cutting, adhering, and drying a printed sheet do.

The upper surface of the outer side of the lower acrylic plate 200 is formed with a bonding portion 230 to which an adhesive is applied.

However, when the adhesive is applied to the adhesive portion 230, when the adhesive flows into the printing portion 220, the outer portion of the printing portion 220 may be stained and the visibility may be lowered.

However, if the thickness of the adhesive portion 230 is arbitrarily reduced, there is a problem that the adhesive strength is lowered.

In order to solve this problem, in the present invention, the overflow preventing groove 210 is formed at the boundary between the printing unit 220 and the adhering unit 230 so that the adhesive applied to the adhering unit 230 flows into the printing unit 220 .

The overflow preventing groove 210 prevents the adhesive 220 from flowing into the printing part 220 even though an excessive amount of adhesive is applied to the printing part 220.

Also, in the case of using a conventionally printed sheet, the central portion may be higher than the outer portion. In this case, the adhesive force may be lowered. If the printing portion 220 is directly printed on the acrylic plate This phenomenon does not occur and the decrease in the adhesive strength can be prevented.

The upper acrylic plate 300, which is a component of the present invention, is made of a transparent acrylic plate, and its periphery is adhered and fixed by an adhesive applied to the bonding portion 230 of the lower acrylic plate 200.

In addition, a depressed depression 310 is formed at a position corresponding to a boundary line of the image of the printing unit 220 at the center of the bottom, so that light irradiated to the depressed depression 310 is refracted, .

On the other hand, a plurality of chip mounting grooves 320 are formed on the sidewall of the upper acrylic plate 300 as in the prior art.

A ring seating portion 330 is formed around the upper surface of the upper acrylic plate 300 so as to have a lower height than the center of the upper surface.

The reflection plate 400, which is a component of the present invention, is adhered and fixed to the upper acrylic plate 300 through an adhesive to the ring seating portion 330.

At this time, since the reflective plate 400 is fixed through the adhesive, the adhesive may be positioned between the LED chip 1000 and the reflective plate 400, thereby reducing the reflection efficiency.

In order to solve such a problem, as shown in the figure, the ring seating part 330 is formed with a bonding prevention groove 331 on the plane where the chip mounting groove 320 is located, It is preferable that the upper acrylic plate 300 is adhered and fixed to the ring seating portion 330 excluding the adhesion preventing groove 331 through an adhesive.

In this configuration, light emitted from the LED chip 1000 through the reflection plate 400 is maximally reflected, thereby minimizing the loss of light up to the central region of the upper acrylic plate 300, do.

At this time, the adhesion preventing groove 331 may be formed to be spaced apart from the outer circumferential end of the upper acrylic plate 300, as shown in the figure, to prevent the occurrence of voids in the adhesion of the reflection plate 400.

The reflector 400 may have its own perimeter and may be provided with a separate finishing material thereon.

As a preferable finishing material, a finishing ring 700 made of a metal material having excellent fineness such as stainless steel can be adhered and fixed via an adhesive.

When the required thickness of the finishing ring 700 is large, the spacer ring 500 is formed in the shape of a plastic ring. The spacing member 500 is formed in the same shape as the reflection plate 400 and is thicker than the reflection plate 400.

The gap member 500 is adhered and fixed to the reflection plate 400 and the gap member 500 is positioned between the reflection plate 400 and the finishing ring 700 to reduce the cost of the expensive stainless member, .

In addition, when the finishing ring 700 is installed, the upper surface of the finishing ring 700 is aligned with the upper surface of the tempered glass plate 600.

The reinforced glass plate 600 may be installed on the upper acrylic plate 300 to protect the upper acrylic plate 300.

At this time, the reinforced glass plate 600 has the same size as the upper surface area of the upper acrylic plate 300 except for the ring seating portion 330.

Meanwhile, the solar unit 900, which is a component of the present invention, is installed in the solar unit installation groove 120 as shown in FIG.

In addition, a solar battery unit 920 is installed on a top surface of the solar unit 900, and a solar battery is converted into an electric power to produce electric power.

The generated power is charged into the internal battery. Inside the case 910, a circuit part for controlling charging and discharging of the battery is built in.

In addition, a first power line 930 protrudes from the bottom of the case 910 to the outside of the case 910 while one side is connected to the circuit portion.

The first power line 930 may be provided with a connection jack 931 for connection between the wires.

Such a solar unit 900 is not only described in Patent Document 1, but also various known solar photovoltaic units that generate sunlight and generate electricity by using sunlight as an energy source are applied. do.

In the structure of the solar unit 900, the first power line 930 is continuously inserted into the inclined grooves 140 and the vertical grooves 130 described above.

At this time, a temporary space for moisture to stay is formed through the inclined grooves 140 inclined from the bottom surface of the solar unit 900 and the vertical grooves 130 connected thereto, so that the solar unit 900 is isolated from moisture or water, Can be reduced.

As shown in FIG. 1, a drainage member 800 may be installed on a bottom surface of the solar unit installation groove 120 at a lower portion of the solar unit 900, as shown in FIG.

At this time, the water discharger 800 is made of a hard material, which is preferable from the viewpoint of stability against load. In the water discharger 800, a plurality of through holes 810 penetrating up and down as shown in FIG. And a water retention groove 820 spaced apart from the bottom surface of the groove 120 may be formed.

The through hole 810 allows water to be drained to the lower side when water flows in from above the solar unit installation groove 120 due to dew condensation or upper gap, ) And the vertical grooves 130, thereby providing a wider retention space to further protect the solar unit 900 from moisture.

The LED chip 1000 as a component of the present invention is installed in the chip mounting groove 320 and the second power line 1010 connected to the first power line 930 is connected to the solar unit 900, So that the light is emitted.

At this time, it will be obvious that various known lighting devices other than the LED chip can be substituted.

Also, a connection jack 1011 is provided at the end of the second power line 1010 so that the connection can be easily and detachably connected to the connection jack 931 described above.

Hereinafter, the operation of the safety-guided solar photovoltaic board of the present invention will be described.

First, in the construction process, the vertical groove 130 is vertically installed in the solar unit installation groove 120 of the block member 100, and the inclined groove 140 is sloped vertically So as to communicate with the groove 130.

The remaining space after the installation of the power supply lines 930 and 1010 is filled with moisture or moisture because the vertical groove 130 and the inclined groove 140 are located below the bottom surface of the solar unit 900 after the installation process is completed. And the solar unit 900 is in a non-contact state with moisture or moisture, thereby reducing the probability of occurrence of a fault such as a short circuit.

That is, even if a variety of water contact factors such as condensation phenomenon, upper gap generation, and lower gap generation occur, it is possible to protect the solar unit by maximizing water drainage and provisional stay.

Furthermore, the drainage material 800 is installed on the bottom surface of the solar unit installation groove 120, thereby securing a secondary drainage and temporary storage space, thereby minimizing the occurrence of an electric leakage fault.

Since the printing unit 220 is formed in advance on the lower acrylic plate 200, unlike the conventional printing method, the printed prints are not cut and adhered to each other. Thus, ease of installation is improved.

In addition, when the upper acrylic plate 300 is adhered to the upper acrylic plate 200 in the construction process, the adhesive is applied to the adhering portion 230 of the lower acrylic plate 200, The printing unit 220 does not move to the printing unit 220, thereby maintaining excellent print quality.

In addition, unlike the prior art, since the reflection plate 400 is provided and the adhesive prevention groove 331 is formed in the upper acrylic plate 300, the performance of the reflection plate 400 is maximized to improve the reflection efficiency.

The safety-guided solar photovoltaic glazing of the present invention may be applied to various road boundaries such as bicycle roads, India, walkways, theme streets, parks and surrounding landscapes, and scenery of public buildings.

100: block member 110: lighting installation groove
120: Solar unit installation groove 130: Vertical groove
140: inclined groove 200: lower acrylic plate
210: Overflow prevention groove 220:
230: Adhesive part 300: Upper acrylic plate
310: engraved groove 320: chip mounting groove
330: ring mounting portion 331:
400: reflector 500: spacing material
600: Tempered glass plate 700: Finishing ring
800: drainage material 810: through hole
820: Water retention groove 900: Solar unit
910: Case 920: Solar panel
930: first power line 1000: LED chip
1010: second power line

Claims (5)

In solar photovics installed at the border of roads,
And a solar unit installation groove 120 having a depth deeper than the lighting installation groove 110 is formed on an outer surface of an upper surface of the solar unit installation groove 120, A vertical groove 130 is formed at the bottom of the end portion of the lighting installation groove 110 in the vertical direction deeper than the bottom surface of the solar unit installation groove 120. The solar unit installation groove 120 facing the lighting installation groove 110 And a slope groove (140) communicating with a lower end of the vertical groove (130) is formed on an end side of an end portion of the stone block member (100);
The upper portion of the upper surface of the printing unit 220 is covered with a lower acrylic sheet 210 having a bonding portion 230 to which an adhesive is applied, A plate 200;
The bottom of the lower acrylic plate 200 is adhered and fixed to the adhesive portion 230 of the lower acrylic plate 200 and the depressed groove 310 is formed at the center of the bottom portion at a position corresponding to the boundary line of the image of the printing portion 220 A plurality of chip mounting grooves 320 are formed on the sidewall surface and a transparent upper acrylic plate 300 having a ring seating portion 330 formed at a lower height than the center of the upper surface is formed around the upper surface, ;
A ring-shaped reflection plate 400 adhered and fixed to the upper acrylic plate 300 through an adhesive to the ring seating portion 330;
A solar panel 920 is installed on the upper surface of the case 910 and a battery for storing the electric power produced by the solar panel 910 is installed inside the case 910 And a first power line 930 protrudes from the case 910 to one side of the case 910 and is connected to the circuit portion of the lower case 910 so that the inclined groove 140 is formed. And a solar unit (900) continuously inserted into the vertical groove (130);
An LED chip 1000 installed in the chip mounting groove 320 and connected to a second power line 1010 connected to the first power line 930 to receive power from the solar unit 900, ; ≪ / RTI >
Safety Induced Photovoltaic Boundary.
The method according to claim 1,
An overflow preventing groove 210 is formed at a boundary between the printing unit 220 and the adhesive unit 230 to prevent the adhesive applied to the adhesive unit 230 from flowing into the printing unit 220. [
Safety Induced Photovoltaic Boundary.
The method according to claim 1,
The ring seating part 330 is formed with a bonding prevention groove 331 on a plane where the chip mounting groove 320 is located,
Wherein the reflection plate 400 is adhered and fixed to the upper acrylic plate 300 through an adhesive to the ring seating portion 330 excluding the adhesion prevention groove 331. [
Safety Induced Photovoltaic Boundary.
The method according to claim 1,
A drainage member 800 is installed on a bottom surface of the solar unit installation groove 120 below the solar unit 900,
Wherein a plurality of through holes 810 are formed in the water discharging member 800 and water recesses 820 are formed at the bottom of the water discharging unit 800 so as to be separated from the bottom surface of the solar unit mounting groove 120. [
Safety Induced Photovoltaic Boundary.
In a safety-guided solar photovoltaic block,
And a solar unit installation groove 120 having a depth deeper than the lighting installation groove 110 is formed on an outer surface of an upper surface of the solar unit installation groove 120, A vertical groove 130 is formed at the bottom of the end portion of the lighting installation groove 110 in the vertical direction deeper than the bottom surface of the solar unit installation groove 120. The solar unit installation groove 120 facing the lighting installation groove 110 And a slope groove (140) communicating with a lower end of the vertical groove (130) is formed on an end side of an end portion of the stone block member (100);
The overflow prevention groove 210 is formed on the upper surface of the lighting fixture groove 110 so as to be spaced apart from the outer circumference of the lighting fixture groove 110. The upper surface of the center of the overflow prevention groove 210, A lower acrylic plate 200 on which an adhesive portion 230 to which an adhesive is applied is formed on an upper side of the outer side of the overflow prevention groove 210;
The bottom of the lower acrylic plate 200 is adhered and fixed to the adhesive portion 230 of the lower acrylic plate 200 and the depressed groove 310 is formed at the center of the bottom portion at a position corresponding to the boundary line of the image of the printing portion 220 A plurality of chip mounting grooves 320 are formed on the sidewalls and a ring mounting portion 330 is formed around the upper surface of the ring mounting portion 330. The ring mounting portion 330 has a lower height than the center of the upper surface, A transparent upper acrylic plate 300 having a bonding preventing groove 331 formed on a plane where the chip mounting groove 320 is located;
A ring-shaped reflection plate 400 adhered and fixed to the upper acrylic plate 300 through an adhesive to the ring seating portion 330 excluding the adhesion preventing groove 331;
A plurality of through holes 810 are formed in the bottom surface of the solar unit installation groove 120 and a moisture stay groove 820 is formed at a bottom portion of the bottom 820 to be spaced apart from the bottom surface of the solar unit installation groove 120. A formed drainage material 800;
A solar panel 920 is installed on the upper surface of the case 910 and the solar panel 910 is installed inside the case 910. The solar panel 920 is installed in the solar panel installation groove 120, A first power line 930 protrudes from the case 910 to the outside of the case 910 while one side of the case 910 is connected to the bottom of the case 910, A solar unit 900 continuously inserted into the inclined grooves 140 and the vertical grooves 130;
An LED chip 1000 installed in the chip mounting groove 320 and connected to a second power line 1010 connected to the first power line 930 to receive power from the solar unit 900, ; ≪ / RTI >
Safety Induced Photovoltaic Boundary.

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