KR20080065951A - Fluorescent lamp mechanism with improved reflection efficiency - Google Patents

Abstract

The present invention relates to a fluorescent lamp device having improved reflection efficiency by expanding a reflecting surface, and the conventional fluorescent lamp device has a problem in that the effective reflecting area of light emitted from the fluorescent lamp is small so as not to effectively increase the illuminance of the fluorescent lamp.

Accordingly, in the present invention, when the fluorescent lamp body 100 and the fluorescent lamp 300 are built in the fluorescent lamp mechanism, the entire surface or a predetermined portion of the surface of the fluorescent lamp body 100 jig uneven surface 110 Forming a plurality of embossing (111) for each concave-convex surface 110 to increase the diffuse reflectance, and the reflection shade 200 in the form of jig-jag irregular surface of the reflecting surface inside the fluorescent light fixture body 100 By installing a plurality of embossing (211) for each concave-convex surface 210 of each reflecting shade 200 to increase the diffuse reflectance, the present invention is a fluorescent lamp within the limited inner surface of the fluorescent lamp body 100 The effective area reflecting the light of 300 is enlarged to increase the reflection efficiency, which can significantly reduce power consumption due to the remarkable increase in illuminance, which greatly increases the efficiency and reduces the power cost. Depending on the material because it does not use the rate in high-income high and achieve significant cost savings are large substitution effect on the reflectivity product that will be in effect nophil competitive price.

Description

Fluorescent lamp equipment which was improved reflection effciency by specular surface enlargement}

The present invention relates to a fluorescent lamp device with improved reflection efficiency by expanding the reflecting surface, and more particularly, it is possible to increase the reflectance by increasing the effective reflecting area as much as possible within the width range of the inner surface of the fluorescent lamp body. The present invention relates to a fluorescent lamp apparatus having improved slope efficiency by expanding a slope.

In general, large-scale light source areas such as offices, factories, or underground facilities in buildings use low-power, low-light and bright fluorescent lamps compared to other light sources to reduce power usage. In order to use it, a dedicated fluorescent lamp fixture must be installed.

Fluorescent lamps contain mercury vapor and some inert gas in a vacuum tube, and the tube itself emits light using gas discharge when insulation is generated when high pressure is applied to both the insulator or the tube.

That is, electrons emitted from the cathode fly to the anode by high pressure, and due to this high-speed motion of the electrons, the electrons get large kinetic energy and collide with mercury and inert gas in the tube during the flight. The kinetic energy of the electrons is transferred to the gas in the tube, the gas is excited and the electrons of the gas move to a higher energy level, and the excited electrons stay as much as Life Time and fall to the lower energy level. Emit energy equivalent to the car.

At this time, the emission wavelength is an ultraviolet region, which stimulates the fluorescent material coated on the inner wall of the tube to emit visible light. When the light is emitted, the tube exhibits negative resistance characteristics, and a large current flows. A ballast, which is a circuit, is needed.

Since the lights of these fluorescent lamps are extremely dazzling, there is a possibility that they will have a significant effect on the eyesight when looking straight for a long time. (LOUVER) may be installed, and a reflector with a high reflectance may be installed between the main body of the fluorescent lamp and the fluorescent lamp to improve lighting efficiency.

Here, the reflector of fluorescent lamps may use glass mirrors, or powder coating white paint on the inner surface, and other materials having high reflection efficiency have been applied.

However, the glass mirror is heavy, so the workability is bad by increasing the weight of the fluorescent lamp body, and the powder coating on the surface is considerably inferior in reflection efficiency.

Therefore, at present, most of them are formed by vacuum evaporation of a high purity aluminum thin film coating layer on a light aluminum plate, or by coating the coating layer on one side of the aluminum thin plate itself as a mirror.

However, since all reflecting surfaces form a flat plate, the efficiency of the luminous flux emitted directly above the fluorescent lamp cannot be effectively used for lighting of a lower surface such as a desk surface requiring lighting. By simply reflecting the light from the incandescent lamp, only the inner surface of the fluorescent lamp body and its surroundings are brightened, and the efficiency of increasing the illuminance around the bottom of the fluorescent lamp is considerably inferior.

In addition, since the width of the inner surface of the main body of the fluorescent lamp is fixed, the effective reflection area of the flat plate reflecting portion installed within the range cannot be limited, so that the illuminance of the fluorescent lamp cannot be effectively utilized.

Therefore, in recent years, the entire reflecting surface or a certain portion of the fluorescent lamp body is formed in the irregular surface of the jig zag or the irregular surface of the jig zag is formed on the reflective surface of the inner surface of the reflection shade installed separately so that the illumination of the fluorescent lamp can be effectively diffused. In this case, the illuminance was increased rather than flat, but there was a limit to increase the illuminance around the bottom of the fluorescent lamp.

In particular, when two or more fluorescent lamps are installed in one fluorescent lamp body, the illumination of polarized light irradiated from both fluorescent lamps cancels each other by photodynamic action, so that the illuminance is further reduced.

Accordingly, the present invention was developed in view of such a conventional problem, and an object of the present invention is to enlarge the effective reflecting area of the reflecting surface as much as possible within the width of a predetermined inner surface of the fluorescent lamp apparatus, including the lower portion of the fluorescent lamp immediately below the lower portion. The present invention provides a fluorescent lamp having improved reflection efficiency by expanding a reflecting surface to increase the illuminance of the light.

In order to achieve the object of the present invention, the present invention comprises a fluorescent lamp body and a fluorescent lamp embedded in the ceiling with a fluorescent lamp, the entire reflecting surface or a predetermined portion of the fluorescent lamp body is formed in the form of uneven surface of the zigzag Embossing of a large number of intaglio or embossing is formed on each uneven surface to increase diffuse reflectance. Also, a reflector having a reflective surface in the form of a jig-jag irregular surface is installed inside the main body of the fluorescent lamp. Or embossing embossed to increase diffuse reflectance.

The present invention is to increase the effective area reflecting the light of the fluorescent lamp as much as possible within the width of the inner surface of the fluorescent lamp main body to increase the reflection efficiency to a significant increase in illuminance on the desk surface that requires lighting Since the power consumption can be significantly reduced, the efficiency of power utilization and maintenance cost can be reduced.

In addition, the increase in efficiency by expanding the reflecting surface does not require the use of high reflectance materials, which are expensive in terms of material cost. Therefore, the substitution effect for expensive imported high reflectance products is large, and the cost reduction effect is high, thereby increasing price competitiveness.

Hereinafter, with reference to the accompanying drawings, the technical configuration and operation effects as a preferred embodiment that can effectively achieve the features of the present invention will be described.

1 is a view illustrating a state in which embossing is formed on the reflective surface of the fluorescent lamp body in a typical fluorescent lamp fixture according to the present invention, Figure 2 illustrates a state in which embossing is formed on a reflection shade separately installed in a typical fluorescent lamp body in accordance with the present invention 3 is an enlarged view of part "A" of FIG. 1 and part "B" of FIG. 2, and FIG. 4A is a diagram illustrating a state in which embossing is engraved on the uneven surface of the present invention. FIG. 4B. Is a view illustrating a state in which embossing is embossed on the uneven surface in the present invention.

In the present invention, the fluorescent light fixture body 100 and the fluorescent lamp 300 are formed in the fluorescent light fixture embedded in the ceiling, the entire surface or a predetermined portion of the surface of the fluorescent light fixture body 100 jig jagged surface 110 It is formed in the form, but each of the uneven surface 110 is characterized in that the diffuse reflectivity is increased by forming a plurality of intaglio or embossed embossing (111).

As such, the present invention forms the uneven surface 110 on the reflective surface of the fluorescent lamp body 100 so that the light emitted from the fluorescent lamp 300 expands the effective reflection area by the uneven surface 110. It is the same.

However, a feature of the present invention is to form a plurality of embossing 111 on the concave-convex surface 110 to further increase the effective reflecting area than the conventional to increase the roughness.

That is, the light emitted from the fluorescent lamp 300 is formed by forming a plurality of embossings 111 on the uneven surface 110 formed directly on the reflective surface of the fluorescent lamp body 100, as illustrated in the fluorescent lamp apparatus illustrated in FIG. 1. In addition to 110, the embossing 111 makes it possible to diffuse the reflection at various angles than the conventional one, so that the illuminance of the front, rear, left, and right as well as the bottom of the fluorescent lamp 300 can be brightened on the desk surface requiring illumination. It is.

In addition, as illustrated in FIG. 2, a plurality of embossings 211 are formed on the concave-convex surface 210 of the reflector 200 to fluoresce in the type of a fluorescent lamp that separately installs the reflector 200 on the fluorescent lamp body 100. As the light of the lamp 300 is diffusely reflected at various angles by the embossing 211 as well as the uneven surface 210, the illuminance of the fluorescent lamp 300 may be improved.

In other words, since the lamp light emitted from the fluorescent lamp 300 is diffusely reflected in various directions by the embossing 111 and 211 regardless of the fluorescent device as shown in FIG. 1 or the fluorescent device as shown in FIG. The light of the fluorescent lamp 300 within the width range is that the effective reflection area can be significantly expanded.

At this time, the height and the bending angle of the concave-convex surfaces 110 and 210 should be compatible with other equipment installed with the fluorescent light fixtures so that the size can be configured in various ways.

Here, the embossing 111 and 211 formed on the uneven surfaces 110 and 210 are diffusely reflected by the light of the fluorescent lamp 300 even if they are formed in an intaglio as shown in FIG. 4A or in an embossed form as in FIG. 4B. It can be done.

Intaglio or embossed embossing (111, 211) of the present invention is a regular representation in the circle in the drawings, but can be formed irregularly with various structural shapes.

The comparison table below is a comparison of the illumination intensity of the conventional fluorescent lamp fixture and the fluorescent lamp fixture of the present invention by position.

                  Illuminance by Measurement Position (LUX)     Remarks     Underneath      front      rear      Left      Ooh     Species      166     126      128     102     100    The present invention      180     132      131     108     104

As shown in the contrast table, the fluorescent lamp apparatus of the present invention, in which embossing is formed, not only directly underneath (directly) the fluorescent lamp, but also all the illuminances of the front, rear, left, and right sides are significantly increased compared to conventional fluorescent lamps without embossing on uneven surfaces. You can see.

5 to 8b illustrate a slim fluorescent light fixture having a low height to which the present invention is implemented, and this also includes an uneven surface 110 or a reflector 200 as shown in FIG. 6 of the slim fluorescent light fixture as shown in FIG. 5. By the embossing (111, 211) formed on the concave-convex surface 210 of the slim fluorescent lamp fixture separately installed) the light of the fluorescent lamp 300 in the conventional inner width range of the fluorescent lamp body 100 is Compared to the more diffused reflections and more efficient lighting, the shape of the irregularities should be formed at an obtuse angle significantly lower than that of fluorescent lamps of general height, so that the lighting efficiency is increased by embossing (111, 211). The increase effect is greater.

In particular, in the case of a ceiling-embedded slim fluorescent lamp that needs to be manufactured in a slim shape when designing and manufacturing a fluorescent lamp, the height of the concave-convex surface or the angle of bending should be remarkably obtuse. In this case, the embossing method is used to increase the surface area to enlarge the effect. I can keep it.

1 is a view illustrating a state in which embossing is formed on the reflective surface of the fluorescent lamp body in a typical fluorescent lamp according to the present invention.

2 is a view illustrating a state in which embossing is formed on the reflection shade installed on the fluorescent lamp body in a typical fluorescent lamp according to the present invention.

3 is an enlarged view of portion "A" of FIG. 1 and portion "B" of FIG.

Figure 4a is a diagram illustrating a state in which the embossed intaglio formed on the uneven surface in the present invention.

Figure 4b is a diagram illustrating a state in which embossing is embossed on the uneven surface in the present invention.

5 is a view illustrating a state in which embossing is formed on the reflective surface of the fluorescent lamp body in a slim fluorescent lamp according to the present invention.

6 is a diagram illustrating a state in which embossing is formed on the reflection shade installed in the fluorescent lamp body in the slim fluorescent lamp according to the present invention.

FIG. 7 is an enlarged view of portion “C” of FIG. 5 and portion “D” of FIG. 6;

8A illustrates a state in which embossing is engraved on an uneven surface in a slim fluorescent lamp according to the present invention.

8B is a view illustrating a state in which embossing is embossed on the concave-convex surface in the slim fluorescent lamp according to the present invention.

Explanation of symbols for main parts of the drawings

100: fluorescent lamp body 110, 210: inclined surface

111,211: Embossing 200: Reflective shade

300: lighting lamp

Claims (2)

In constructing a luminaire that is embedded in the ceiling by the fluorescent lamp body 100 and the fluorescent lamp 300, The entire reflecting surface or a predetermined portion of the fluorescent lamp body 100 is formed in the form of the uneven surface 110 of the zigzag, but a large number of intaglio or embossed embossings 111 are formed on each uneven surface 110 to increase the diffuse reflectance. Fluorescent lamp apparatus, the reflection efficiency is improved by expanding the reflection surface, characterized in that. The method of claim 1, Install a reflector 200 in the form of a concave-convex surface 210 of the zig-zag with a reflecting surface inside the fluorescent lamp body 100, but a plurality of intaglio or embossing embossing (211) for each concave-convex surface 210 of each reflecting shade 200 A fluorescent lamp apparatus having improved reflection efficiency by expanding a reflecting surface, characterized by increasing the diffuse reflectance by forming a).

Images