KR102006462B1 - Lighting apparatus for tunnel and lens unit thereof - Google Patents

Abstract

The present invention relates to a lighting device for a tunnel. According to the present invention, the lighting device for a tunnel which is installed in the tunnel comprises: a substrate formed of a metal material; a plurality of light source units installed on the substrate; and a lens unit fixed on the substrate, covering the light source unit, penetrating light emitted from the light source unit, and made of a transparent materials. The lens unit includes: a lens unit body formed of a transparent material; and a plurality of lens units of a convex shape individually corresponding to the plurality of light source units and formed in the lens unit body. Sizes of front and rear regions of a light radiation region which penetrates the lens unit and is formed by the light radiated to the inside of the tunnel are differently formed.

Description

LIGHTING APPARATUS FOR TUNNEL AND LENS UNIT THEREOF}

The present invention relates to a tunnel lighting apparatus, and relates to a tunnel lighting apparatus that can suppress the glare of the driver of the vehicle running in the tunnel.

Tunnel lighting devices are installed in tunnels such as highways, railways, and underground roadways to secure the driver's view.

Tunnel lighting devices generally have a light distribution type that spreads widely from side to side along a road length and narrowly to a road width, such as a bat-wing type.

1 is a view showing a tunnel in which a conventional tunnel lighting device is installed.

Referring to FIG. 1, in the general tunnel lighting device, the front area and the rear area of the light irradiation area A _L by the lighting device 900 are formed to have the same size. In addition, the irradiation angle θ ₂₂ (relative to the vertical reference line v perpendicular to the bottom surface) and the irradiation angle θ ₂₁ with respect to the rear region of the illuminating device 900 are also formed in substantially similar sizes. .

When the tunnel lighting device such as the batwing type is installed, the irradiation area is formed long in the front and rear direction of the driving direction of the vehicle 500, but there is an advantage of helping to secure a view in a dark environment, but the vehicle is When entering the tunnel, as the light is long irradiation in the direction of the vehicle (the rear region of the light irradiation area A _L ), it may cause discomfort such as glare to the driver. In addition, when the driver is suddenly exposed to the light of the tunnel lighting device, there is a problem that can cause a vehicle accident due to glare.

Korean Patent Registration No. 10-1119125 (Name of invention: Formation method of tunnel lighting fixture and tunnel lighting fixture)

Embodiment of the present invention, to solve the above problems, to propose a tunnel lighting device and a lens unit thereof that can suppress the glare of the driver.

Tunnel lighting device according to an embodiment of the present invention, the tunnel lighting device installed in the tunnel, the substrate formed of a metal material; A plurality of light source units provided on the substrate; And a lens unit fixed to the substrate, covering the light source unit, transmitting light emitted from the light source unit, and formed of a transparent material, wherein the lens unit includes: a lens unit body formed of a transparent material; A size of the front region of the light irradiation area corresponding to the light source unit of the plurality of lens units formed on the lens unit body, the lens unit having a convex shape, and formed by light transmitted through the lens unit and irradiated into the tunnel; The size of the posterior region is formed differently.

The lens unit may be disposed above the light source unit corresponding to the lens unit and protrude convexly in the opposite direction of the light source unit, and the lens unit may face the rear region with respect to the center line of the lens unit. A first area may include a second area facing the front area with respect to the center line of the lens unit, and the average thickness of the first area may be greater than the average thickness of the second area.

The thickness reduction width of the first region from the first region of the lens unit to the first point, which is a first distance from the center line of the lens unit, may be defined by the center line of the lens unit in the second region of the lens unit. The first area up to a third point smaller than the thickness reduction width of the second area to a second point, which is a second distance having the same size as the first distance, and spaced apart from the first point by a third distance. The thickness reduction width of is greater than the thickness reduction width of the second area from the second point to a fourth point spaced apart by a fourth distance equal to the third distance, wherein the first distance and the second distance are the third distance. And a thickness greater than the fourth distance, wherein thicknesses of the first region and the second region at the edges of the first region and the second region may be the same.

In addition, an irradiation angle of light passing through the first area based on a vertical reference line perpendicular to the bottom surface may be smaller than an irradiation angle of light passing through the second area.

In addition, a lower surface of the lens unit may include a receiving groove recessed toward the first region and the second region of the lens unit so that the light source unit may be accommodated, and an inner surface of the receiving groove may be rounded. Can be.

In addition, the size of the front region of the light irradiation area formed by the light transmitted through the lens unit and irradiated into the tunnel is larger than the size of the rear area of the light irradiation area, and the vehicle passes through the tunnel. The direction may be parallel to the direction from the rear region toward the front region.

The light amount of the front region of the light irradiation region may be greater than the light amount of the rear region of the light irradiation region.

In addition, an irradiation angle of the boundary surface of the front region of the light irradiation region may be greater than an irradiation angle of the boundary surface of the rear region with respect to the vertical reference line perpendicular to the bottom surface.

According to another aspect of an embodiment of the present invention, a lens unit of a lighting device for a tunnel includes a lens unit body formed of a transparent material, and a plurality of lenses respectively formed in the lens unit body and corresponding to the plurality of light source units. And a lens unit, wherein the lens unit is formed to protrude convexly in the opposite direction of the light source unit, and the lens unit includes a first region facing the rear region with respect to the center line of the lens unit and the front with respect to the center line of the lens unit. And a second region facing the region, wherein the average thickness of the first region is greater than the average thickness of the second region.

The lens unit may be disposed above the light source unit corresponding to the lens unit and protrude convexly in the opposite direction of the light source unit, and the lens unit may face the rear region with respect to the center line of the lens unit. A first region and a second region facing the front region with respect to the center line of the lens unit, wherein the average thickness of the first region is greater than the average thickness of the second region, and the first region of the lens unit The thickness reduction width of the first area to a first point that is a first distance with respect to the center line of the lens unit is equal to the first distance in the second area of the lens unit with respect to the center line of the lens unit. The first distance to a third point that is less than the thickness reduction width of the second area to a second point that is a second distance of and spaced apart from the first point by a third distance; Inverse thickness reduction is greater than a thickness reduction of the second region from the second point to a fourth point spaced apart by a fourth distance equal to the third distance, wherein the first distance and the second distance are the third distance. The first region and the second region may have a thickness greater than a distance and a fourth distance, and the thicknesses of the first region and the second region may be equal to each other.

According to the proposed embodiment, there is an advantage of suppressing glare of the driver and securing a wide field of view inside the tunnel.

1 is a view showing a tunnel in which a conventional tunnel lighting device is installed.
2 is a view showing a tunnel in which the lighting device for a tunnel according to an embodiment of the present invention is installed.
3 and 4 are views illustrating a lens unit of the lighting device for a tunnel of FIG. 1.
5 is a view showing a cross section of the lighting device for a tunnel of FIG.
FIG. 6 is a view illustrating an irradiation area by light emitted from the tunnel lighting apparatus of FIG. 1.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, only the present embodiments to make the disclosure of the present invention complete, and common knowledge in the art to which the present invention pertains. It is provided to fully inform the person having the scope of the invention, which is defined only by the scope of the claims.

Although the first, second, etc. are used to describe various components, these components are of course not limited by these terms. These terms are only used to distinguish one component from another. Therefore, of course, the first component mentioned below may be the second component within the technical spirit of the present invention.

Like reference numerals refer to like elements throughout.

Each of the features of the various embodiments of the present invention may be combined or combined with each other in part or in whole, various technically interlocking and driving as can be understood by those skilled in the art, each of the embodiments may be implemented independently of each other It may be possible to carry out together in an association.

On the other hand, the interim effects that can be expected by the technical features of the present invention that are not specifically mentioned in the specification of the present invention are treated as described herein, the present embodiment to those skilled in the art It is provided to explain the invention more completely, the contents shown in the drawings may be exaggerated than the actual appearance of the invention, the detailed description of the configuration that is determined to unnecessarily obscure the subject matter of the present invention Omit or briefly describe it.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

2 is a view showing a tunnel in which the lighting device for a tunnel according to an embodiment of the present invention is installed.

2, the tunnel lighting device 1 according to the embodiment of the present invention is installed in the tunnel T, and the driver 500 in the process of driving the vehicle 500 inside the tunnel T. Provides light for visibility.

The light irradiation area A _L formed by the light irradiated from the tunnel lighting device 1 includes a rear area A _L1 and a front area A _L2 , and includes a rear area A _L1 and a front area ( A _L2 ) is formed differently. The traveling direction of the vehicle 500 is formed in a direction from the rear region A _L1 toward the front region A _L2 , and preferably, the size of the front region A _L2 is larger than the size of the rear region A _L1 . do. Further, the irradiation angle θ ₁₂ of the boundary surface B _L2 of the front region A _L2 of the light irradiation area A _L with respect to the vertical reference line v perpendicular to the bottom surface is a light irradiation area ( It is formed larger than the irradiation angle θ ₁₁ of the boundary surface B _L1 of the rear region A _L1 of A _L ). That is, one lighting device 1 irradiates light toward the front area A _L2 for a long time, and irradiates light relatively short to the rear area A _L1 .

The rear region A _L1 facing the direction in which the vehicle 500 enters is formed to have a relatively small irradiation angle θ ₁₁ , so that the size of directly irradiating light directly onto the driver's eyes of the vehicle 500 is reduced. do. In addition, the front region A _L2 formed long in the direction in which the vehicle 500 travels allows light to be irradiated over a wide range irrespective of the vehicle driver's field of view so that the driver's field of view can be smoothly secured in a dark environment. do.

Hereinafter, the configuration of the lighting device for tunnel 1 according to the present embodiment will be described in detail.

3 and 4 are views illustrating a lens unit of the tunnel lighting apparatus of FIG. 1, and FIG. 5 is a cross-sectional view of the tunnel lighting apparatus of FIG. 1.

3 to 5, the tunnel lighting apparatus 1 according to the present embodiment includes a substrate 300 formed of a metal material, a plurality of light source units 200 installed on the substrate 300, and The lens unit 100 is fixed to the substrate 300, covers the light source unit 200, transmits light emitted from the light source unit 200, and is formed of a transparent material.

The substrate 300 may be, for example, a PCB substrate formed of a metal material such as metal or aluminum, and rapidly illuminates heat generated from the plurality of light source units 200 installed in the substrate 300. It can diverge outside of (1).

The light source unit 200 may include a light emitting surface 210 that emits light and may be, for example, a light emitting diode (LED) module. In the present embodiment, the light source unit 200 may be described as an LED by way of example, but is not limited to an incandescent lamp, a halogen lamp, a fluorescent lamp, an organic light emitting diode, and an OLED. It may be formed of various light sources for emitting light.

The lens unit 100 corresponds to a lens unit body 110 formed of a plate-like transparent material, and corresponds to a plurality of light source units 200, respectively, and is formed on the lens unit body 110 and includes a plurality of lens portions having convex shapes ( 120 and a ridge 130 formed between the lens units 120.

The lens unit body 110 may be formed of a transparent material, and for example, may be formed of polycarbonate. In the present embodiment, the lens unit body 110 is described as an example of a configuration formed of polycarbonate, but may be formed of a material having various transparency such as glass and polypropylene.

In the lens unit body 110, a plurality of through holes 111 through which the fastening member for connecting to the substrate 300 passes may be formed along the edge of the lens unit body 110.

The lens unit 120 is disposed above the light source unit 200 corresponding to the lens unit 120 and protrudes convexly from the lens unit body 110 in a direction opposite to the light source unit 200.

The lens unit 120 includes a first region 121 facing the rear region A _L1 of the light irradiation area A _L based on the center line C of the lens unit 120, and a center line C of the lens unit 120. The second region 122 facing the front region A _{L2 is} referred to. The average thickness of the first region 121 is greater than the average thickness of the second region 122. That is, the first region 121 is formed to be thicker than the second region 122 as a whole, so that the light transmitted through the first region 121 is more linear than the light transmitted through the second region 122.

In more detail, in the first region 121 of the lens unit 120, the first region from the center line C of the lens unit 120 to the first point P ₁ , which is the first distance d ₁ . The thickness reduction width of the 121 may be equal to the first distance d ₁ in the second region 122 of the lens unit 120 with respect to the center line C of the lens unit 120. It is formed smaller than the thickness reduction width of the second region 122 to the second point (P ₂ ) which is d ₂ ).

In addition, the thickness reduction width of the first region 122 from the first point P ₁ to the third point P ₃ spaced apart by the third distance d ₃ is the third from the second point P ₂ . The thickness of the second region 122 to the fourth point P ₄ spaced apart by the fourth distance d ₄ equal to the distance d ₃ is greater than the thickness reduction width.

That is, the thickness of the first region 121 of the lens unit 120 decreases from the centerline C to the edge side of the first region 121 to a level smaller than the thickness of the second region 122. After the predetermined point (fourth point P ₄ ), the reduction is greater than the reduction in thickness of the second region 122. The thickness of the edge portion of the first region 121 is formed to be substantially the same size as the thickness of the edge portion of the second region 122.

The first distance d ₁ and the second distance d ₂ are greater than the third distance d ₃ and the fourth distance d ₄ . That is, the size of the section in which the thickness of the first region 121 decreases and the size of the section in which the thickness of the second region 121 decreases is small, and the size of the thickness of the first region 121 decreases in the second region. Since the thickness of the 121 is larger than the size of the section larger than the size of the decrease, the average thickness of the first region 121 is greater than the average thickness of the second region 122.

On the other hand, the lower surface of the lens unit 120, the receiving groove which is recessed toward the first region 121 and the second region 122 of the lens unit 120, so that one light source unit 200 can be accommodated. 125 is formed, the inner surface of the receiving groove 125 may be formed round. The inner surface of the receiving groove 125 may be formed in a symmetrical shape with respect to the center line (C).

The protruding portion 130 is formed between the lens portions 120 protruding from the lens unit body 110 and is protruded to a lower height than the lens portion 120. The ridge 130 may disperse the stress or other external force due to the heat applied to the lens unit 120 protruding from the lens unit body 110, thereby preventing the lens unit 120 from being damaged. A part of the lens unit body 110 overlaps each other at the edge of the ridge 130.

In the tunnel lighting device 1 according to the present embodiment, the irradiation angle θ ₁₁ of the light L ₁ passing through the first region 121 with respect to the vertical reference line v perpendicular to the floor surface. Is smaller than the irradiation angle θ ₁₂ of the light passing through the second region 122. That is, since the thickness of the first region 121 is formed relatively thicker than the second region 122 and the transmission surface is formed relatively flat, the light L ₁ transmitted through the first region 121 may be formed. More vertical components are obtained than light L ₂ transmitted through the two regions 122. Light L ₁ passing through the first region 121 is irradiated toward the rear region A _L1 of the light irradiation region A _L , and light L ₂ passing through the second region 122 is irradiated with the light. Irradiated to the front region A _L2 side of the region A _L.

FIG. 6 is a view illustrating an irradiation area by light emitted from the tunnel lighting apparatus of FIG. 1.

Referring to FIG. 6, the light irradiation area A _L of the tunnel lighting device 1 according to the present embodiment includes a rear area A _L1 , a front area A _L2 , and an intermediate area A _L3 . .

As described above, the size of the front region A _L2 is larger than that of the rear region A _L1 , thereby suppressing glare of the driver and securing a wide field of view inside the tunnel. The light amount in the front region A _L2 is larger than the light amount in the rear region A _L1 . An intermediate region A _L3 is formed between the front region A _L2 and the rear region A _L1 , ie, in the downward direction perpendicular to the lighting device 1, and the amount of light in the intermediate region A _L3 is the front region A. _L2 ) and smaller than the rear region A _L1 .

According to the tunnel lighting apparatus according to the proposed embodiment, there is an advantage to suppress the glare of the driver, and to secure a wide field of view inside the tunnel.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the range of.

Claims (11)

In the tunnel lighting device installed in the tunnel,
A substrate formed of a metal material;
A plurality of light source units provided on the substrate;
And a lens unit fixed to the substrate, covering the light source unit, transmitting the light emitted from the light source unit, and formed of a transparent material.
The lens unit includes a lens unit body formed of a transparent material, and a plurality of lens units corresponding to the plurality of light source units and formed on the lens unit body, and having a convex shape.
The lens unit,
It is disposed above the light source unit corresponding to the lens unit, is formed convexly projected in the opposite direction of the light source unit
A first region facing the rear region based on the center line of the lens unit and a second region facing the front region based on the center line of the lens unit, wherein an average thickness of the first region is greater than an average thickness of the second region. Formed,
In the first region of the lens unit, a thickness reduction width of the first region from the center region of the lens unit to a first point that is a first distance is based on the center line of the lens unit in the second region of the lens unit. Less than a thickness reduction width of the second area to a second point that is a second distance of the same size as the first distance,
The thickness reduction width of the first area from the first point to a third point spaced apart by a third distance is equal to the second point from the second point to a fourth point spaced apart by a fourth distance equal to the third distance. Greater than the thickness reduction of the area,
The first distance and the second distance are greater than the third distance and the fourth distance, and the thicknesses of the first area and the second area at the edges of the first area and the second area are the same. ,
It includes a ridge formed between the lens portion protruding from the lens unit body,
The thickness of the raised portion is formed to be raised to a height higher than the substrate, the illumination device for a tunnel, characterized in that formed by being raised to a lower height than the lens portion. delete delete According to claim 1,
And an irradiation angle of light passing through the first area based on a vertical reference line perpendicular to the bottom surface is smaller than an irradiation angle of light passing through the second area. According to claim 1,
A lower surface of the lens unit may include a receiving groove recessed toward the first region and the second region of the lens unit so that the light source unit can be accommodated, and an inner surface of the receiving groove is rounded. Lighting device for tunnel. According to claim 1,
The size of the front region of the light irradiation area formed by the light transmitted through the lens unit and irradiated into the tunnel is greater than the size of the rear area of the light irradiation area,
And a direction in which the vehicle passes in the tunnel is parallel to a direction from the rear region toward the front region. The method of claim 6,
And a light amount of the front area of the light irradiation area is greater than a light amount of the rear area of the light irradiation area. The method of claim 6,
And an irradiation angle of the boundary surface of the front region of the light irradiation region is greater than an irradiation angle of the boundary surface of the rear region with respect to the vertical reference line perpendicular to the bottom surface. delete delete The method of claim 1,
The ridge is,
A part of the lens unit body, respectively, the tunnel illumination device, characterized in that arranged on the rim of the ridge

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