KR102526585B1 - Delineator - Google Patents

Abstract

The present invention relates to a delineator and, in particular, to a delineator, which can further brighten light emitted from the delineator and thus enhance visibility. The delineator of the present invention comprises: a main body which has one surface formed forward and the other surface formed backward; a plurality of first LEDs which are disposed along a rim of the main body on the one surface thereof; a permeable lens unit which covers all of the plurality of first LEDs and in which a plurality of concentric protrusions are continuously formed around each first LED on a rear surface facing the first LEDs, and a through-hole is formed in the center; and a reflection lens unit which is disposed in the through-hole to reflect light incident from the outside front. The light emitted from the first LEDs is refracted by the protrusions of the permeable lens unit and thus is emitted in parallel toward the front.

Description

delineator { DELINEATOR }

The present invention relates to a delineator, and more particularly, to a delineator capable of increasing visibility by making light emitted from the delineator brighter.

In general, delineators installed around the road are used to promote safe driving of drivers by diffusely reflecting light incident from the front of the vehicle and projecting it to the outside.

However, the conventional delineator has a very simple structure and only has an indirect reflection function that simply diffusely reflects the light incident from the vehicle headlight from the front and projects it to the outside. I had a lot of problems with this falling off.

In order to solve this problem, recently, a lighting device such as an LED is mounted on the delineator together with an existing reflector to increase the visibility of the delineator even in fog or rain.

However, since the conventional delineator simply reflects light emitted from the LED forward, there is a limit to increasing the visibility of the delineator.

Patent Publication 10-2011-0080565 Patent Publication 10-2014-0029572

The present invention is to solve the above problems, and an object of the present invention is to provide a delineator capable of increasing visibility by sending light emitted from an LED mounted on the delineator farther and making it brighter.

In order to achieve the above object, the delineator of the present invention includes a main body having one surface formed in the front and the other surface formed in the rear; a plurality of first LEDs disposed along the circumference of one surface of the main body; a transmission lens part covering all of the plurality of first LEDs and continuously forming a plurality of protrusions in the shape of concentric circles centered on each of the first LEDs on a rear surface facing the first LEDs, and having a through hole formed in the center thereof; A reflective lens unit disposed in the through hole to reflect light incident from the outside front, wherein the light emitted from the first LED is refracted by the projections of the transmission lens unit and irradiated in parallel toward the front characterized by

A reflective member disposed around the first LED to reflect light emitted from the first LED to the transmission lens unit, wherein the light emitted from the first LED is transmitted to the projections of the transmission lens unit. While being refracted and irradiated forward, a relatively bright section and a dark section are formed, and the reflective member reflects the light emitted from the first LED to a part forming the dark section among the rear surfaces of the transmission lens unit.

The reflective member is inclined downward toward the center of the first LED.

A plurality of third reflective protrusions having a concentric circle shape centered on the first LED are continuously formed on the reflective member, and the third reflective protrusion forms a concentric circle with the protrusion of the transmission lens unit, and the light emitted from the first LED Light is reflected by the third reflecting protrusion and is irradiated to a portion forming the dark section among the rear surfaces of the transmission lens unit.

The reflective member is disposed between a plurality of first LEDs that are spaced apart from each other, and both sides of the reflective member are inclined downward in opposite directions to each other.

A coupling protrusion protrudes from the center of the rear surface of the reflective member, the coupling protrusion protrudes more toward the rear surface than both sides of the reflective member, and the coupling protrusion penetrates the main body and is detachably coupled to the main body.

A second LED disposed in the center of one surface of the main body; further comprising a first reflector for retroreflecting light incident from the outside front while being disposed around the reflective lens unit; a transflective second reflector disposed at the center of the reflective lens unit to cover and face the second LED, transmit light emitted from the second LED toward the outside while partially reflecting light incident from the outside front; made up of

A plurality of first reflecting protrusions having sharp ends protrude continuously from the rear surface of the first reflecting part, and second reflecting protrusions formed by flatly cutting the pointed ends of the first reflecting protrusions from the rear surface of the second reflecting part. Protrusions are continuously formed, but the second reflecting protrusions, the ends of which are cut flat, transmit the light emitted from the second LED forward.

According to the delineator of the present invention as described above, the following effects are obtained.

According to the present invention, the light emitted from the first LED can be sent farther and brighter by the protrusion formed in the transmission lens unit, thereby increasing visibility.

In addition, the present invention actively radiates light forward through the first LED and the second LED while reflecting light incident from the outside forward, even in weather and environments (fog, rainy weather, etc.) in which reflection efficiency is reduced. You can make the driver have a better view of the delineator.

In particular, since the first LED radiates light around the reflective lens unit and the second LED radiates light at the center of the reflective lens unit, the driver can better check the position and shape of the delineator. , The first reflector of the reflection lens part retroreflects, and the second reflector can allow the light emitted from the second LED to be smoothly emitted forward through partial reflection and partial transmission, thereby further improving visibility.

In addition, by brightening the dark section formed by the forwardly irradiated light after being refracted by the transmission lens unit, the brightness of the light forwardly irradiated through the transmission lens unit is changed to a bright state regardless of position. It can be made more uniform, and a dark section can be brightened, so that the visibility of the delineator can be improved.

1 is a perspective view of a delineator according to an embodiment of the present invention;
2 is a one-way exploded perspective view of a delineator according to an embodiment of the present invention;
3 is an exploded perspective view of a delineator in another direction according to an embodiment of the present invention;
4 is a perspective view of a state in which a transmission lens unit and a reflection lens unit are removed from a delineator according to an embodiment of the present invention;
5 is a rear view showing a rear surface of a transmission lens unit according to an embodiment of the present invention;
6 is a cross-sectional perspective view of a reflective lens unit according to an embodiment of the present invention;
7 shows a relationship between a second LED and a second reflector of a delineator according to an embodiment of the present invention;
Figure 8 is a side cross-sectional view taken along line AA of Figure 1;
9 is a cross-sectional view illustrating shading of light by a reflection member of a delineator according to an embodiment of the present invention.
10 is a photograph of the brightness of light when there is no reflective member and when the reflective member is mounted according to an embodiment of the present invention.

As shown in FIGS. 1 to 6, the delineator of the present invention includes a main body 10, a first LED 21, a second LED 22, a transmission lens unit 30, and a reflective lens. A portion 40 and a reflective member 50 are included.

The main body 10 has one surface formed in the front and the other surface formed in the rear.

A circuit board and a battery are disposed inside the main body 10, and a bracket is mounted on the rear surface of the main body 10 so that the main body 10 can be coupled to the outside.

In addition, a reflector is formed on one surface of the main body 10 so that the light emitted from the first LED 21 and the second LED 22 is reflected forward, as will be described later, and light incident from the outside is reflected. It also serves as a reflector.

In addition, as shown in FIGS. 2 and 4, a circular first mounting groove 11 is formed along the circumference on one surface of the main body 10, and a second mounting groove 12 is formed in the center of one surface. this is formed

The first LEDs 21 are formed in plurality and are spaced apart from each other along the circumference on one surface of the main body 10 .

More specifically, as shown in FIG. 4 , the first LED 21 is mounted in the first mounting groove 11 formed in a circular shape on one surface of the main body 10 .

The second LED 22 is disposed in the center of one surface of the main body 10 .

More specifically, as shown in FIG. 4 , the second LED 22 is mounted in the second mounting groove 12 formed in the center of one surface of the main body 10 .

The first LED 21 and the second LED 22 are connected to a substrate embedded in the main body 10 .

The light emitted from the first LED 21 and the second LED 22 is irradiated forward, and some of the light is reflected by a reflector formed on one surface of the main body 10 and then irradiated forward.

The transmission lens unit 30 and the reflection lens unit 40 cover one surface of the main body 10 .

The transmission lens unit 30 is coupled to one surface of the main body 10 while covering all of the plurality of first LEDs 21 .

A solar cell 31 is installed at the upper end of the transmission lens unit 30, and the solar cell 31 is connected to a built-in battery of the main body 10 to generate electricity from the solar cell 31. Allow the battery to be charged.

A through hole 32 penetrating the front and back is formed in the center of the transmission lens unit 30 .

In addition, on the rear surface of the transmission lens unit 30, that is, the surface facing the first LED 21, as shown in FIGS. 3 and 5, concentric circles centered on each first LED 21 are formed. A plurality of protrusions 33 are formed in succession.

Due to the protrusion 33, the transmission lens unit 30 can implement the same function as a Fresnel lens.

That is, the light emitted from the first LED 21 is refracted by the projection 33 of the transmission lens unit 30 and radiated forward in parallel, so that the light can be radiated farther in parallel to the driver. Even at a long distance, the delineator can be recognized through the light from the first LED 21 .

Since the first LED 21 is formed along the circumference of one surface of the main body 10, a plurality of protrusions 33 are disposed around the through hole 32 of the transmission lens unit 30, The first LED 21 is disposed at the center of the plurality of protrusions 33 formed in a concentric circle shape.

The reflective lens unit 40 is for reflecting light incident from an outside front, and covers a portion where the second LED 22 is mounted while being disposed in the through hole 32 .

As shown in FIGS. 3 and 6 , the reflection lens unit 40 includes a first reflection unit 41 and a second reflection unit 45 .

The first reflection part 41 is disposed around the reflection lens part 40 .

The first reflector 41 retroreflects light incident from an external front to the front.

The second reflector 45 is disposed at the center of the reflection lens unit 40 and faces the second LED 22 .

The second reflector 45 has a semi-transmissive property and structure, and as shown in FIG. 7, transmits the light emitted from the second LED 22 to the outside while partially reflecting light incident from the outside front. let it

As shown in FIGS. 6 and 7 , a plurality of first reflecting protrusions 42 having sharp ends are continuously protruded from the rear surface of the first reflecting part 41 .

As shown in FIGS. 6 and 7 , second reflecting protrusions 46 formed by flatly cutting the sharp end of the first reflecting protrusion 42 are continuously formed on the rear surface of the second reflecting portion 45. .

As shown in FIG. 7 , the second reflecting protrusion 46 , the end of which is cut flat, forwards the light emitted from the second LED 22 .

More specifically, among the light incident from the outside into the transmission lens unit 30, the light incident to the first reflector 41 is retroreflected by the first reflector 41 and reflected forward. The light incident to the second reflector 45 is reflected forward by a reflector disposed around the second LED 22 while being partially reflected and partially transmitted.

And, the light emitted from the second LED 22 is irradiated forward after passing through the second reflecting part 45 formed with the second reflecting protrusion 46 whose end is cut flat.

As described above, the present invention actively radiates light forward through the second LED 22 while reflecting light incident from the outside, so that the driver can drive to the deli even in weather and environments (fog, rainy weather, etc.) in which reflection efficiency is reduced. You can make the narrator more visible.

In particular, since the first LED 21 emits light around the reflective lens unit 40 and the second LED 22 emits light at the center of the reflective lens unit 40, the driver It is possible to better check the position and shape of the delineator, and the first reflecting part 41 of the reflection lens part 40 retroreflects and the second reflecting part 45 partially reflects and partially transmits the image. Since light emitted from the second LED 22 can be smoothly emitted forward, visibility can be further improved.

As shown in FIGS. 4 and 9 , the reflective member 50 is disposed around the first LED 21 to transmit light emitted from the first LED 21 to the transmission lens unit 30 . serves as a reflector.

The light emitted from the first LED 21 is refracted by the protrusion 33 of the transmission lens unit 30 and irradiated forward, forming a relatively bright section and a relatively dark section.

9 illustrates a difference in brightness, that is, a shade between a case in which there is no light by the reflective member 50 and a case in which light is added by the reflective member 50 according to the present invention.

When there is no additional light by the reflective member 50 because there is no reflective member 50, the light emitted from the first LED 21 and transmitted through the transmission lens unit 30 is a bright section and a dark section. The shading difference of is displayed large.

The reflection member 50 reflects the light emitted from the first LED 21 to a part forming the dark section among the rear surfaces of the transmission lens unit 30 .

For this reason, the dark section formed by the transmission lens unit 30, that is, the section where light is slightly irradiated forward, is further irradiated with light through the reflective member 50, thereby changing the dark section to a brighter one.

That is, as shown in FIG. 9, when light is added by the reflective member 50, the light emitted from the first LED 21 passes through the transmission lens unit 30 and is generated in a dark section. By adding light, it is possible to brighten a dark section and reduce a difference in shading between a bright section and a dark section.

In this embodiment, the reflective member 50 is inclined downward toward the center of the first LED 21 .

A plurality of third reflective protrusions 51 concentrically centered on the first LED 21 are continuously formed on the reflective member 50 .

At this time, the third reflective protrusion 51 forms the same concentric circle as the protrusion of the transmission lens unit 30 .

The light emitted from the first LED 21 is reflected by the third reflecting protrusion 51 and irradiated to the part forming the dark section among the rear surfaces of the transmission lens unit 30, so that the dark section becomes bright. Let it be.

The reflective member 50 is disposed between the plurality of first LEDs 21 spaced apart from each other, and both sides of the reflective member 50 are inclined downward in opposite directions to each other.

That is, both sides of the reflective member 50 are inclined downward in both directions in which the first LED 21 is disposed.

Accordingly, the light emitted from the adjacent first LEDs 21 is reflected through the reflective member 50 disposed therebetween and irradiated forward.

In addition, a coupling protrusion 52 protrudes from the center of the rear surface of the reflective member 50 .

The coupling protrusion 52 protrudes further toward the rear surface than both sides of the reflective member 50 .

The coupling protrusion 52 is detachably coupled to the body 10 while penetrating the body 10 .

10 shows pictures of the brightness of the delineator in a state in which the reflective member 50 of the present invention is not mounted and in a state in which the reflective member 50 is mounted.

In FIG. 10 , it can be confirmed that the brightness of the delineator is brighter as the dark section decreases in the structure in which the reflective member 50 is mounted.

By brightening the dark section formed by the light refracted by the transmission lens unit 30 and irradiated forward as described above by the additional light reflected by the reflection member 50, the transmission lens unit 30 Through this, the brightness of the light irradiated forward can be made more uniform in a bright state regardless of the position, and the visibility of the delineator can be improved by brightening the dark section.

The delineator of the present invention is not limited to the above-described embodiment, and can be variously modified and implemented within the scope permitted by the technical spirit of the present invention.

10: main body, 11: first mounting groove, 12: second mounting groove,
21: 1st LED, 22: 2nd LED,
30: transmission lens part, 31: solar cell, 32: through hole, 33: protrusion part,
40: reflective lens unit, 41: first reflective unit, 42: first reflective protrusion, 45: first reflective unit, 46: second reflective protrusion,
50: reflective member, 51: third reflective protrusion, 52: coupling protrusion,

Claims (8)

A main body having one surface formed in the front and the other surface formed in the rear;
a plurality of first LEDs disposed along the circumference of one surface of the main body;
a transmission lens part covering all of the plurality of first LEDs and continuously forming a plurality of protrusions in the shape of concentric circles centered on each of the first LEDs on a rear surface facing the first LEDs, and having a through hole formed in the center thereof;
a reflective lens unit disposed in the through hole to reflect light incident from an outside front;
A reflective member disposed around the first LED to reflect the light emitted from the first LED to the transmission lens unit;
The light emitted from the first LED is refracted by the projection of the transmission lens unit and irradiated in parallel toward the front to form a relatively bright section and a dark section,
The reflective member reflects the light emitted from the first LED to a portion forming the dark section among the rear surfaces of the transmission lens unit,
The reflective member is formed to be inclined downward toward the center of the first LED,
A plurality of third reflective protrusions having a concentric circle shape centered on the first LED are continuously formed on the reflective member,
The third reflection protrusion forms a concentric circle with the projection of the transmission lens unit,
The delineator, characterized in that the light emitted from the first LED is reflected by the third reflecting projection and irradiated to a portion forming the dark section among the rear surfaces of the transmission lens unit. delete delete delete In claim 1,
The reflective member is disposed between a plurality of mutually spaced first LEDs,
Both sides of the reflective member are inclined downward in opposite directions to each other. The method of claim 5,
Coupling protrusions are formed protruding from the center of the rear surface of the reflective member,
The coupling protrusion protrudes more toward the rear side than both sides of the reflective member,
The engaging protrusion is detachably coupled to the main body while penetrating the main body. In claim 1,
A second LED disposed in the center of one side of the main body; further comprising,
The reflective lens unit,
a first reflector that is disposed around the reflective lens unit and retroreflects light incident from the outside front;
a transflective second reflector disposed at the center of the reflective lens unit to cover and face the second LED, transmit light emitted from the second LED toward the outside while partially reflecting light incident from the outside front; Delineator characterized in that consisting of. The method of claim 7,
A plurality of first reflecting protrusions having a pointed end are continuously protruded from the rear surface of the first reflecting unit,
On the rear surface of the second reflecting part, second reflecting protrusions formed by flatly cutting the pointed ends of the first reflecting protrusions are continuously formed,
The second reflecting projection, the end of which is cut flat, transmits the light emitted from the second LED forward.

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