KR930005310Y1 - Shade - Google Patents

Abstract

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Description

Reflective shade structure of lighting fixture

1 is a conventional reflection shade structure diagram.

2 is an exemplary view showing a glare zone by a conventional reflection shade.

3 is a reflection shade structure according to the present invention.

졔 4 degrees is a tangential angle of the reflecting surface with respect to the vertical line of the reflection shade of the present invention.

* Explanation of symbols for main parts of the drawings

1A: tubular base 1B: screw hole

1C-1E: Reflective surface 4: Fluorescent lamp

5: screw 6: lamp base

The present invention relates to the structure of the reflector of the ceiling luminaire, and in particular, to the reflection shade structure of the luminaire to improve the reflection efficiency as a low-brightness high reflection shade by improving the structure so that the light beam from the filament of the light source is not disturbed by the filament. It is about.

In general, since the light from the light source is often not suitable for the purpose of lighting as it is, the light fixture has a function of reflecting light, that is, exchanging light distribution of the light source, and fixing the light source or protecting the light source. will be.

In other words, this function can only be achieved by combining optical, electrical and mechanical functions. In particular, the reflector has been adapted to properly investigate the reflection phenomenon in exchanging light distribution of the light source.

Conventional lighting fixture reflector having such a function is made of a cylindrical shape in the outer direction as shown in the first drawing of Fig. 1, which is mainly used indoors using a metal hill lamp as a light source as shown in FIG. A socket 2 for electrical use is mounted on an aluminum reflector or an upper plate made of an iron plate, and a heat dissipation hole 3 is provided at the lower end of the socket to prevent overheating of the socket 2 and contamination of the reflective surface. ) Is formed by forming.

The reflective surface of the conventional reflector 1 is generally cylindrical in the central longitudinal section, whereby the visible light emitted from the filament is incident on the reflective surface and immediately illuminates the downward direction.

In other words, this is because light up to 0-90 ° is effectively reflected in the downward direction with respect to the vertical line with respect to the filament of the lamp.

Therefore, the light of more than 90 ° does not reflect effectively downward despite the high reflecting surface brightness, thereby reducing the lighting efficiency.

In addition, it is a condition that can be obtained in the shape of a reflection shade to remove glare (bad strong light in the field of view, glare), which causes discomfort to the human being and causes vision loss.

Therefore, in the normal line of sight, the light in the direction that falls within this field of view within the range of 30 ° in the vertical direction of the human line of view belongs to the glare range as in the second ridge.

However, such a conventional reflector structure does not consider optical characteristics in a portion close to the light source, and is generally formed to have a cylindrical shape, so that a glare phenomenon, which causes vision impairment and visual function deterioration, is generated, and the light source itself Interfering with the filament has a disadvantage of reducing the lighting efficiency.

Therefore, the present invention is to improve the shape of the reflection shade to solve the above-mentioned conventional problems, so that the light rays emitted from the filament of the light source does not interfere with the filament, it is possible to illuminate the lower direction with a low-brightness high reflection shade with extremely good efficiency It is an object to provide an improved reflection shade.

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

3 shows the present invention is a tubular base (1A) formed with a screw hole (1B) for fixing to the ballast (7), and a pair of fluorescent lamps (4) in the tubular base (1A) Two parabolic phases (1C) and (1D) having a curved shape to install a lamp base (5) and reflect the light source so as to be irradiated to the direct light of the light source from the fluorescent lamp (4). And a conical lower reflection surface 1E having a straight line extending therefrom.

Reference numeral 1 is a reflection shade body, and 6 is a screw.

Referring to Figure 4 the effect of the present invention configured as described above is as follows.

First, as shown in FIG. 3, the reflection shade 1 has an upper reflection plane 1C having an upper focal point F1 and a lower focal point F2, which are rotated outwardly in a parabolic shape, and the upper reflection plane 1C. ) Is connected to the lower side of the intermediate reflection surface (1D) in the shape of a rotation parabolic shape inwardly, and the lower reflection surface connected to the lower side of the intermediate reflection surface (1D) and conical in the downward direction ( 1E) is formed.

The reflection shade 1 has a tubular base 1A sized to closely surround the base 5 of the fluorescent lamp 4 for heat transfer contact thereon, and is formed in the side wall of the reflection shade 1. It is fixed to the ballast house 7 with the screw 6 through the hole 1B.

The upper focus F1 of the upper reflecting surface 1C is positioned near the plane P including the connecting line between the upper reflecting surface 1C and the intermediate reflecting surface 1D, and the lamp (near the upper focus F1) is positioned near the upper reflecting surface F1. 4) and filament (not shown) are located.

In addition, the position of the lower focus F2 is changed up and down by the size of the illumination range, and the reflection shades 1A-1E are integrally processed, and aluminum having good thermal conductivity is coated.

In more detail, that is, as shown in FIG. 3, most of the heat generated by the fluorescent lamp 4 is transferred to the lamp base 5, and the heat obtained from the lamp base 5 is transferred to the reflection shade base 1A. This heat is transmitted to the entire reflection shade 1 and spreads to the surrounding air.

When the light beam emitted from the filament is incident on the upper reflection surface 1C, the reflected light having high reflection surface luminance passes from the filament (upper focus F1) to the lower focal point F2 directly downward to move the downward direction of the luminaire. Illuminate.

This is due to the property of the rotated parabolic shape, and the light incident on the upper reflecting surface 1C and reflected by the property is illuminated so as not to interfere with the filament.

In addition, the connecting portion between the upper reflecting surface 1C and the lower reflecting surface 1E is such that the tangent is preferably about 5-7 degrees and 30 degrees with respect to the vertical line as in the fourth embodiment.

The tangent of the upper reflecting surface 1C is about 5-7 degrees with respect to the vertical line, which is smoothly connected to the upper reflecting surface 1C and at the same time excludes the cause of the reflected light glare on the upper part of the intermediate reflecting surface 1D. In order to be reflected to the filament side without being reflected downward.

Also, in the connection portion with the lower reflection surface 1E, if the connection is about 30 degrees with respect to the vertical line, if it is less than 30 degrees, the reflected light from the lower portion of the intermediate reflection surface 1D causes glare, 30 degrees is necessary.

In order to satisfy these conditions, the tip portion of the parabolic line was used as described above, and the lower reflective surface 1E reflected the reflected light of the intermediate reflective surface 1D once again to face downward, and the reflected light was constant. It also diffuses in the direction.

In addition, since the reflector 1 is plated with an aluminum alloy and deposited on aluminum with a purity of 99.5% or more on the reflecting surface, it is possible to reflect light rays extremely well.

For example, the reflectivity of the reflector is 65-70% for chromium plating, 80-85% for electrolytic polishing, 91-95% for aluminum deposition plating, and so on. Plating is used.

As described above, since the lamp base is configured to be in close contact with the reflection shade base, the heat generated from the lamp base is naturally emitted in the air because it is transmitted to the entire reflection shade through the reflection shade base, and the reflection shade diffuses the reflection. As a result, there is no glare, bright and even lighting is provided, and since three reflective surfaces are installed in succession, lighting efficiency can be better and energy saving using high reflectance (91-95%) can be achieved. Economic efficiency is greatly improved.

Claims (4)

A tubular base 1A having a screw hole 1B for fixing to the ballast housing 7 and a lamp base 5 for fixing a pair of fluorescent lamps 4 in the tubular base 1A are provided. Two parabolic phase intermediate reflecting surfaces 1C, 1D having a curved shape to reflect the light source so as to be irradiated to the direct light of the light source from the fluorescent lamp 4, and a conical lower portion having a straight line extending therefrom. A reflection shade structure of a luminaire, which is formed by a reflecting surface 1E. According to claim 1, wherein each reflecting surface is formed by connecting the upper reflection surface of the shape of the upper side from the upper side to the outer side, the middle reflection surface of the shape of the both sides, and the lower reflection surface of the conical shape in turn, and 5 with respect to the vertical line of the filament Reflector shade structure of a luminaire, characterized in that the angle is -7 degrees and 30 degrees. The reflector structure of a luminaire according to claim 1 or 2, wherein each reflecting surface is deposited by aluminum plating. The tubular base (1A) of claim 1, wherein the lamp base (5) is fixed in close contact with the tubular tubular base (1A), and the tubular base (1A) is formed in a square structure so as to absorb the generated heat of the fluorescent lamp (4) and diverge it into the air. Reflector shade structure of lighting fixture made with.