KR102276049B1 - A Light Distribution Controlling Type of a Floodlight Module Using a Variable Symmetric Type of a Reflector and a Light Apparatus by the Same - Google Patents

Abstract

The present invention relates to an LED floodlight module with a light distribution controlling structure using a variable symmetric type reflector, and a light apparatus by the same. The LED floodlight module with a light distribution controlling structure includes: a plurality of control reflectors (11_1 to 11_L) extended along a light induction direction while being circularly disposed adjacent to each other; a base (13) to which one end of the plurality of control reflectors (11_1 to 11_L) is coupled; and a guide holder (14) rotatably disposed with respect to the base (13). The inclination angles of the plurality of control reflectors (11_1 to 11_L) are adjusted by the rotation of a guide holder (14). The light distribution can be adjusted and the evenness can be maintained.

Description

A Light Distribution Controlling Type of a Floodlight Module Using a Variable Symmetric Type of a Reflector and a Light Apparatus by the Same

The present invention relates to an LED floodlight module having a light distribution control structure using a variable-type symmetrical reflector and a lighting device by the same, and specifically, to a light distribution using a variable-type symmetrical reflector capable of adjusting the light distribution area by changing the geometric structure of the reflector It relates to an LED floodlight having a control structure and a lighting device by the same.

The light emitted from the light source illuminates the illumination area while being diffused, and the light distribution characteristic of the lighting device needs to be adjusted so that the predetermined illumination area has a suitable illumination environment. The light distribution characteristic may be formed by, for example, inducing a diffusion direction of light by a reflector or changing a traveling direction of light by a lens. Patent Registration No. 10-1194760 discloses a floodlight divided into polygons. In addition, Patent Registration No. 10-1571370 discloses a light distribution sheet and a lighting device including the same. It is advantageous to adjust the light distribution characteristics so that the size of the illumination area can be adjusted and the uniformity can be controlled. However, the prior art does not disclose a light distribution control module having such a characteristic.

The present invention has the following objects to solve the problems of the prior art.

Prior Art 1: Patent Registration No. 10-1194760 (Changjo Energy Con Co., Ltd., Announced on Oct. 25, 2012) Multi-angle split dome floodlight with improved light distribution and illuminance Prior Art 2: Patent Registration No. 10-1571370 (POSCO Co., Ltd., Announcement on 11.25/2015) Light distribution sheet and LED lighting device including the same

An object of the present invention is to provide an LED floodlight module having a light distribution control structure using a symmetrical reflector of a variable method that enables light distribution to be controlled while maintaining uniformity, and a lighting device thereby.

According to a suitable embodiment of the present invention, an LED floodlight module of a light distribution control structure using a variable-type symmetrical reflector includes a plurality of control reflectors each extending along a direction of light while being disposed adjacent to each other in a circular shape; a base to which one end of a plurality of control reflectors is coupled; and a guide holder disposed to be rotatable with respect to the base, and the angle of inclination of the plurality of adjustment reflectors is adjusted in the extending direction by rotation of the guide holder.

According to another suitable embodiment of the present invention, it further includes an adjustment clamp for rotatably fixing the plurality of adjustment reflectors to the base.

According to another suitable embodiment of the present invention, it further includes an elastic flap for maintaining the plurality of adjustable reflectors in a predetermined direction.

According to another suitable embodiment of the present invention, each of the plurality of control reflectors gradually increases in width along the light guiding direction and has a curved overall shape along the extension direction.

According to another suitable embodiment of the present invention, the guide holder has a ring shape as a whole, and a plurality of guide paths for guiding the movement of each adjustable reflector along the inner circumferential surface are formed.

According to another suitable embodiment of the present invention, it further comprises a rotation adjustment unit for rotating the guide holder.

According to another suitable embodiment of the present invention, the lighting device includes a plurality of adjustable reflectors disposed successively adjacent to each other along a circle; LED module disposed in the center of the control reflector; and a guide holder for guiding the plurality of adjustment reflectors to be moved in a circumferential direction, wherein the plurality of adjustment reflectors are moved along the guide holder to adjust the inclination level along the extension direction, thereby controlling light distribution.

The LED floodlight module having a light distribution control structure using a variable-type symmetrical reflector according to the present invention transmits and guides light to the lighting area by a plurality of adjustable reflectors capable of directional angle adjustment, so that the lighting area can be controlled. A uniform degree of uniformity is maintained by adjusting the light distribution characteristic by adjusting the extension angle of the control reflector. Various types of additional light distribution control means may be disposed in the floodlight module according to the present invention, and the present invention is not limited thereto. The lighting device according to the present invention can be applied to various lighting lamps including floodlights. The lighting device according to the present invention has the advantage that it can be effectively applied to the manufacture of a lighting device according to the light pollution prevention method by applying a reflector module method, unlike the known lens-type floodlight, so that the transmitted light is limited to the reflector.

1 and 2 show an embodiment of an LED floodlight module having a light distribution control structure using a variable-type symmetrical reflector according to the present invention.
3 shows an embodiment of an exploded structure of a floodlight module according to the present invention.
4 shows an embodiment of a control reflector applied to the floodlight module according to the present invention.
5 and 6 show an embodiment of a reflector control structure applied to the floodlight module according to the present invention.
7 illustrates an embodiment of a structure in which a lighting area is adjusted by an LED lighting device using a variable-type symmetrical reflector according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the embodiments are for a clear understanding of the present invention, and the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so they will not be repeatedly described unless necessary for the understanding of the invention, and well-known components will be briefly described or omitted, but the present invention It should not be construed as being excluded from the embodiment of

1 and 2 show an embodiment of an LED floodlight module having a light distribution control structure using a variable-type symmetrical reflector according to the present invention.

1 and 2, the LED floodlight module having a light distribution control structure using a variable-type symmetrical reflector is disposed adjacent to each other in a circular shape and a plurality of control reflectors 11_1 to 11_L each extending along the light induction direction. ; a base 13 to which one end of a plurality of control reflectors 11_1 to 11_L is coupled; and a guide holder 14 that is rotatably disposed with respect to the base 13 , and the extension direction of the plurality of control reflectors 11_1 to 11_L is adjusted by the rotation of the guide holder 14 .

The plurality of control reflectors 11_1 to 11_L reflect the light emitted from the LED module EM and guide it to the lighting area, and each of the control reflectors 11_1 to 11_L has the same or similar structure. Each of the control reflectors 11_1 to 11_L may have a curved shape that is convex outward as a whole while gradually increasing in width along the light induction direction, but is not limited thereto, and may have various structures depending on the lighting area. The plurality of control reflectors 11_1 to 11_L may be sequentially disposed adjacent to each other along a circle, whereby the reflector module may have a truncated cone-shaped reflective structure in which the diameter increases along the light emission direction as a whole. One end portion of each of the control reflectors 11_1 to 11_L may be coupled to the base 13 in which an arrangement hole is formed in the central portion while being in a circular plate shape as a whole. The LED module EM may be disposed in the arrangement hole, and the LED module EM may have a symmetrical shape with respect to the center. Each of the control reflectors 11_1 to 11_L may be coupled to the base 13 to be rotatable or to be tilted by the control clamps 12_1 to 12_L. Specifically, each of the adjustable reflectors 11_1 to 11_L may be rotated inward or outward around the bonding point of the base 13, whereby the inclination of each of the adjustable reflectors 11_1 to 11_L may be adjusted. . The inclination adjustment of each of the adjustment reflectors 11_1 to 11_L as described above may be performed by the guide holder 14 . The guide holder 14 can be rotated in one direction or the other direction by the operation of the rotation control unit 17, and by the rotation of the guide holder 14, a plurality of adjustment reflectors 11_1 to 11_L are attached to the adjustment clamp ( 12_1 to 12_L) may be rotated in an inward direction or an outward direction. The outer surface of each of the control reflectors 11_1 to 11_L may contact the guide path formed in the inner part of the guide holder 14, and the guide holder 14 rotates to change the contact portion to change the contact portion of each of the control reflectors 11_1 to 11_L) may be adjusted. A hook plate 15 may be coupled to the guide holder 14 , and the hook plate 15 induces rotation of the guide holder 14 and at the same time stably moves each of the control reflectors 11_1 to 11_L to a predetermined position. It has a fixing function. In detail, when the adjustable reflective plates 11_1 to 11_L are adjusted to have a preset inclination level, the adjustable sloping plates 11_1 to 11_L need to be stably maintained at predetermined positions. Elastic flaps 16_1 to 16_L may be installed to ensure positional stability of the adjustable inclined plates 11_1 to 11_L. The elastic flaps 16_1 to 16_L may include, for example, an elastic means such as a coil spring, and one end may be fixed to the hook plate 15 while the other end may be coupled to each adjustable reflector 11_1 to 11_L. have. Positional stability of each of the inclination control plates 11_1 to 11_L can be secured with respect to external shock or vibration by the elastic flaps 16_1 to 16_L. Each of the inclination control plates 11_1 to 11_L may be fixed to a predetermined position in various ways and is not limited to the presented embodiment.

An exploded structure of the reflector module having such a structure will be described below.

Figure 3 shows an embodiment of the disassembled structure of the reflector module according to the present invention.

Referring to FIG. 3 , the base 13 , the guide holder 14 , and the hook plate 15 may have a circular band shape as a whole, and an induction hole may be formed in each central portion. And the LED module EM may be disposed in the central part of the base 13, and the light emitted from the LED module EM is guided to a lighting area defined by a plurality of control reflectors 11_1 to 11_L arranged in a circle. can be One end of each of the adjustment reflectors 11_1 to 11_L may be fixed to the body extending in a circle of the base 13 by the adjustment clamps 12_1 to 12_L. One end of each of the adjustment clamps 12_1 to 12_L may be fixed to the base 13 , and the other end may be coupled to one end of each of the adjustment reflectors 11_1 to 11_L. The outer surface of each of the control reflectors 11_1 to 11_L may come into contact with the inner edge of the guide holder 14 , and the hook plate 15 may be coupled to the guide holder 14 . The guide holder 14 and the hook plate 15 may be rotatably coupled with respect to the base 13 , and the guide holder 14 may be rotated by the rotation adjustment unit 17 . The elastic flaps 16_1 to 16_L may have a structure in which hook-shaped hooks are formed in both directions of the coil spring-shaped elastic means, and one hook is coupled to a fixed hook 152_K formed on the hook plate 15, Another hook may be coupled to the rear of each of the control reflectors 11_1 to 11_L. The guide holder 14 and the hook plate 15 may be rotated by the operation of the rotation control unit 17 , whereby the inclination of each of the control reflectors 11_1 to 11_L may be adjusted. When the inclination is adjusted to a predetermined level, each of the adjustment reflectors 11_1 to 11_L may be stably fixed at a predetermined position by the elastic flaps 16_1 to 16_L. Hereinafter, an operation structure for adjusting the inclination of the adjustment reflectors 11_1 to 11_L will be described in detail.

4 shows an embodiment of an adjustable reflector applied to the reflector module according to the present invention.

The left, middle and right sides of FIG. 4 show the shape seen from the inside, the shape seen from the side, and the shape seen from the outside of the control reflector, respectively. The control reflector includes a reflective body 111 that gradually increases in width along the extension direction; a locking wing 112 formed on one side of the reflective body 111 to be coupled to the base; a fastening hole 113 to which the fastening portion 122 of the adjustment clamp 12_K is coupled; and a coupling ring 114 to which the hook of the elastic flap is coupled. As shown on the right side of FIG. 4 , a contact inclined surface 111a inclined in the width direction may be formed on one side of the reflective body 111 . Such a contact inclined surface 111a may have a function of preventing a gap from being generated at a contact portion between adjacent control reflectors. The contact inclined surface 111a may have an appropriate structure according to the structure of the control reflector, and is not limited to the presented embodiment. The adjustment clamp 12_K may include a fixing block 121 fixed to the base and a semi-cylindrical fastening portion 122 integrally formed with the fixed block 121 and coupled to the fastening hole 113 . The control reflector may have an outwardly convex curved shape while extending from the fastening hole 113 in the direction of the coupling ring 114 , thereby preventing light from being dispersed to the outside and light distribution can be effectively controlled. And the inclination of such a control reflector can be adjusted by the rotation of the guide holder.

5 and 6 show an embodiment of a reflector control structure applied to the reflector module according to the present invention.

Referring to FIG. 5 , the base 13 includes a base body 131 having a circular band shape; a plurality of arrangement paths (132_1 to 132_L) formed along the inner circumferential surface of the base body 131; and fixing holes 133_1 to 133_L to which fixing pins for fixing each of the adjustment clamps are coupled. The guide holder 14 rotatably coupled with respect to the base 13 includes a guide body 141 having a circular band shape corresponding to the base body 131; A plurality of guide paths (142_1 to 142_L) formed along the inner circumferential surface of the guide body 141; and an engaging unit 143 formed along the edge of the guide body 141 . Each of the induction paths 142_1 to 142_L may form a linear path extending linearly along a tangent direction with respect to one point of the circular edge. And the rear surface of each adjustable reflector may be in contact with each linear path. By the rotation of the guide holder 14, the position at which the induction paths 142_1 to 142_L contact the adjustable reflector is changed and the adjustable reflector can be rotated inward or outward, and the arrangement paths 132_1 to 132_L are the adjustable reflectors A hook plate 15 may be coupled to the guide holder 14 , and the hook plate 15 is a plate body having a circular band shape corresponding to the guide body 141 . 151; and a plurality of fixing hooks 152_1 to 152_L formed on the plate body 151 to which one end of the elastic flap is coupled, rotated on the engaging unit 143 formed in the guide holder 14 A control unit may be coupled.

Referring to FIG. 6 , the rotation control unit includes a circular bar-shaped control knob 171 ; and a rotation induction unit to which one end of the adjustment knob 171 is coupled. The rotation induction unit may include an engaging block 172a having a cylindrical spur gear structure and a fastening block 172b extending from the engaging block 172a. A rim wall may be formed in the guide holder, and an engaging unit 143 capable of being rotated by engaging the engaging block 172a on the rim wall may be formed. An outer surface of the control reflector 11_K may be in contact with one of the induction paths 142_1 to 142_K. And as described above, as the engaging block 172a is rotated by the rotation of the adjustment knob 171, the guide holder 14 is rotated, and accordingly, the induction paths 142_1 to 142_K are in contact with the adjustment reflector 11_K. As the position is changed, the inclination of the control reflector 11_K may be adjusted, and thus the light distribution may be adjusted.

7 illustrates an embodiment of a structure in which a lighting area is controlled by an LED lighting device using a variable-type symmetrical reflector according to the present invention.

Referring to FIG. 7 , a plurality of control reflectors 11_1 to 11_L are continuously arranged adjacent to each other along a circle; LED module (EM) disposed in the center of the control reflector (11_1 to 11_L); and a guide holder 14 for guiding the plurality of adjustment reflectors 11_1 to 11_L to move in the circumferential direction, wherein the plurality of adjustment reflectors 11_1 to 11_L are moved along the guide holder 14 to determine the extension direction The inclination level is adjusted accordingly, thereby adjusting the light distribution.

An LED module EM in which a plurality of LED elements are symmetrically disposed may be disposed at the center of the base 13 , and the light emitted from the LED module EM is guided by the control reflectors 11_1 to 11_L to induce the first Illumination lights L11 and L12 may be formed. Each of the control reflectors 11_1 to 11_L may be maintained at a first inclination angle A1 with respect to the vertical reference plane VR that is perpendicular to the horizontal reference plane HR. The guide holder 14 may be rotated along the rotation direction R by the operation of the rotation control unit 17 to adjust the light distribution, and each of the control reflectors 11_1 to 11_L is at the second inclination angle A2. The slope can be adjusted. When the inclination is adjusted in this way, an illumination area by the second illumination lights L21 and L22 may be formed. The inclination angles A1 and A2 may be set to predetermined angles according to the usage environment of the lighting device, and thereby the same lighting device may be suitably used in different usage environments. In the presented embodiment, the illumination lights L11 to L22 are guided in a direction perpendicular to the ground, but the illumination lights L11 to L22 may be guided in various directions, and the present invention is not limited thereto.

Although the present invention has been described in detail with reference to the presented embodiments, 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. . The present invention is not limited by such variations and modifications, but only by the claims appended hereto.

11_1 to 11_L: adjustable reflector 12_1 to 12_L: adjustable clamp
13: base 14: guide holder
15: hook plate 16_1 to 16_L: elastic flap
17: rotation control unit
111: reflective body 112: catch wing
122: fastening portion 131: base body
132_1 to 132_L: placement path 133_1 to 133_L: fixing hole

Claims (7)

A plurality of control reflectors (11_1 to 11_L) arranged in a circle adjacent to each other, each extending along the light guide direction (11_1 to 11_L);
a base 13 to which one end of a plurality of control reflectors 11_1 to 11_L is coupled and an arrangement hole is formed in the central portion to place the LED module EM; and
a guide holder 14 rotatably disposed with respect to the base 13;
The guide holder 14 has a ring shape as a whole, and a plurality of linearly extending along a tangential direction with respect to one point of the circular rim to induce movement of each of the control reflectors 11_1 to 11_L along the inner circumferential surface. Induction paths (142_1 to 142_L) are formed,
The position at which the rear surfaces of the control reflectors 11_1 to 11_L are in contact with the induction paths 142_1 to 142_L, and the induction paths 142_1 to 142_L by the rotation of the guide holder 14 are in contact with the adjustment reflectors 11_1 to 11_L An LED floodlight module having a light distribution control structure using a variable-type symmetrical reflector, characterized in that the inclination angle of each of the control reflectors 11_1 to 11_L is adjusted while changing. The LED floodlight of claim 1, further comprising an adjustment clamp (12_1 to 12_L) for rotatably fixing a plurality of adjustment reflectors (11_1 to 11_L) to the base (13). module. The LED floodlight module of claim 1, further comprising elastic flaps (16_1 to 16_L) for maintaining the plurality of control reflectors (11_1 to 11_L) in a predetermined direction. The method according to claim 1, Each of the plurality of control reflectors (11_1 to 11_L) of the light distribution control structure using a variable type symmetrical reflector, characterized in that the width gradually increases along the direction of light induction and becomes a curved shape as a whole along the direction of extension LED floodlight module. delete The LED floodlight module of claim 1, further comprising a rotation adjustment unit (17) for rotating the guide holder (14). a plurality of control reflectors (11_1 to 11_L) continuously arranged adjacent to each other along a circle;
LED module (EM) disposed in the center of the control reflector (11_1 to 11_L); and
Includes a guide holder 14 for guiding a plurality of control reflectors (11_1 to 11_L) to move along the circumferential direction,
The guide holder 14 has a ring shape as a whole, and a plurality of linearly extending along a tangential direction with respect to one point of the circular rim to induce movement of each of the control reflectors 11_1 to 11_L along the inner circumferential surface. Induction paths (142_1 to 142_L) are formed,
The position at which the rear surfaces of the control reflectors 11_1 to 11_L are in contact with the induction paths 142_1 to 142_L, and the induction paths 142_1 to 142_L by the rotation of the guide holder 14 are in contact with the adjustment reflectors 11_1 to 11_L A lighting device, characterized in that the level of inclination along the extension direction of each of the control reflectors 11_1 to 11_L is adjusted while changing, thereby controlling light distribution.

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