KR20040046635A - A road mounting indicating light - Google Patents

Abstract

PURPOSE: A road stud buried under the road is provided to heighten the utility of a road stud using a solar battery. CONSTITUTION: The road stud buried under the road contains: a post unit(100) provided with a post buried under the road; a body unit(200) attached to the upper part of the post unit(100) and provided with an LED inward and a solar battery(201) upward; and a lens interposed between the post(100) and the body(200) and provided with an LED downward. A portion of the surface of the lens is exposed outward.

Description

A road mounting indicating light

The present invention relates to a road retractable beacon, and more particularly, to be embedded on the road surface of the road to be lit or flashing to easily identify the location of the lane, or to a road refillable beacon for transmitting various information will be.

Markers are installed to mark lanes such as the center line of roads, or to be easily identified at night, such as boundary seats. These markers generally use a reflector to reflect when the headlights of the car are illuminated. Markers of the type used to make this possible are used.

These cover bottles are composed of struts that are embedded in the road and a body part that is exposed on the road surface to reflect light. It is a part to be able to be, the body portion is to be reflected on the road surface by installing a reflecting plate on the part.

This type of cover bottle has been widely used because it is easy to manufacture and has a low cost, but there are many problems in visibility because it does not shine itself. That is, since only the cover bottles within the range in which the headlights of the automobile are irradiated can be identified, there is a problem in that they cannot be identified when they are located in a distant place or when the headlights are broken, thereby failing to function properly.

Therefore, in recent years, cover bottles of a type that can emit light by incorporating LEDs have been developed. This type of cover bottles need to be separately buried for supplying power, which makes construction difficult and maintenance difficult. There is a problem that is difficult to use practical.

In recent years, LED marker bottles have been developed to improve this and require no external power supply. That is, as a flashing LED using a solar cell, referring to Figure 1, the cover bottle is equipped with a disk-shaped body portion on the upper portion of the support portion, the four LEDs in the disk-shaped body portion at equal intervals It is installed, and the transparent window is installed between the body portion and the holding portion so that the light generated from the LED is irradiated to the outside through the transparent window.

The label bottle is to install a solar cell on the top of the body portion without using a separate external power source so that the LED blinks using the power generated by the solar cell. Therefore, there is no need to connect a power line or the like to each cover bottle, so that the construction is easy and the post-management also has an advantage.

However, since the power generation efficiency of the solar cell is low, when the solar light is not received for a long time, there is a fear that the power may not be sufficient to perform a function. In fact, if the sun does not receive about a day or so, the label bottle stops working because it runs out of power, which is very fatal considering the role of the label bottle.

The present invention has been made to overcome the drawbacks of the prior art as described above, using a solar cell does not require a separate external power supply, and minimizes the power consumption of the cover bottle to operate even without receiving sunlight for a considerable period of time. The technical challenge is to provide a retractable beacon that does not stop.

1 is a perspective view showing a conventional road sign bottle using the LED.

Figure 2 is a perspective view showing an embodiment of a road-filled cover bottle according to the present invention.

3 is a perspective view of a lens of the embodiment illustrated in FIG. 2.

4 is a cross-sectional view taken along line AA ′ of FIG. 2.

FIG. 5 is a cross-sectional view taken along line BB ′ in FIG. 2.

In order to achieve the above technical problem, the present invention, the holding portion having a support embedded in the road; In the road-filled label bottle is mounted on top of the support portion, the LED is mounted therein, the upper portion includes a body portion to which the solar cell is mounted, the lens is interposed between the support portion and the body portion, LED is mounted on the lower portion, characterized in that some of the surface of the lens is exposed to the outside.

That is, the present invention uses the lens instead of the conventional transparent window, so that the same visibility can be maintained even when using a smaller number of LEDs than the prior art. Through this, the power generated from the solar cell located above the body part is stored in a conventional storage battery and then used to flash the LED. The support portion is embedded in the road as in the conventional cover bottle and the body portion is exposed to the road surface. At this time, the lens is located between the body portion and the holding portion is configured to expose at least a portion of the lens to the outside so that the light emitted from the LED can go out through the lens.

Preferably, the edge portion of the lens is preferably exposed, but is not necessarily limited thereto. In addition, the lens is empty inside, it is preferable that a reflecting plate is attached to the portion of the surface except the exposed portion and the LED insertion portion. That is, the light irradiated from the LED insertion unit is reflected by the reflecting plates installed on the upper and lower surfaces of the inner space of the lens, but is irradiated to the outside only through the external exposure unit where the reflecting plate is not installed, thereby further increasing the efficiency. This allows light emitted from the LED to be irradiated to the outside with little loss.

Preferably, a cylindrical groove is formed in the upper portion of the lens, and the upper portion of the body portion on which the solar cell is mounted is accommodated in the cylindrical groove so that the surface of the lens and the surface of the body portion are smoothly connected to each other. Due to this configuration, it is possible to extend the life of the cover bottle by smoothly passing without the collision occurs when the tire of the car crosses the cover bottle, it is possible to reduce the extent that the cover bottle penetrates the road by the collision.

Preferably, the body portion and the edge portion in contact with the outer peripheral portion of the lens; A solar cell accommodating part disposed on the edge part and accommodating the solar cell; It is preferable that the edge portion and the solar cell accommodating portion are formed of one or more pairs of reinforcing ribs. The lens is positioned between the edge portion and the solar cell accommodating portion.

The reinforcing ribs serve to fix the solar cell accommodating portion to the edge portion and to prevent the body portion from being damaged when pressed by the tire of the vehicle. The body portion and the support portion is to be detachably coupled to the border portion in contact with each other, it is preferable to replace only the body portion, not the entire cover bottle when the body portion is broken. For example, fixing the body portion and the support portion with bolts can simply replace the body portion.

In addition, the reinforcing ribs are spaced apart from each other at equal intervals so as to uniformly distribute the load of the vehicle, the lower side of the reinforcing ribs are configured to support the load of the vehicle so as to support the load of the vehicle It is good.

Hereinafter, with reference to the accompanying drawings will be described in more detail with respect to an embodiment of a buried road sign bottle according to the present invention.

Referring to FIG. 2, the embodiment is composed of a support 100 and a body 200, and a lens 300 interposed between the support 100 and the body 200. The pillar portion 100 has a cylindrical pillar 102 for insertion into the road, and has an extension 104 having a diameter larger than that of the pillar 102. A printed circuit board (not shown) including a storage battery for temporarily storing power generated by the solar cell 201 to be described later is installed inside the support part.

Body portion 200 is located on the upper portion of the support portion (100). The body portion 200 has a solar cell accommodating portion 202 located at the top, an edge portion 204 located at the bottom, and four reinforcing ribs connecting the solar cell accommodating portion 202 and the edge portion 204. 206, the edge 204 is coupled with four bolts in contact with the extension 104. The solar cell accommodating part 202 has a space for accommodating the solar cell 201, where the solar cell 201 is accommodated.

Referring to FIG. 3, the lens 200 is a hollow transparent body, and a space 302 in which the solar cell accommodating part 202 is inserted is formed at an upper portion of the lens 200, and the LED is located at a portion adjacent to the space 302. Irradiation unit 304 through which the light is transmitted is located. In addition, the irradiation section 304 is formed with four grooves 306 at intervals of 90 °, the reinforcing rib 206 described above is inserted. The lower part of the lens has a seating portion which is in contact with the support portion 100, the hole 308 for inserting the LED is drilled in the center of the seating portion.

The bottom of the space 302 into which the accommodation portion 202 is inserted and the seating portion are coated with a material that reflects light. As a result, the light irradiated from the LED is not absorbed and can be emitted to the outside through the irradiation unit 304. Instead of coating, an embodiment in which a reflector is fitted may also be considered.

4 and 5, the coupling state between the body part 200, the lens 300, and the support part 100 is shown in more detail. 4 is a cross-sectional view including the reinforcing rib 206, and it can be seen that the lower portion of the reinforcing rib 206 is seated on the upper portion of the support 100. Therefore, when the load of the vehicle is applied to the body portion 200, the solar cell accommodating portion 202 located above the body portion 200 is firmly supported without sitting down. In addition, between the two reinforcing ribs 206, a solar cell accommodating part 202, which accommodates a solar cell, is positioned in the upper part, and a part of the seating part of the lens is inserted into a space under the reinforcing part. Since the surface of the solar cell 201 is located inside the solar cell accommodating part 202 as shown, and does not receive a direct load of the vehicle, there is no fear of damage.

FIG. 6 is a cross-sectional view of the reinforcing rib 206 not included, and the irradiating portion 304 of the lens is positioned between the edge portion 204 of the body portion 200 and the solar cell accommodating portion 202. The solar cell accommodating part 202 is inserted into the space 302 above the lens. In addition, a hole 308 through which the LED can be inserted is formed in the lower part of the lens, and the remaining part except the irradiation part and the lens insert part is coated with a material that reflects light, so the light generated from the LED is located at the upper part and the lower part. It is reflected by the reflector and all are emitted to the irradiation part without loss. In the case of the above embodiment, the same visibility can be maintained even when the LED used has less power consumption than the conventional LED, that is, a dark LED.

According to the present invention having the above-described configuration, the same visibility can be maintained even when using a smaller number of LEDs than in the prior art. Therefore, when the solar light is not received for a long time, that is, even in rainy season, it can maintain the operation without any abnormality, thereby providing an effect of increasing the utility of the road marker bottle using solar cells.

Claims (7)

A support portion having a support embedded in the road; In the road-filled cover bottle is mounted on the top of the holding portion, the LED is mounted therein, the upper portion includes a body portion to which the solar cell is mounted, The lens is interposed between the support portion and the body portion, the LED is mounted on the lower portion of the lens, and part of the surface of the lens, the road-filled marker bottle, characterized in that exposed to the outside. The method of claim 1, The lens is empty inside, the road-filled marker bottle, characterized in that the reflection plate is attached to the portion of the surface except the exposed portion and the LED insert. The method of claim 2, And a cylindrical groove formed in the upper portion of the lens, and an upper portion of the body portion on which the solar cell is mounted is accommodated in the cylindrical groove so that the surface of the lens and the surface of the body portion are smoothly connected to each other. The method of claim 1, The body portion and the edge portion in contact with the outer peripheral portion of the lens; A solar cell accommodating part disposed on the edge part and accommodating the solar cell; Road-filled cover bottle, characterized in that consisting of one or more pairs of reinforcing ribs connecting the edge portion and the solar cell receiving portion. The method of claim 4, wherein The body portion and the holding portion is a road-filled marker bottle, characterized in that detachable coupling in a state in contact with each other. The method of claim 5, The body part and the holding portion is retractable road sign, characterized in that the bolt is detachably coupled. The method of claim 4, wherein The reinforcement ribs are spaced apart from each other at equal intervals, and the bottom surface of the reinforcement ribs, characterized in that the contact with the upper surface of the support portion.