KR101230660B1 - Light Distribution Apparatus of LED Roadway Lighting Luminaire - Google Patents

Abstract

Light distribution control device of the LED road lighting fixture of the present invention is a light source module including a plurality of LED light source, coupled to the light source module, the segment A having one slope and facing the segment A and bound the bending point A reflection shade consisting of a segment B and a segment C divided into a plurality of light sources, a first light source including a plurality of light source module and a plurality of first lighting unit to control the longitudinal light distribution of the road including the reflector, and a plurality of light source module It includes a plurality of second light source to control the light distribution in the width direction of the road including a plurality of second light source and the reflection shade provided.
Accordingly, the present invention improves the efficiency of the road lighting fixtures, ensures the roughness and uniformity of the road surface, provides a light distribution control device for LED lighting fixtures that can increase the lighting rate by controlling the light going back, the developed light distribution It is possible to provide a fastening method of the control device easily and to minimize glare to the driver.

Description

 Light Distribution Apparatus of LED Road Lighting Mechanism {Light Distribution Apparatus of LED Roadway Lighting Luminaire}

The present invention relates to an apparatus for controlling the light distribution of a lighting device that illuminates a road using LEDs.

LED is a long-life, high-efficiency, eco-friendly lighting means compared to the conventional light source, LED road lighting fixtures are actively being developed as the LED light efficiency is recently improved.

However, due to the straightness in emitting light from the LED, there was a problem in terms of optical performance and light quality in order to replace a street lamp fixture using a conventional HID lamp in road lighting.

In order to solve this problem, the reflection shade is used to condense the light emitted from the LED toward the road.

In this case, when the bending points of the reflection shades are given a lot, that is, when the number of segments of the reflection shades increases, the light collecting performance is further improved, but manufacturing becomes difficult.

In addition, although the light collecting performance is improved even if the height of the reflection shade is increased, the overall size of the reflection shade increases, which causes a problem in that the construction cost increases.

In the case of simply applying the LED streetlight, which is the same as the conventional streetlight, the average road surface roughness is lowered and the uniformity is lowered. Therefore, it is difficult to realize a high-quality road lighting environment due to the wide road lane in Korea.

For high quality road lighting, it is important to ensure the driver's field of vision by providing the required illuminance and uniformity, and light distribution control of lighting fixtures is important.

Therefore, it is urgently needed to develop a light distribution device for a road lighting apparatus suitable for an LED light source by utilizing the advantages of a light emitting diode (LED) light source.

The present invention is to solve the above problems, in more detail to improve the efficiency of the road lighting fixtures, to ensure the roughness and uniformity of the road surface, and to control the light going back to increase the lighting rate of the LED lighting fixtures It is to provide a light distribution control device.

It is also an object of the present invention to provide a method of easily fastening the developed light distribution control device and to provide a minimum of glare to the driver.

Light distribution control device of the LED road lighting fixture of the present invention is coupled to the light source unit module 100, the light source unit module 100 including a plurality of LED light source 110, the segment A (210) having one slope and A first light source unit including a plurality of light source unit modules 100 and a reflection shade 200 including a segment B 220 and a segment C 230 disposed to face the segment A 210 and separated by a bending point. The second light source unit 410 and the reflection shader including a plurality of first lighting units 300 and a plurality of light source module modules 100 to control longitudinal light distribution of the road including the 310 and the reflector 200. A plurality of second lighting unit 400 for controlling the light distribution in the width direction of the road including a plurality of 200.

In addition, the slope of the reflection shade 200 is formed based on the equation φ = 1/2 (γ-δ), φ of the equation is the inclination angle of the segment of the reflection shade 200, γ is the LED light source 110 The vertical angle, δ of the light emitted from is characterized in that the light reflected from the segment is the angle between the vertical line and ρ.

In addition, the segment A 210 has α with respect to the vertical axis of the light source unit module 100, wherein α is 24 ° to 26 °, and the segment B 220 has β on the vertical axis of the light source unit module 100. Β is 21 ° to 23 °, and an angle between the segment B 220 and the segment C 230 is ω, but the ω is 164 ° to 167 °, and the segment C 230 is a light source module ( It has an ε on the vertical axis of 100), characterized in that the ε is formed in 6 ° ~ 8 °.

In addition, the first light source unit 310 has a predetermined angle θ with respect to the horizontal line, the θ is 5 °, the second light source unit 410 has a predetermined angle ρ with respect to the horizontal line, but the ρ is It is characterized by a 45 °.

In addition, the light source module 100 includes an LED light source 110, an LED substrate 120 having a plurality of LED light sources 110, and a heat dissipation fin 130 in close contact with an upper portion of the LED substrate 120. Characterized in that the 'c' shaped fastening portion 131 is formed on the heat dissipation fin 130, the coupling portion 240 is formed in the 'shade' shape in the reflection shade 200, The fastening part 131 and the coupling part 240 is characterized in that the sliding fastening.

In addition, the first reflection shade 211, the second reflection shade 212, the third reflection shade 213 of the reflection shade 200, but the reflection shade shade on the outside of the first reflection shade 211 and the second reflection shade 212 The fixing part 250 is formed, and the third reflection shade 213 is coupled to both sides when the first reflection shade 211 and the second reflection shade 212 are fastened to the light source module 100. .

In addition, the first reflector 211, the second reflector 212, and the third reflector 213 are included in the first illumination unit 300 and the second illumination unit 400, and the second illumination unit The auxiliary reflection shade 214 formed by extending the lengths of the first reflection shade 211, the second reflection shade 212, and the third reflection shade 213 of the reflection shade 200 included in the 400 is the second reflection shade 200. It is characterized in that the lighting unit 400 is further provided.

In addition, the first lighting unit 300 is fastened to the fastening structure 500, the reflection shade fixing bolt 510 is fixed to the reflection shade fixing portion 250 formed in the reflection shade 200, the heat radiation fin The heat dissipation fin fixing bolt 520 is coupled to and fixed to the heat dissipation fin fixing part 132 formed by being coupled to the 130.

In addition, the second lighting unit 400 is a reflection shade fixing bolt 510 is inserted into the reflection shade fixing portion 250 formed in the first reflection shade 211 and the second reflection shade 212 and the third reflection shade ( 213 is coupled to the side of the first reflector 211 and the second reflector 212, the heat radiation fin fixing bolt 520 is coupled to the heat radiation fin fixing hole 132 is formed by coupling the heat radiation fin 130 It is characterized in that it is fixed.

The light distribution control device of the LED road lighting apparatus of the present invention is easy to manufacture because the shape of the reflection shade for light distribution control is simple, and is easy to assemble since the reflection shade is fastened when the reflection shade is fastened to the light source unit. By varying the quantity depending on the application, the required luminous flux can be provided.

In addition, by shaping the shape of the reflector to efficiently control the light emitted from the LED to evenly illuminate the road surface, to satisfy the illuminance and uniformity required by the road lighting, and to send light only to the road surface through the rear light control It is possible to improve the lighting rate and to minimize the glare affecting the driver by implementing light distribution by giving a tilt to the light source module.

1 is a view showing an example of equal interval division of the LED light source for determining the light beam redistribution and segment slope applied in the present invention.
2 is a view showing a cross-sectional design process of the reflection shade to focus the light emitted from the LED light source.
3 is a cross-sectional view showing the shape of the reflection shade of the present invention.
4 is a view showing a method of fastening the reflection shade to the light source module.
5 is a perspective view of a first lighting unit for light distribution control in a road width direction;
6 is a perspective view of a second lighting unit for light distribution control in a road longitudinal direction;
7 is a perspective view showing the shape of a single light distribution controller of the present invention;
8 is a perspective view showing an LED road lighting mechanism composed of a plurality of light distribution control apparatus of the present invention.
9 is a view showing a light distribution curve for the light distribution apparatus of the road lighting mechanism according to the present invention.
10 is a view showing the illumination intensity distribution simulation results by the light distribution control device of the road lighting mechanism according to the present invention.

Hereinafter, the technical idea of the present invention will be described more specifically with reference to the accompanying drawings.

However, the accompanying drawings are only examples to illustrate the technical idea of the present invention in more detail, and thus the technical idea of the present invention is not limited to the accompanying drawings.

In the light distribution control device 11 of the LED road lighting apparatus according to the present invention, the LED light source 110 is used. However, the individual LED light source 110 lacks the luminous flux for satisfying the illuminance required by the road lighting.

Therefore, a plurality of LED light sources 110 are used, and in the present invention, seven LED light sources 110 should be provided in the LED substrate 120 by configuring a single module to facilitate electrical control.

Although one LED light source 110 is a very small light source, the light emission form is very different from the ideal point light source due to the light emission characteristics of the actual LED device. Moreover, the light distribution control device design process is more difficult for the LED light source 110 forming the cluster as in the present invention.

In the present invention, rather than designing the light distribution control device 11 in a state in which the light source module 100 is assembled to achieve light distribution, the light distribution control device 11 is designed to be focused on each light source unit, and each light source module 100 is designed. By inclining to assemble, the whole apparatus can achieve light distribution for road lighting.

Further, in the present invention, the IES file for the LED light source 110 is analyzed, and the zonal constant factor, Ωγ1-γ2 = 4πIγsin ((γ2-γ1) / 2) sin ((γ2 + γ1) / 2) (shown below) ( Here, Ωγ1-γ2 is the luminous flux between the γ1-γ2 angle, γ1-γ2 is the vertical angle, Iγ is the luminous intensity at the γ angle) to obtain the luminous flux for each angle and then concentrate the light as much as possible toward the vertical axis of the LED light source 110 By redistributing the luminous flux so as to make it possible, the method of finally determining the inclination of the reflection shade 200 is used.

Figure 1 shows an example of the equal interval division of the LED light source 110 applied in the present invention, Figures 2 to 3 is the reflection shade 200 to focus the light emitted from the LED light source 110 The figure which shows the cross section of.

1 to 3, it is preferable to design the inclination of the reflector 200 to focus as much as possible toward the vertical axis of the LED light source 110 based on the direction of the light emitted from the LED.

In addition, the tilt determination of the reflection shade 200 basically follows the slope determination formula of the reflection shade 200 and uses a ray tracing method.

[Equation 1]

φ = 1/2 (γ-δ)

Here, φ is the inclination angle of the segment of the reflector 200, γ is the vertical angle of the light emitted from the light source, δ is the angle (that is, the vertical angle to send) of the light reflected from the segment with the vertical line.

The shape of the reflector 200 designed through the above method is shown in FIG. 3.

The reflection shade 200 has a shape facing each other with the LED light source 110 interposed therebetween, and one side thereof faces the first reflection shade 211 including one segment having one slope to have a bending point. And a second reflector 212 including two segments.

That is, the reflection shade 200 includes a first reflection shade 211 including a segment A 210 having one inclination and a segment B 220 facing the first reflection shade 211 and divided at a bending point. And a second reflector 212 composed of segment C 230.

At this time, the segment A (210) has an α with respect to the vertical axis of the light source unit module 100, the α is 24 ° ~ 26 °, the segment B 220 has a β on the vertical axis of the light source unit module 100 Β is 21 ° to 23 °, and an angle between the segment B 220 and the segment C 230 is ω, but the ω is 164 ° to 167 °, and the segment C 230 is a light source module ( Ε on the vertical axis of 100) but the ε is tilted from 6 ° to 8 °.

The reason why the angles of the facing segments are different as described above is to reduce the blocking angle by the reflector 200 to provide the glare of the driver to the minimum in the light distribution control in the longitudinal direction.

In addition, the light source unit module 100 includes an LED light source 110, an LED substrate 120 having a plurality of LED light sources 110, and a heat dissipation fin 130 in close contact with an upper portion of the LED substrate 120. It is composed.

In addition, the reflector 200 is formed by extrusion molding a material of a synthetic resin such as aluminum extrusion or plastic, and is produced by coating aluminum deposition on the reflective surface, the upper end of the reflector 200 is formed on the heat dissipation fin 130 Coupling portions 240 are formed on both sides in order to fix the fastening portions 131.

FIG. 4 is a view illustrating a method of fastening the reflector 200 including the first reflector 211, the second reflector 212, and the third reflector 213 to the light source module 100.

The reflection shade 200 is fastened to the light source module 100 by a slide method. That is, the fastening part 131 is formed in a 'c' shape on the heat dissipation fin 130, and the coupling part 240 is formed in a 'a' shape on the reflection shade 200. And the reflection shade 200 are fastened in a slide manner.

As described above, the reflection shade 200 is fastened to the light source module 100 by a slide method, so that the assembly of the apparatus is easy, and can be easily detached during maintenance, repair or replacement, thereby reducing the maintenance cost.

In addition, the first reflecting plate 211 and the second reflecting plate 212 may be fixed after being fastened to the light source module by a slide method, and the third reflecting plate 213 is fastened to the side for the purpose of increasing efficiency.

In this case, the reflection shade fixing part 250 is formed outside the first reflecting plate 211 and the second reflecting plate 212, so that the third reflecting plate is the first reflecting plate 211 and the second reflecting plate 212. Both sides of the) is coupled by the reflection shade fixing bolt 510.

In addition, the light source unit modules 100 to which the reflector 200 is fastened are assembled with different structures and different inclinations for light distribution control in the road width direction and the length direction, and the reflector shades to provide an appropriate luminous flux according to a use. By assembling by varying the number of the light source module module 200 200 is fastened, it has fluidity. Since the first reflection shade 211 and the first light source 310 for the width-direction light distribution control are inclined toward the road surface, the light going back is minimized to send more light to the road surface, thereby improving the lighting rate.

5 is a view illustrating a shape in which the light source module 100 is assembled for light distribution control in a road width direction, and a plurality of first reflection shades 211 and second reflection shades 212 are provided on the first light source portion 310. Coupled to form a first lighting unit 300 for controlling light distribution in the road width direction.

In addition, the first light source unit 310 to which the plurality of reflection shades 200 are fastened for the light distribution control and the rear light control in the road width direction has a predetermined angle θ with respect to the horizontal axis of the road, but the angle θ is 5 °. The first light source unit 310 is assembled using the fastening structure 500.

FIG. 6 is a view illustrating a second lighting unit 400 in which a light source module 100 is assembled for light distribution control in a longitudinal direction of a road, and a plurality of fastening portions 120 of the light source module 100 are provided for light distribution control in a longitudinal direction. Two reflection shades 200 are combined to form a second light source unit 410.

In addition, the auxiliary reflection shade formed by extending the length of the first reflection shade 211, the second reflection shade 212, and the third reflection shade 213 of the reflection shade 200 included in the second lighting unit 400. 214 is further provided in the second lighting unit 400, and the second light source unit 410 has a predetermined angle ρ with respect to a horizontal line, and the ρ is inclined at an angle of 45 ° to distribute light in the road length direction. To form a second lighting unit 400 to control.

7 is a perspective view of a final module structure showing a shape in which the light source unit module 100 to which the reflection shade 200 is fastened is assembled.

The first lighting unit 300 is positioned in front of the second lighting unit 400 to distribute light in the width direction, and the second lighting unit 400 distributes the light in the longitudinal direction.

In addition, the first lighting unit 300 is fixed by the fastening structure 500, and more specifically to the reflector fixing portion 250 formed in the first reflector 211 and the second reflector 212. The reflection shade fixing bolt 510 is coupled, and the heat radiation fin fixing bolt 520 is inserted into the heat radiation fin fixing hole 132 formed by combining the heat radiation fin 130 to fix the light source unit module 100.

In addition, the second lighting unit 400 is a reflection shade fixing bolt 510 is inserted into the reflection shade fixing portion 250 formed in the first reflection shade 211 and the second reflection shade 212, the third reflection shade 213 ) Is coupled to the side of the first reflector 211 and the second reflector 212, the heat radiation fin fixing bolt 520 is inserted into the heat radiation fin fixing hole 132 is formed by the heat radiation fin 130 is coupled to the The light source module 100 is fixed.

In addition, the first light source unit 300 and the second light source unit 400 is limited to the angle formed by the vertical axis of the road to 45 ° and 5 °, but the light distribution by varying the angle according to the length and width of the road It can be implemented efficiently.

8 is a perspective view of a modular structure of the LED road lighting fixture 10 showing a shape in which the plurality of light distribution control devices 11 according to the present invention are assembled, and the light distribution control device 11 may vary in quantity depending on a use. Application can provide the required luminous flux.

More specifically, the light distribution control device 11 is composed of a first lighting unit 300 and two second lighting unit 400, according to the situation and the purpose of the road, the quantity of the light distribution control device 11 Alternatively, it is possible to provide the luminous flux required for each situation.

9 is a light distribution curve diagram for the light distribution control apparatus according to the present invention.

In the drawing, the central vertical axis represents luminance (cd), the horizontal axis and both vertical and vertical axes represent angles at which light is emitted, and the luminance (cd) was measured at 30-degree intervals from 0 degrees to 360 degrees.

As shown in the figure by using the reflector 200 of the present invention, it can be seen that the illumination rate is improved because the rear light is controlled to send the light to the road surface from 0 ° to 60 °.

FIG. 10 is a view showing an LED road lighting fixture 10 formed of a plurality of light distribution control devices 11 according to the present invention at a 10m installation height and a 35m installation interval on a reciprocating six-lane road of one-way three-lane (one lane 3.5m). It is a figure which simulates the situation arrange | positioned and shows the result of having performed the illumination simulation in that situation.

10 can be seen that the LED road lighting mechanism 10 according to the present invention gives an even illuminance distribution on the road surface when it is arranged to face one-way three-lane road, six-way round trip.

KS C 7658 Simulation result Average surface roughness [lx] 14 16.8 Comprehensive Roughness Bacteria
[Emin / Eavg] 0.4 0.63 Lane Shaft Bacteria
[Emin / Emax] 0.5 Lane 1: 0.86
Second lane: 0.69
Third lane: 0.64 TI [%] - 9

Table 1 shows the average illuminance for each lane, overall uniformity, and lane axis uniformity, and illuminance criteria and simulation of road illumination for drivers presented in KS C 7658, which recommends safety and performance requirements for LED security and street lighting fixtures. The results are compared and presented. Before the simulation, the luminous flux was input in consideration of the efficiency reduction by SMPS or other devices at the rated luminous flux of the LED.

As shown in Table 1, the LED road lighting fixture 10 of the present invention has an average road surface roughness of 16.8 lx and an overall roughness level of E _min / E _avg. 0.63, Lane Axillary Balancing System 1 lane 0.86 2 lane 0.69 3 lane 0.64, higher than the values given in KS C7658, can be used as road lighting.

Therefore, the light distribution control device of the LED road lighting mechanism 10 of the present invention is easy to manufacture because the shape of the reflection shade 200 for light distribution control is easy, and the reflection shade 200 is fastened to the light source unit module 100. Since the assembly is easy because it is fastened in a slide manner, the light source module 100 can provide the required luminous flux by varying the quantity depending on the purpose of the lighting fixture.

In addition, by specifying the shape of the reflector 200 to efficiently control the light emitted from the LED light source 110 to be evenly illuminated on the road surface, to satisfy the illuminance and uniformity required in the road lighting, rear light control Since only light is transmitted through the road surface, the lighting rate may be improved, and the light source module 100 may be tilted to implement light distribution, thereby minimizing glare affecting the driver.

10 LED lighting device 11: light distribution control device
100: light source module 110: LED light source
120: LED substrate 130: heat radiation fin
131: fastening portion 132: heat radiation fin fixing hole
200: reflection shade 210: segment A
220: segment B 230: segment C
211: first reflection shade 212: second reflection shade
213: third reflection shade 214: secondary reflection shade
240: coupling part
250: reflection shade fixing portion 300: first lighting unit
310: first light source 400: second illumination
410: second light source unit 500: fastening structure
510: reflection shade fixing bolt 520: heat radiation fin fixing bolt
530: Structure fixing bolt

Claims (9)

In road lighting fixtures,
A light source unit module 100 including a plurality of LED light sources 110;
Segment B (220) and Segment C (230), which are coupled to the light source module module (100), are disposed to face the segment A (210) and the segment A (210) having one slope, and are separated by a boundary of a bending point. Reflection shade 200 made of;
A plurality of first lighting units 300 including a first light source unit 310 provided with a plurality of light source unit modules 100 and the reflection shade 200 to control longitudinal light distribution of a road; And
And a plurality of second lighting units 400 for controlling the light distribution in the width direction of the road, including a plurality of second light source units 410 and the reflection shade 200 provided with a plurality of light source unit modules 100.
The slope of the reflection shade 200 is expressed by equation
φ = 1/2 (γ-δ), wherein φ of the equation is the inclination angle of the segment of the reflector 200, γ is the vertical angle of light emitted from the LED light source 110, δ is the segment Light distribution control device for LED road lighting fixtures, characterized in that the reflected light is an angle formed with the vertical line.
delete The method of claim 1,
The segment A 210 has α with respect to the vertical axis of the light source module 100, wherein α is 24 ° to 26 °, and the segment B 220 has β on the vertical axis of the light source module 100. β is 21 ° to 23 °, and the angle between the segment B 220 and the segment C 230 is ω, but the ω is 164 ° to 167 °, and the segment C 230 is the light source unit module 100. Light distribution control device of the LED road lighting fixture having an ε on the vertical axis of the ε is formed 6 ° ~ 8 °.
The method of claim 1,
The first light source unit 310 has a predetermined angle θ with respect to the horizontal line, the θ is 5 °, and the second light source unit 410 has a predetermined angle ρ with respect to the horizontal line, but the ρ is 45 °. Light distribution control device of the LED road lighting fixtures.
The method of claim 1,
The light source unit module 100 includes an LED light source 110, an LED substrate 120 having a plurality of LED light sources 110, and a heat dissipation fin 130 in close contact with an upper portion of the LED substrate 120. But
A 'c' shaped fastening part 131 is formed on the heat dissipation fin 130, and a coupling part 240 is formed in a 'b' shape on the reflection shade 200, and the fastening part 131 is formed. Light distribution control device of the LED road lighting fixtures, characterized in that the sliding portion and the coupling 240).
6. The method of claim 5,
The reflection shade 200 is composed of a first reflection shade 211, a second reflection shade 212, a third reflection shade 213,
A reflection shade fixing part 250 is formed outside the first reflection shade 211 and the second reflection shade 212, and the third reflection shade 213 is provided with the first reflection shade 211 and the second reflection shade 212. Light distribution control device for LED road lighting fixtures, characterized in that coupled to both sides when the light source module 100 is fastened.
The method according to claim 6,
The first reflector 211, the second reflector 212, and the third reflector 213 are included in the first illumination unit 300 and the second illumination unit 400, and the second illumination unit 400. The second reflection shade 214 formed by extending the length of the first reflection shade 211, the second reflection shade 212, and the third reflection shade 213 of the reflection shade 200 included in the second lighting unit Light distribution control device of the LED road lighting fixture, characterized in that it is further provided in 400.
8. The method of claim 7,
The first lighting unit 300 is fastened to the fastening structure 500, the reflection shade fixing bolt 510 is fixed to the reflection shade fixing portion 250 formed in the reflection shade 200, the heat radiation fin 130 The light distribution control device for LED road lighting fixtures, characterized in that the heat radiation fin fixing bolt 520 is coupled to and fixed to the heat radiation fin fixing portion 132 is combined.
8. The method of claim 7,
In the second lighting unit 400, a reflection shade fixing bolt 510 is inserted into the reflection shade fixing part 250 formed in the first reflection shade 211 and the second reflection shade 212 so that the third reflection shade 213 is provided. The heat dissipation fin fixing bolt 520 is coupled to the side surfaces of the first reflector 211 and the second reflector 212, and the heat dissipation fin fixing bolt 520 is fixed to the heat dissipation fin fixing hole 132 formed by the heat dissipation fin 130. Light distribution control device of the LED road lighting fixtures.

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