KR102158006B1 - Lighting apparatus - Google Patents

Abstract

The present invention relates to a lighting fixture and, more specifically, to a lighting fixture, which can be used for indoor lighting of a building by controlling a traveling direction of light emitted from an internal light emitting means with a lens and a reflector. According to the present invention, a lighting required for broadcasting or performance can be set to a desired direction and angle, an installation angle of a housing can be easily adjusted, and light emitted from a LED can be concentrated and illuminated in one place. The lighting fixture comprises: a housing (102); a control panel (108); a heat dissipation plate (110); a lens bracket (114); a PCB (116); a lens (118); one pair of reflector fixing wings (120); and a reflector (122).

Description

Lighting fixtures{LIGHTING APPARATUS}

The present invention relates to a lighting luminaire, and more particularly, to a lighting luminaire that can be used for indoor lighting of a building by adjusting the traveling direction of light emitted from an internal light emitting means with a lens and a reflector.

In general, several lighting devices are installed on indoor stages of various performance halls and broadcasting stations. In order to highlight the stage and performance, such lighting fixtures are provided in various forms, not only in color and brightness, but also in different widths.

Therefore, since conventional lighting fixtures provide different straightness or expandability of light depending on the width of the light, that is, the distance between the lens and the light source, when installing it on the stage, it is necessary to prepare an appropriate lighting lamp, and also the appropriate position or distance. There is an inconvenient problem to find and install.

In addition, as for lighting fixtures, an adjustment plate is installed on the lens rim to adjust the width or shape of the light by opening or closing it. Since most of the conventional adjustment plates are fixed on the lens rim, it is very necessary to replace it with another or change the installation direction. There is an uncomfortable problem.

KR 20-2014-0002728 U KR 20-2013-0001107 U

The present invention for solving the above-described problem is provided with a lens for diffusing light emitted from a light source in a certain direction inside a housing, and a reflector for reflecting light emitted from the lens and proceeding to the front, and bent by a certain angle. An object of the present invention is to provide a lighting fixture that allows light to proceed in a desired direction by arranging a reflector in a state.

The present invention conceived to solve the above problems is a lighting fixture that emits light for lighting, and the side portion has a trapezoidal shape with a narrow upper surface and a wide bottom surface, and a tempered glass window 104 that emits light is installed at the front portion. A housing 102; A control panel 108 installed in the housing 102 to control an operation of a lighting fixture; A heat sink 110 installed on the rear surface of the housing 102 to cool heat; A lens bracket 114 installed below the inside of the housing 102; A PCB 116 installed on the lens bracket 114 and controlling current to emit light; A transparent lens (118) coupled to the upper surface of the PCB (116) to diffuse or refract light emitted from the PCB (116); A pair of reflective plate fixing wings 120 installed on the left and right sides of the upper interior of the housing 102; A reflector 122 installed between the pair of reflective plate fixing wings 120 and reflecting light emitted from the lower lens 118 and proceeding upward to advance to the tempered glass window 104 at the front side; Include.

The PCB 116 comprises a substrate 116a on which circuits and devices are mounted, an LED 116b installed on the substrate 116a to emit light, and an electric circuit 116c for converting and supplying current. To do.

The lens 118 is formed on the upper surface of the diffusion part 118a formed in a trapezoidal shape of the upper light lower narrow, the flange 118b having a relatively larger area, and the upper surface of the flange 118b. It is formed in the form of an arch and characterized in that it consists of an uneven diffusion portion (118c) to allow light to spread.

The reflective plate 122 is manufactured in a form in which a rectangular metal plate is divided into a plurality of bent portions 122a, each bent portion 122a is bent in one direction, and the left and right sides of the plurality of bent portions 122a Part of the distal end is characterized by forming an insertion piece 122b configured to extend longer than other bent portions 122a.

An insertion groove (120b) is formed in the pair of reflector fixing wings (120), and insertion pieces (122b) formed at left and right ends of the bent portion (122a) are inserted and fixed to the insertion groove (120b). do.

According to the present invention, lighting required for broadcasting or performance can be set to a desired direction and angle, the installation angle of the housing can be easily adjusted, and the light generated from the LED can be concentrated and illuminated in one place. .

1 is a perspective view showing the structure of a lighting fixture according to an embodiment of the present invention.
2 is a front view showing the front structure of the lighting fixture.
3 is a side view showing a side structure of a lighting fixture.
4 is a plan view showing a plan structure of a lighting fixture.
Figure 5 is a side cross-sectional view showing the arrangement of the interior of the lighting fixture.
6 is a perspective view showing an arrangement structure of a lens and a reflector.
7 is a perspective view showing a coupling structure of a reflector fixing wing and a reflector.
8 is a side cross-sectional view showing a bending angle of the reflector.
9 is an exploded perspective view showing a coupling structure of a PCB and a lens.
10 is a front view showing a coupling structure of a PCB and a lens.
11 is a side cross-sectional view showing a path through which light moves in a lens.
12 is a side cross-sectional view showing a path through which light is reflected and moved from a reflector.

Hereinafter, a "lighting lamp" according to an embodiment of the present invention will be described with reference to the drawings.

1 is a perspective view showing the structure of a lighting fixture according to an embodiment of the present invention, Figure 2 is a front view showing the front structure of the lighting fixture, Figure 3 is a side view showing the side structure of the lighting fixture, Figure 4 is a lighting fixture A plan view showing a planar structure, FIG. 5 is a side cross-sectional view showing an arrangement state inside a lighting fixture, FIG. 6 is a perspective view showing an arrangement structure of a lens and a reflector, FIG. 7 is a perspective view showing a combination structure of a reflector fixing wing and a reflector, and FIG. A side cross-sectional view showing a bending angle of a silver reflector, FIG. 9 is an exploded perspective view showing a combination structure of a PCB and a lens, FIG. 10 is a front view showing a combination structure of a PCB and a lens, and FIG. 11 shows a path through which light moves from the lens. A side cross-sectional view, FIG. 12 is a side cross-sectional view showing a path through which light is reflected and moved from a reflector.

The lighting luminaire 100 of the present invention is installed on an indoor stage to emit light of various colors and brightness, and thus is configured as a device used for purposes such as photographing images or performing performances.

The lighting fixture 100 of the present invention includes a means for emitting light in the interior of the housing 102, a means for concentrating or diffusing light, a means for reflecting light and directing it to the front. In addition, heat dissipation means for effectively discharging heat generated from the light emitting means or the power supply device may be further included.

The housing 102 constituting the body of the lighting fixture 100 of the present invention, as shown in Figs. 1 to 4, forms a receiving space of a certain volume, and is provided with a transparent window to allow light to radiate.

In general, the housing 102 is made of a metal material such as aluminum having high heat transfer efficiency, but in some cases, a synthetic resin material may be used.

The housing 102 has a trapezoidal shape at a side portion and an open front portion. A tempered glass window 104 is installed in the open opening of the front. The tempered glass window 104 is made of a glass material having high heat resistance so as not to be deformed or damaged even by high temperature heat, and is made of a transparent material to facilitate the passage of light. In some cases, it may be made of a translucent material or glass of a color-added material.

A preferential treatment 106 that is rotatably coupled to the side of the housing 102 is installed. The preferential treatment 106 is a fixing means in the shape of a U, and is rotatably coupled to both sides of the housing 102. In a state in which the preferential treatment 106 is coupled to a separate fixing device, the irradiation angle of light can be adjusted by rotating the housing 102 within a certain angle range.

A fixing handle 112 is installed at a portion where the preferential treatment 106 is connected to the housing 102 so that the housing 102 can be selectively fixed.

A control panel 108 for controlling the operation of the lighting fixture 100 may be installed at the front or side of the housing 102. The control panel 108 may be provided with a switch that can control the on/off of the lighting fixture 100, brightness, color, special effects, and the like.

A heat sink 110 is attached to the rear portion of the housing 102. The heat sink 110 is made of a material such as aluminum or copper having high thermal conductivity, and several thin plates are attached at intervals so that heat generated from the lighting luminaire 100 is quickly dissipated. In some cases, forced cooling means such as water cooling may be applied.

The side portion of the housing 102 of the present invention has a trapezoidal shape, and is manufactured in the form of an upper narrow beam with a narrow upper surface and a wide lower surface. And after the light emitted from the light emitting means installed on the bottom rises upward and is reflected, it is configured to be emitted to the outside through the front part.

As shown in FIG. 5, a light emitting means, a diffusion means, and a reflecting means are provided in the interior receiving space of the housing 102.

A lens bracket 114 is installed below the inside of the housing 102. The lens bracket 114 may have a flat plate shape or a box shape provided with a space in which the lens 118 is accommodated. In the drawings of the present invention, it is described that the PCB 116 and the lens 118 are attached to the flat plate, but the shape may be different.

A PCB 116 is installed on the lens bracket 114. The PCB 116 is provided with a circuit for controlling current and a means for emitting light. In the present invention, an LED or an OLED is used as a light emitting means.

A lens 118 is coupled to the upper surface of the PCB 116. The lens 118 evenly diffuses the light emitted from the PCB 116 or refracts it in a certain direction to emit light in a desired shape. The lens 118 is made of transparent glass or synthetic resin, and is constructed so that the cross-sectional area increases as it rises from the bottom to the top so that the light can gradually diffuse.

A pair of reflective plate fixing wings 120 are installed on the left and right sides of the upper inside the housing 102. The reflective plate fixing wing 120 is made into a flat plate shape that is flat and elongated downwards and upwards, and is disposed so that the planes face each other from the left and right.

A reflector 122 is installed between the pair of reflective plate fixing wings 120. The reflective plate 122 is manufactured in a rectangular shape, and each of the left and right edges is fixed to the reflecting plate 122 disposed on the left and right. The reflector 122 is manufactured by bending a flat metal plate by a predetermined angle at regular intervals. The reflector 122 is disposed above the area in which the lens 118 is installed inside the housing 102 and is disposed to bend toward the front portion of the housing 102.

As shown in FIG. 5, since the direction in which the reflective plate 122 is bent is toward the front portion of the housing 102, the light that has passed through the lens 118 is reflected to the reflecting plate 122 and the front portion of the housing 102 is You can proceed towards.

6 and 7 illustrate the structure of the reflector fixing wing 120 and the reflector 122 in detail.

The flat plate portion 120a of the reflector fixing wing 120 is made of a flat metal plate, and is made of a rectangular shape that is relatively long in the downward and upward direction. However, the shape of the flat plate portion 120a of the reflector fixing wing 120 may be made into a triangle or other polygon.

A plurality of insertion grooves 120b spaced apart from each other in the upper and lower direction are formed in the flat plate portion 120a.

The reflector 122 is made of a material such as stainless steel, aluminum, mirror, or metal film having high light reflection efficiency. The body of the reflective plate 122 divides the flat plate into a plurality of bent portions 122a, and is configured to have a concave shape as a whole by bending each of the divided bent portions 122a in one direction. The width and the bent angle of the bent portion 122a may be constant, but may be configured to increase or decrease according to a certain rule.

The flat plate forming the plurality of bent portions 122a is a rectangular metal plate, and the left and right end portions of each bent portion 122a have the same length, but the lengths of some portions are configured to extend longer than other portions. The portion protruding to the left and right sides of the bent portion 122a is relatively large in length to the left and right constitutes the insertion piece 122b. The insertion piece 122b is a part protruding left and right from the body of the rectangular bent portion 122a, and the insertion piece 122b is inserted and fixed in the insertion groove 120b formed in the reflector fixing wing 120. To this end, the size and shape of the insertion piece 122b, the spaced distance, etc. are manufactured to be the same as the size and shape of the insertion groove 120b, the spaced distance, and the like.

If necessary, a locking jaw is formed so that the insertion piece 122b does not easily fall out of the insertion groove 120b, or the end portion of the insertion piece 122b can be folded so that the reflection plate 122 is not separated from the reflection plate fixing wing 120. It is also possible to avoid it.

The reflective plate 122 is characterized in that one flat metal plate is bent in one direction at regular intervals or according to a predetermined rule to form a shape similar to a curved surface. As shown in FIGS. 6 and 7, a line indicated by a dotted line on the flat plate means a boundary line in which the bent portion 122a is folded.

Meanwhile, as shown in FIG. 8, the bent portion 122a formed on the reflective plate 122 is manufactured in a state that is bent by a predetermined angle with respect to the adjacent bent portion 122a. In addition, the width of the bent portion 122a may also be changed according to the use condition or size of the lighting fixture 100.

The reflective plate 122 is disposed so that the plurality of bent portions 122a are connected from the bottom to the top in the housing 102. The reflector 122 is fixed to the rear side of the tempered glass window 104 around the lens 118 that emits light. In addition, the bent portion 122a is bent stepwise to face the front portion of the tempered glass window 104 while facing upward from the bottom. Accordingly, the light emitted upward from the lens 118 disposed under the housing 102 may hit the reflector 122 and be reflected, thereby proceeding toward the front portion of the lighting fixture 100.

The bent portion (122a) is installed at a lower portion close to the lens 118, and the upper portion is installed at a position spaced upward from the lens 118. The width of the bent portion 122a may be constant, but in the present invention, the width is configured to gradually increase from the bottom to the top.

As shown in Fig. 8, the width of the bent portion 122a is 15.6525 mm at the bottom and 32.2 mm at the top. Such a number may vary depending on the environment in which the lighting device is used, and the same technical effect can be achieved if the width is gradually increased from the bottom to the top.

Also, the size of the bent angle gradually decreases. In FIG. 8 of the present invention, the angle formed by the first bent portion 122a and the second bent portion 122a at the bottom is set to be 174°, and the angle gradually increases to 175°, 176°, 177°, 178 It was configured to increase to °. A smaller angle between two adjacent bent portions 122a means more bending, and a larger angle means closer to the plane. Accordingly, it can be seen that the reflector 122 of the present invention is bent slightly closer to the plane from the bottom to the top.

Since light is emitted from the lower lens 118 upward, the area to which the light touches increases as it goes upward. Accordingly, by increasing the width of the bent portion 122a upwardly, light can be reflected and refracted to the same extent.

In addition, since the difference in the angle at which the light goes upward becomes smaller, the light is reflected and refracted to the same degree even if the bending angle of the bent portion 122a is gradually decreased.

Meanwhile, a characteristic shape and structure of the lens 118 are shown in FIGS. 9 and 10.

The lens 118 of the present invention is installed on the upper surface of the PCB 116. The PCB 116 includes a substrate 116a on which circuits and devices are mounted, an LED 116b installed on the substrate 116a to emit light, and an electric circuit 116c for converting and supplying current. In addition, a structure for protection and heat dissipation of the electric device may be further added. The LED 116b installed on the substrate 116a is installed in contact with or close to the bottom surface of the lens 118.

The lens 118 is made of glass or synthetic resin made of a transparent material, and refracts light incident from the lower LED 116b to an appropriate angle and direction to emit uniform light.

The lens 118 is formed in the form of an arc on the upper surface of the diffuser 118a and the upper surface of the diffuser 118a and has a relatively wider area and the upper surface of the flange 118b. It consists of an uneven diffusion portion (118c) to allow light to spread evenly.

The diffusion unit 118a has a trapezoidal shape in both the front and the side surfaces, and is manufactured so that the cross-sectional area in the traveling direction increases from the bottom to the top, so that the light can gradually spread and proceed upward. Therefore, if light is emitted from the center of the bottom of the diffusion unit 118a, when reaching the upper flange 118b as shown in FIG. 11, the light is uniformly spread over the entire flange 118b or the difference in the amount of light is minimized. Light can be emitted in the state.

The uneven diffusion portion 118c is manufactured to protrude upward in an arc shape toward the left and right direction of the diffusion portion 118a from the upper surface of the flange 118b. In addition, it is manufactured such that two or more irregularities are formed on the surface in the front-rear direction of the diffusion part 118a. Each uneven-shaped curved surface serves to disperse the light once again, allowing the light to be uniformly irradiated on a wide surface.

In the lighting fixture 100 of the present invention having such a configuration, the light emitted from the lower LED 116b is diffused while passing through the lens 118, and is reflected by the reflective plate 122 inside the housing 102. It is discharged to the outside through the negative tempered glass window 104. When the color of the LED 116b is arranged differently or the lens 118 is replaced with a color added, various color effects may be produced.

Although preferred embodiments of the present invention have been described above with reference to the accompanying drawings, the technical configuration of the present invention described above is another specific form without changing the technical spirit or essential features of the present invention by those skilled in the art. It will be appreciated that it can be implemented with. Therefore, the embodiments described above should be understood as illustrative and non-limiting in all respects, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description, and the meaning and scope of the claims and All changes or modified forms derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

100: lighting fixture 102: housing
104: tempered glass window 106: preferential treatment
108: control panel 110: heat sink
112: fixed handle 114: lens bracket
116: PCB 118: lens
120: reflector fixing wing 122: reflector

Claims (5)

As a lighting fixture that emits light for lighting,
The side portion is a trapezoidal shape with a narrow upper surface and a wide bottom surface, and a housing 102 in which a tempered glass window 104 for emitting light is installed at the front portion;
A control panel 108 installed in the housing 102 to control an operation of a lighting fixture;
A heat sink 110 installed on the rear surface of the housing 102 to cool heat;
A lens bracket 114 installed below the inside of the housing 102;
A PCB 116 installed on the lens bracket 114 and controlling current to emit light;
A transparent lens (118) coupled to the upper surface of the PCB (116) to diffuse or refract light emitted from the PCB (116);
A pair of reflective plate fixing wings 120 installed on the left and right sides of the upper interior of the housing 102;
A reflector 122 installed between the pair of reflective plate fixing wings 120 and reflecting light emitted from the lower lens 118 and proceeding upward to advance to the tempered glass window 104 at the front side; Includes,
The reflective plate 122 is manufactured in a form in which a rectangular metal plate is divided into a plurality of bent portions 122a, and each bent portion 122a is bent in one direction,
Some of the left and right end portions of the plurality of bent portions 122a form an insertion piece 122b configured to extend longer than the other bent portions 122a,
Insertion grooves 120b are formed in the pair of reflective plate fixing wings 120, and insertion pieces 122b formed at left and right ends of the bent portion 122a are inserted and fixed in the insertion grooves 120b,
The plurality of bent portions 122a are configured to increase in width while going upward spaced apart from the bottom adjacent to the lens 118,
The plurality of bent portions (122a) is configured to decrease the bent angle from the bottom to the top, and the angle formed by the two adjacent bent portions (122a) is increased from the bottom to the top, the lighting fixture. The method of claim 1,
The PCB 116 comprises a substrate 116a on which circuits and devices are mounted, an LED 116b installed on the substrate 116a to emit light, and an electric circuit 116c for converting and supplying current. With lighting fixtures. The method of claim 1,
The lens 118 is a diffusion part 118a formed in a trapezoidal shape of the upper light lower narrow, a flange 118b formed on the upper surface of the diffusion part 118a and having a relatively larger area, and the upper surface of the flange 118b It is formed in the form of an arch, characterized in that consisting of an uneven diffusion portion (118c) to allow light to spread out, lighting fixtures. delete delete

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