KR102128220B1 - Dual reflector adjusting module for LED lamp and lighting lamp implement using of the same - Google Patents

Abstract

The present invention provides a dual-reflector control module for an LED lamp and a floodlighting fixture using the same which can individually rotate and control a pair of reflectors to change lighting directions and adjust the size of a lighting area. According to a preferred embodiment of the present invention, the dual-reflector control module for the LED lamp comprises: a reflector housing having a floodlight port opened to one side; a rear reflector rotatably hinge-coupled to one side in the reflector housing; a front reflector facing the rear reflector to be rotatably hinge-coupled to the other side in the reflector housing; a first and a second servo motor installed side by side on the reflector housing side; a first arm connected to a rotary shaft of the first servo motor; a rear reflector driving link wherein one end thereof is connected to the first arm and the other end thereof is connected to the rear reflector; a second arm connected to a rotary shaft of the second servo motor; and a front reflector driving link wherein one end thereof is connected to the second arm and the other end thereof is connected to the front reflector.

Description

Dual reflector adjusting module for LED lamp and lighting lamp implement using of the same}

The present invention relates to a dual reflector control module for LED lighting and a floodlight fixture using the same, in particular, it is possible to form a light distribution curve suitable for the object to be projected, thereby realizing an optimal leveling system, and each of the four through four floodlights in one floodlight. It is possible to obtain the light distribution curves of dogs and overcome the limit of 10 lux of vertical roughness according to the standard of light pollution prevention method through the angle control of the front and rear reflectors so that it can be conveniently applied by adjusting the size and direction of the lighting area in any field conditions. It relates to a dual reflector control module for an LED lighting and a floodlight using the same.

Known LED asymmetric projection method is performed by allowing the light generated from the LED to be transmitted through asymmetric reflectors facing each other. In this case, lighting is performed only in an area of a size limited by the intrinsic curvature radius of the reflector. Therefore, there is a problem that the lighting direction can be adjusted to suit the installation situation of the LED lighting equipment and the lighting area cannot be adjusted large or small.

As a background technology of the present invention, as Korean Patent Registration No. 10-2030931,'Asymmetric glareless reflector and floodlight using the same' have been proposed. This provides an asymmetric reflecting structure to eliminate glare during night illumination, but provides an asymmetric flood reflector with high illuminance and luminance in a wide flooded area and a floodlight using the same. Here, the asymmetric transmissive reflector includes a first reflective curved portion and a second reflective curved portion forming an asymmetrical side facing the first reflective curved portion. However, the background technology has limitations in applying to various field conditions because it is difficult to form a light distribution curve suitable for a target to be projected because the first reflective curved portion and the second reflective curved portion are fixedly installed.

Korean Registered Patent Registration No. 10-2030931

The present invention can form a light distribution curve suitable for the object to be projected to realize an optimal leveling system, obtain four different light distribution curves through four light transmission ports in one light projector, and vertical roughness according to the light pollution prevention method standards. It provides a dual reflector control module for LED lighting and a floodlight fixture using the same, which overcomes the limit of 10 lux through the size and direction of the lighting area in any field conditions through angle control of the front and rear reflectors. There is a purpose.

A dual reflector control module for LED lighting according to a preferred embodiment of the present invention includes: a reflector housing having a light-transmitting opening opened to one side; A rear reflector rotatably hinged to one side in the reflector housing; A front reflecting plate hingedly coupled to the other side of the reflector housing to face the rear reflecting plate; First and second servomotors installed side by side on the reflector housing side; A first arm connected to the rotation axis of the first servomotor; A rear reflector drive link having one end connected to the first arm and the other end connected to the rear reflector; A second arm connected to the rotation axis of the second servomotor; It characterized in that it comprises; one end is connected to the second arm and the other end is connected to the front reflector front reflector drive link.

In addition, the first arm is formed with a plurality of rear reflector drive link connecting holes formed at regular intervals so as to increase or decrease the rotation angle of the rear reflector, one end of the rear reflector drive link connection hole of the plurality of rear reflector drive link It is characterized by being inserted into one and connected to the hinge.

In addition, the rear reflector driving link is made of a wire material and is characterized by having a bending step formed by bending twice at regular intervals in the longest straight section to prevent buckling during operation and to reinforce bending rigidity.

In addition, the second arm is characterized in that a plurality of front reflector drive link connecting holes are formed at regular intervals so as to increase or decrease the rotation angle of the front reflector.

In addition, the rear reflecting plate and the front reflecting plate are characterized in that they are installed in an asymmetric shape.

In addition, the reflective plate housing has a housing bottom plate formed in a square strip shape having an opening for LED arrangement communicated with the light transmitting sphere; A housing wall erected at a constant height along the housing bottom plate; One or more first hinge grooves formed to hinge the rear reflector plate to the bottom surface of the housing bottom plate; One or more second hinge grooves formed at a predetermined distance from the first hinge grooves to hinge-couple the front reflective plate to the bottom surface of the housing bottom plate; It characterized in that it comprises; a servo motor mount installed with a heat dissipation opening opened downward to the housing bottom plate side to install the first servo motor and the second servo motor.

According to the dual reflector control module for LED lighting of the present invention and a floodlight fixture using the same, it is possible to individually control the two front and back reflectors so that the direction of illumination and the increase or decrease of the illumination area can be adjusted and projected. By forming a light distribution curve suitable for it, it is possible to realize an optimal leveling system.

In addition, it is possible to obtain four different light distribution curves through four light-transmitters in one light-transmitter and illuminate any field condition through angle control of the front and rear reflectors in accordance with the Light Pollution Prevention Act standards. It can be conveniently applied by overcoming through the size adjustment and direction of the area.

In addition, since the servomotor mount is installed in the reflector housing, the installation of the first and second servomotors is easy, and the life of the first and second servomotors is improved due to the heat generation effect.

In addition, the rotation angles of the first and front reflectors can be variously controlled by a method in which a driving link is hinged to any one of a plurality of holes respectively formed in the first arm and the second arm.

In addition, since the rear reflector drive link has a multi-stage bent structure, buckling is prevented even with a long wire, thereby increasing the reliability of the rotation of the rear reflector.

The following drawings attached in this specification are intended to illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the present invention, so the present invention is only described in the accompanying drawings. It is limited and should not be interpreted.
1 is a perspective view of a dual reflector control module for LED lighting according to an embodiment of the present invention.
Figure 2 is an exploded perspective view of Figure 1;
Figure 3 is a front view of Figure 1;
4 is a rear view of FIG. 3;
5 is a rear side perspective view of the reflector housing shown in FIG. 1.
6A is an exploded view showing a state in which three rear reflectors and three front reflectors can be selectively installed in the reflector housing shown in FIG. 1.
6B is an exemplary view showing a state in which three rear reflectors and three front reflectors shown in FIG. 6A can be installed in a reflector housing.
7A and 7B are perspective and front views of a dual reflector control module for LED lighting according to another embodiment of the present invention.
8A is a state diagram of four dual reflector control modules for LED lighting according to an embodiment of the present invention.
8B is a perspective view of a floodlight fixture to which the four LED lighting dual reflector control module shown in FIG. 8A is applied.
9a to 9f is a light distribution according to the angle control of the front and rear reflectors according to the present invention,
Figure 9a is when the front reflector is variable by one side by 5 degrees,
Figure 9b is when the front reflector is variable by one side by 10 degrees,
9c is when the rear reflector is variable by 5 degrees,
9d is when the rear reflector is variable by 10 degrees,
9E is when the front reflector and the back reflector are varied by 5 degrees on both sides,
9F shows when the front reflector and the back reflector are varied by 10 degrees on each side.

The present invention will be described in detail below with reference to the embodiments presented in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention and the invention is not limited thereto.

The dual reflector control module 10 for LED lighting according to the present embodiment is provided with a reflector housing 12 having a light transmitting hole 12a open to one side as shown in FIGS. 1 to 5. The reflector housing 12 has a housing bottom plate 121 formed in a quadrangular band shape with an opening 121a for LED arrangement communicating with the light transmission hole 12a, and a housing installed at a predetermined height along the housing bottom plate 121 The wall 122, one or more first hinge grooves 123 formed to hinge the rear reflecting plate 14 to the bottom surface of the housing bottom plate 121, and the rear reflecting plate 16 on the bottom surface of the housing bottom plate 121 ) To install the one or more second hinge grooves 124 and the first servo motor 18 and the second servo motor 20 formed at a distance from the first hinge groove 123 to couple the hinges. It includes a servo motor mount 125 installed on the housing bottom plate 121 side.

In this embodiment, the first hinge groove 123 is formed in two places with a certain inter-axle distance h1, and the second hinge groove 124 has an inter-axle distance h1 and a different inter-axle distance h2. Although formed at a location, the present invention is not limited to this location and may be formed at more locations or may be formed at one location as shown in FIGS. 7A and 7B.

A rear reflector 14 is rotatably hinged to one side in the reflector housing 12. The rear reflection plate 14 is hinged to and installed in the first hinge groove 123 formed on the bottom surface of the housing bottom plate 121. Therefore, the rear reflection plate 14 is rotatable with the first hinge groove 123 as the first rotation axis X1. At this time, the radius of curvature R1 of the rear reflecting plate 14 is formed smaller than the radius of curvature R2 of the front reflecting plate 16 and is installed asymmetrically. When installed in this way, reinforcement interference is performed to increase the illuminance and luminance of the corresponding illumination area. Of course, the rear reflecting plate 14 and the front reflecting plate 16 may be installed with a flat reflecting surface having a curvature radius on either side or both without curvature.

In this embodiment, the rear reflector 14 is provided with three having an angle of reflection of 30°, 48°, and 60°, and any one of them is selected to rotate by selecting any one of the two first hinge grooves 123 It is installed to allow angle adjustment. The reflection angle of the rear reflection plate 14 is not limited to this example.

The front reflecting plate 16 is rotatably hinged to the other side in the reflecting plate housing 12 facing the rear reflecting plate 14. The front reflecting plate 16 is hinged to and installed in the second hinge groove 124 formed on the bottom surface of the housing bottom plate 121. Therefore, the front reflection plate 16 is rotatable with the second hinge groove 124 as the second rotation axis X2.

In this embodiment, the front reflector 16 is provided with three having an angle of reflection of 30°, 48°, and 60°, and any one of them is selected to rotate by selecting any one of the two second hinge grooves 124 It is installed to allow angle adjustment. The reflection angle of the front reflection plate 16 is not limited to this example.

First and second servo motors 18 and 20 are provided side by side on the reflector housing 12 side. In this embodiment, the first and second servomotors 18 and 20 are installed side by side on the servomotor mount 125 installed on the housing bottom plate 121 side of the reflector housing 12.

The first arm 22 for rotationally driving the rear reflection plate 14 via the rear reflection plate drive link 24 is connected to the rotation shaft of the first servomotor 18. At this time, a plurality of rear reflector drive link connecting holes 22a formed at regular intervals are formed on the first arm 22 so as to increase or decrease the rotation angle of the rear reflector 14, and one end of the rear reflector drive link 24 is formed. It is inserted into any one of the plurality of rear reflector drive link connecting holes 22a and is hinged. Therefore, the rear reflection plate drive link 24 is hinged by selecting any one of the plurality of rear reflection plate drive link connection holes 22a, thereby enabling various control of the rotation angle of the rear reflection plate 14.

The rear reflection plate driving link 24 has one end connected to the first arm 22 and the other end connected to the rear reflection plate 14. At this time, the rear reflector drive link 24 is made of a long wire, it is preferable to have a bent step portion (24a) formed by bending twice at regular intervals in the longest straight section in order to prevent buckling and reinforce the bending rigidity during operation. When the rear reflector driving link 24 is made of a long wire, it is advantageous to fabricate the floodlight luminaire 100 as shown in FIG. 8A by arranging the dual reflector adjusting module 10 for LED lighting side by side as shown in FIG. 8B.

The second arm 26 for rotationally driving the front reflection plate 16 via the front reflection plate drive link 28 is connected to the rotation axis of the second servo motor 20. At this time, the second arm 26 is formed with a plurality of front reflector drive link connecting holes 26a formed at regular intervals so as to increase or decrease the rotation angle of the front reflector 16. Therefore, the front reflection plate drive link 28 is hinged by selecting any one of the plurality of front reflection plate drive link connection holes 26a, thereby enabling various control of the rotation angle of the front reflection plate 16.

The front reflector drive link 28 has one end connected to the second arm 26 and the other end connected to the front reflector 16. In this embodiment, the front reflector drive link 28 has one end hinged to any one of the plurality of front reflector drive link connecting holes 26a of the second arm 26, and the other end is connected to the rear surface of the front reflector 16. It is hinged to the protruding connecting piece 162.

The servo motor mount 125 has a heat dissipation opening 125a that is opened downward for heat treatment during operation of the first and second servo motors 18 and 20. Therefore, the lifespan of the first and second servomotors 18 and 20 is improved.

Unexplained code '129' is'reinforcement plate'.

The dual reflector control module 10 for LED lighting configured as described above has the rear reflector 14 through the rear reflector drive link 24 according to the rotation driving direction of the first servo motor 18 as shown in FIG. 3. ) Is rotated about the first hinge axis (X1) to adjust the angle.

In addition, the front reflector 16 is rotated around the second hinge axis X2 of the reflector housing 12 through the front reflector drive link 28 according to the rotational driving direction of the second servomotor 20. Adjustment is made.

The dual reflector control module 10 for LED lighting configured as described above is installed on the bottom surface of the reflector housing 12, as shown in Figure 8b, a plurality of LED elements 50 are arranged side by side, LED floodlight fixture 100 as shown in Figure 8a Is used as In this case, by adjusting the light distribution angle of the rear reflection plate 14 and the front reflection plate 16, as shown in FIGS. 9A to 9F, a light distribution curve suitable for the object to be projected can be formed to realize an optimal leveling system. That is, as shown in FIG. 9A, it can be seen that light distribution is made farther to the farther side when the front reflecting plate 16 is 10-degree-side variable as shown in FIG. Also, as shown in FIG. 9C, it can be seen that light distribution is made smaller when the rear reflector 14 is changed by 5 degrees to the side than in the case where the rear reflector 14 is variable by 5 degrees to the side. In addition, when the front reflecting plate 16 and the rear reflecting plate 14 are varied by 5 degrees as shown in FIG. 9E, the distance is greater than when the front reflecting plate 16 and the rear reflecting plate 14 are varied by 10 degrees as shown in FIG. 9F. You can see that the lighting is done.

In addition, as shown in FIGS. 8A and 8B, when four dual reflector control modules 10 for LED lighting are applied to one floodlight 100, four different light distribution curves can be obtained through four floodlights. In addition, in the dual reflector control module 10 for LED lighting, the reflective surfaces of the rear reflector 14 and the front reflector 16 are installed asymmetrically, so that it is possible to adjust the lighting direction and adjust the size of the illumination area with no glare. It has the advantage of becoming. In addition, according to the light pollution prevention law standards, the vertical roughness limit of 10 lux has the advantage of being conveniently applicable to any site conditions through the angle control of the two rear reflecting plates 14 and the front reflecting plate 16.

Reference numeral '90' is'front cover', '70' is'rear cover', and '80' is'floodlight hinge bracket'.

The present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such modified and modified inventions, but is limited by the appended claims.

10: Dual reflector control module for LED lighting
12: Reflector housing
14: rear reflector
16: Front reflector
18: 1st servo motor
20: second servo motor
22: first arm
24: rear reflector drive link
26: second arm
28: front reflector drive link

Claims (7)

In the dual reflector control module 10 for LED lighting,
A reflector housing 12 having a light transmitting hole 12a open to one side;
A rear reflecting plate 14 rotatably hinged to one side in the reflector housing 12;
A front reflector plate (16) rotatably hinged to the other side of the reflector housing (12) facing the rear reflector plate (14);
First and second servomotors 18 and 20 installed side by side on the reflector housing 12 side;
A first arm 22 connected to the rotation axis of the first servomotor 18;
A rear reflection plate driving link 24 having one end connected to the first arm 22 and the other end connected to the rear reflection plate 14;
A second arm 26 connected to the rotation axis of the second servomotor 20;
A dual reflector control module for LED lighting, characterized in that it includes; one end is connected to the second arm 26 and the other end is connected to the front reflector 16, the front reflector drive link (28). According to claim 1,
The first arm 22 has a plurality of rear reflector drive link connecting holes 22a formed at regular intervals to increase or decrease the rotation angle of the rear reflector 14, and one end of the rear reflector drive link 24 is formed. Dual reflector control module for LED lighting, characterized in that it is inserted into any one of a plurality of rear reflector drive link connection holes (22a) and hinged. According to claim 1,
The rear reflector drive link 24 is made of wire and is characterized by having a bending step portion 24a formed by bending twice at regular intervals in the longest straight section to prevent buckling during operation and to reinforce bending rigidity. Dual reflector control module for lighting. According to claim 1,
The second arm 26 has a plurality of front reflector drive link connecting holes 26a formed at regular intervals so as to increase or decrease the rotation angle of the front reflector 16, dual reflector control module for LED lighting, characterized in that formed . According to claim 1,
The rear reflector 14 and the front reflector 16 is a dual reflector control module for LED lighting, characterized in that installed asymmetrical to each other. According to claim 1,
The reflector housing 12 is
A housing bottom plate 121 having an opening 121a for disposing an LED in communication with the light transmitting sphere 12a and formed in a quadrangular band shape;
A housing wall 122 which is erected at a predetermined height along the housing bottom plate 121;
One or more first hinge grooves (123) formed to hinge the rear reflector plate (14) to the lower surface of the housing bottom plate (121);
One or more second hinge grooves 124 formed at a predetermined distance from the first hinge groove 123 to hingely engage the front reflective plate 16 on the lower surface of the housing bottom plate 121;
Including the first servo motor 18 and the second servo motor 20, the servo motor mount 125 is installed with a heat dissipation opening 125a opened to the bottom of the housing bottom plate 121 side to install the Features a dual reflector control module for LED lighting. Claims 1 to 6, wherein any one of the dual reflector control module 10 for LED lighting is installed adjacent to each other in a plurality of or more, and these two light reflector 12a of the dual reflector control module 10 for LED lighting LED element (50) disposed toward; LED floodlight fixture comprising a.

Images