KR100823042B1 - Lighting fixtures for electrodeless fluorescent lamp - Google Patents

Abstract

A lighting device is provided to raise a safety level of a driver by decreasing dazzling of driver eyes by preventing light from a vehicle running in the opposite direction from being delivered to the driver eyes. A refractive unit(101) has a hemispherical cross-section and is made of a transparent material. Plural prisms are formed on an inner surface of the refractive unit. An opening is formed on the refractive unit. A housing has a hemispherical structure with an opening formed at a lower portion thereof, such that the housing is symmetrical with respect to the refractive unit. A reflective plate is formed on an inner surface of the housing. A round electrodeless fluorescent lamp is fixed on a lamp holder, which is bolt-coupled with a lower surface of the housing. The housing is bolt-coupled with the refractive unit, such that the openings are mated with each other. A ballast box(110) is bolt-coupled with the other sides of the refractive unit and the housing and fixed at both ends of an arm, which is bent at a lighting pole. Ballast supplies a start voltage to the electrodeless fluorescent lamp and restricts a current. The inner surface of the refractive unit is divided into plural sections. Plural prisms are protruded from the respective sections, such that the light from the electrodeless fluorescent lamp is refracted to ground. Angles of the triangular prism are different from each other in the respective portions of the inner surface.

Description

Lighting fixtures for electrodeless fluorescent lamp

The present invention relates to a luminaire dedicated to electrodeless fluorescent lamps, and more particularly, to electrodeless fluorescent lamps that suppress light glare by implementing light distribution in a cutoff type with high light efficiency for electrodeless fluorescent lamps having a relatively larger size than general fluorescent lamps. Relates to a lamp-only luminaire.

In general, lighting fixtures such as street lamps are provided at regular intervals in the roadway on which the vehicle runs and in India where people pass, so as to facilitate the passage at night and to easily identify the pia.

That is, during the day when the surrounding identification is easy, the driver of the car driving at high speed can easily identify lanes and other driving vehicles, but in the case of weather and weather where the visibility is unstable even during the day, or at night when the surrounding identification is difficult Since road users, including drivers, cannot easily identify objects, lighting fixtures should be installed on roadways and sidewalks so that objects can be easily identified and passed safely.

In addition, in the case of a tunnel or an underground roadway, light cannot be turned on regardless of day or night, so a lighting device is required to illuminate the interior. There was a problem in that the light emitted from the headlights of the vehicle running on the side and the light fixtures installed around the road enters the eye and confuses the clock, thereby making it difficult to secure a safe clock.

The above-described conventional lighting fixtures should be designed to illuminate the ground as shown in Figure 1, most of the light source for lighting is used because it is not possible to provide a light suitable for the purpose and requirements used by only the light source is emitted from all directions In order to provide lighting that meets the objectives and needs, the optical design must control the light to achieve proper light distribution.

That is, in the conventional road lighting fixtures, such optical design parts are insufficient, so the size of the lighting fixtures tends to increase in proportion to the size of the lamp. Especially, in the case of the electrodeless fluorescent lamp, the lamp size is relatively larger than that of the general fluorescent lamp. Slim and compact optical design is very difficult and it is difficult to limit the glare.

As shown in FIG. 1, when the light is to be emitted to the ground, the street lamp poles are fixed upright in a straight line up to a certain height, and the light fixtures are installed at the ends of the arms by combining the arms in one direction from the ends of the poles. .

At this time, even if the lighting fixture is installed on the pole installed arm as described above, the light emitted from the lighting fixture is to be reflected toward the ground and the wider light distribution should be formed so that the distance of the street lamp can be widened, accordingly, In the conventional street lamps and lighting fixtures, the light generated by the light source is simply designed so that the light emitted from the light emitting source can be widely projected on the ground. As it is exposed as it is, the problem of making it difficult to secure the clock due to the effects of glare and the like still remains.

In addition, since the electrodeless fluorescent lamp cannot guarantee its characteristics, in particular, a long lifetime by heat, it is essential to apply a luminaire that solves this problem.

The present invention devised to solve the above problems, the desired light distribution can be realized by the light generated from the light emitting source, and at the same time to illuminate only the desired target portion to the one-way lane of the light of the electrodeless fluorescent lamp It cuts the light interference by controlling the light source so that the back light does not diverge behind the sidewalk, and cuts light distribution with high light efficiency for the electrodeless fluorescent lamp which is relatively larger than general fluorescent lamp. It is possible to realize higher illumination and uniform illumination and light distribution by suppressing the induction of clarity, and since the characteristics of electrodeless fluorescent lamps are greatly affected by heat, the lamp is mounted directly on the luminaire housing, and thus the lamp is primarily The heat emitted from the heat is released to the outside and the lamp and the ballast are designed and manufactured in an independent structure, Minimize interference with the electrodes to provide a non-free electrodes for long life fluorescent lamps to ensure maximum fluorescent lamp luminaire has a private purpose.

The above object has a semi-cylindrical cross-sectional structure, the entire surface is made of a transparent material so that light is transmitted, a plurality of prism for refracting light is formed on the inner surface, the refraction portion formed in the upper portion and ; It has a semi-cylindrical structure with an opening formed in the lower portion so as to be symmetrical with the refraction portion, a reflecting plate for reflecting light on the inner surface is mounted, the round electrodeless fluorescent lamp is fixed to the lamp holder bolted to the lower surface, A housing bolted to the refracting portion such that the openings abut against each other; And a ballast coupled to the other end of the refracting portion and the housing, coupled to an end of the arm that is bent or refracted by the street lamp pole, and a ballast containing a ballast for limiting the supply of current and current to the electrodeless fluorescent lamp. It is achieved by a luminaire dedicated for an electrodeless fluorescent lamp.

In addition, a first section of the inner surface of the refracting portion from one side end to a predetermined length toward the other side has a plurality of prisms protruding in a triangle to cause the light emitted from the electrodeless fluorescent lamp to be refracted to the ground, and downward from the prism. The inner angle of the protruding part is 95 ° to 90 °, the inner side of one side is 40 ° to 35 °, and one side of the protruding part is formed relatively longer than the other side of the protruding part, and is formed from the other end of the first section. In the second section up to a certain length extending in the other direction, a plurality of prisms are formed in a triangular prism that causes the light emitted from the electrodeless fluorescent lamp to be refracted to the ground. ° ~ 85 °, the inner angle of one side is 35 ° ~ 30 °, forming one side of the protruding portion relatively longer than the other side of the protruding portion, the other side direction from the other end of the second section In the third section up to a predetermined length, a plurality of prisms are formed in a triangle to project light emitted from the electrodeless fluorescent lamp into the ground, and the inner angle of the projecting portion projecting downward from the prism is 85 ° to 80 °, the inner angle of one side is 30 ° to 25 °, and one side of the protruding portion is formed to be relatively longer than the other side of the protruding portion, and is formed from the other end of the third section to a predetermined length extending in the other direction. In section 4, a plurality of prisms are formed to protrude into a triangle, which causes the light emitted from the electrodeless fluorescent lamp to be refracted to the ground, and the inner angle of the protruding portion protruding downward from the prism is 80 ° to 75 °, 25 ° to 20 °, and one side of the protruding portion is formed to be relatively longer than the other side of the protruding portion, and the fifth section from the lower portion to the lower portion of the fourth portion diverges from the electrodeless fluorescent lamp. The prism that causes light to be refracted to the ground is formed into a triangle, and the inner protrusion of the protrusion protruding downward from the prism is 85 ° to 80 °, and the inner angle of one side is 25 ° to 20 °. It is preferable that one side is molded relatively longer than the other side of the protruding portion.

As described above, the present invention obtains the light distribution required by the existing street lamps and security lighting fixtures, and enables the design of the installation height and the slim and lightweight lighting fixtures, thereby reducing the thickness of the pole, thereby reducing the cost of the facility. By using the refraction of light caused by prism, light distribution can be formed to prevent the light from being exposed to the driver of the car driving in the opposite lane, which eliminates the difficulty of securing the clock due to glare and induces safe driving. And it has the effect of minimizing the influence of light interference due to the back light.

Figure 2 is an exploded perspective view showing the overall configuration of the luminaire according to the present invention, Figure 3 is a cross-sectional view showing the structure of the present invention, Figure 4 is a state in which the bend and the housing according to the present invention is coupled 5 is a perspective view illustrating a light distribution structure by a refraction part in which a prism is formed according to the present invention, and FIG. 5 b illustrates a prism instead of the refraction part of the present invention. FIG. 6 is a view illustrating a light distribution structure of a lighting device that is implemented when a general transparent body is not used, and FIG. 6 is a view illustrating a state in which a lighting device according to the present invention is installed on a street lamp pole.

As shown in FIG. 2, the refracting portion 101 is made of a transparent material on the entire surface, and has a semi-cylindrical cross section, one of which is open at one side, and the housing 102 is opaque to which light is not transmitted. It is made of one material, the other side is an open structure, these refracting portion 101 and the housing 102 has a structure that is bolted to each other facing each other as shown in FIG.

Here, the electrodeless fluorescent lamp 103 is fixed to the lower surface of the housing 102 by the lamp holder 104, where the lamp holder 104 is a 'U' shaped lamp holder for mounting a cylindrical object As a 104, the cylindrical body of the electrodeless fluorescent lamp 103 is inserted into one end and the other end of the electrodeless fluorescent lamp 103, and is inserted into the accommodating groove 104a of the lower round groove shape, and the upper part of the housing. By being bolted and fixed to the lower surface of the 102, the electrodeless fluorescent lamp 103 can be fixedly coupled to the housing 102.

That is, when the housing 102 and the refracting portion 101 are coupled to each other, a reflecting plate is mounted on the inner surface of the housing 102, the electrodeless fluorescent lamp 103 is fixed to the lower surface of the reflecting plate, and then the housing ( The electrodeless fluorescent lamp 103 may be embedded inside the housing 102 and the refracting portion 101 by bolting the 102 and the refracting portion 101 as shown in FIG. 2.

The bolting method of the housing 102 and the refracting portion 101, the open portion of the housing 102 and the refracting portion 101 to face each other, the first through hole 105 formed in the housing 102 The fixing screw 107 may pass through the fixing screw 107 to allow the fixing screw 107 to pass through the second through hole 106 formed in the refraction portion 101, and then to be fastened to the nut 108. Instead of the through hole 106, a screw hole (not shown) is formed, and the fixing screw 107 penetrating the first through hole 105 formed in the housing 102 is fastened to the screw hole formed in the deflection part 101. It may be.

That is, the first through hole 105 and the second through hole 106 are formed to correspond to the housing 102 and the refraction portion 101, respectively, so that the housing 102 and the refraction are fixed with the fixing screw 107 and the nut 108. The part 101 may be coupled to each other, and the first through hole 105 is formed in the housing 102 and the screw hole is formed in the corresponding refraction portion 101 so that the refraction portion 101 is formed only by the fixing screw 107. ) And the housing 102 can be fixed.

As such, the method of coupling the housing 102 and the refraction portion 101 is a general technical idea, and thus various modifications may be made without restricting the means thereof.

Here, as shown in FIG. 3, the inner surface of the refraction portion 101 is protruded into a plurality of prisms 109 that refracts light inward, and the prism 109 is fixed from the top to the bottom. As the angles protrude differently for each section, a light distribution structure as shown in FIG. 5A is formed.

That is, after dividing the first section (S1) to the fifth section (S5) from one end of the inner surface of the refracting portion 101 toward the other side, in the first section (S1) to the fifth section (S5) By varying the angle of refraction of the light, as shown in FIG. 3, the inner angle of the triangle of the protruding portion may be gradually decreased toward the other side, so that the refracted light may appear as light distribution as shown in FIG. 5A.

Preferably, as shown in FIG. 3, in the first section S1 up to a predetermined length, a plurality of prisms 109 protruding in a triangle to cause the light emitted from the electrodeless fluorescent lamp 103 to be refracted to the ground. It is formed, the inner angle of the projecting portion projecting downward from the prism 109 is 95 ° ~ 90 °, the inner angle of one side is 40 ° ~ 35 °, the one side side (a) of the protrusion portion is the other side ( to be molded longer than b).

The second section S2 from the other end of the first section S1 to a predetermined length extending in the other direction has a plurality of prisms that cause light emitted from the electrodeless fluorescent lamp 103 to be refracted to the ground. 109 is formed in a triangular protrusion, the inner angle of the protrusion projecting downward from the prism 109 is 90 ° ~ 85 °, the inner angle of one side is 35 ° ~ 30 °, one side of the protrusion (a) To be formed relatively longer than the other side (b) of the protrusion.

In addition, the third section S3 from the other end of the second section S2 to a predetermined length extending in the other direction has a plurality of prisms that cause the light emitted from the electrodeless fluorescent lamp 103 to be refracted to the ground. 109 is formed in a triangular protrusion, the inner angle of the protrusion projecting downward from the prism 109 is 85 ° ~ 80 °, the inner angle of one side is 30 ° ~ 25 °, one side of the protrusion (a) To be formed relatively longer than the other side (b) of the protrusion.

The fourth section S4, which extends from the other end of the third section S3 to a predetermined length extending in the other direction, includes a plurality of prisms that cause light emitted from the electrodeless fluorescent lamp 103 to be refracted to the ground. 109 is formed in a triangular projection, the inner angle of the projecting portion projecting downward from the prism 109 is 80 ° ~ 75 °, the inner angle of one side is 25 ° ~ 20 °, one side of the protrusion (a) To be formed relatively longer than the other side (b) of the protrusion.

Finally, the fifth section S5 from the other end of the fourth section S4 to the other end of the refracting portion 101 includes a plurality of light sources that cause light emitted from the electrodeless fluorescent lamp 103 to be refracted to the ground. The prism 109 is formed to protrude in a triangle, the inner angle of the protrusion projecting downward from the prism 109 is 85 ° ~ 80 °, the inner angle of one side is 25 ° ~ 20 °, one side of the protrusion (a ) Is formed relatively longer than the other side (b) of the protrusion.

Accordingly, as described above, the light refraction ranges from the first section S1 to the fifth section S5, respectively, so that light distribution can be realized as shown in FIG. 5A.

Here, as shown in FIG. 2 or 3, the refracting part 101 and the housing 102 are fixedly provided with a fluorescent lamp 103 having a long round shape in one direction, and thus, the first section S1 to the fifth. The light is evenly emitted until the section S5.

In particular, in the present invention, as described above, the electrodeless fluorescent lamp 103 may be installed in the refraction portion 101 and the housing 102, but a fluorescent lamp having an electrode may be fixedly installed in this case. In this case, the prism The formed refraction unit 101 does not need to install a general transparent cover without a prism to induce refraction of light, and in this case, light distribution as shown in FIG. 5B can be obtained.

On the other hand, the other end of the housing 102 and the refraction portion 101 is bolted to the ballast box 110 as shown in Figure 2, the housing 102 and the refraction portion inside the ballast box 110 A ballast is provided to supply the starting voltage or limit the current to the electrodeless fluorescent lamp 103 installed inside the 101.

The present invention made of the above configuration is bolted to the end of the arm 111 is bent or coupled at a predetermined angle from the top of the street lamp pole 112 as shown in FIG.

The ballast box 110 is coupled to the pole 112 structure and coupling means can be easily implemented by those skilled in the art, the present invention is not limited thereto, it can be variously adopted and changed.

Therefore, when power is supplied in the state in which the lighting device of the present invention is installed in the street lamp pole 112 as described above, in each section of the prism 109 formed in the refraction unit 101, the light is refracted at different angles. It is possible to implement the light distribution as shown in Figure 5a.

Here, when the luminaire according to the present invention illuminates the road surface (roadway), the light generated by the electrodeless fluorescent lamp 103 by the prism 109 is controlled to be able to project only the ground of the one-way lane, the light of the light emitting source By controlling the divergence direction, it is possible to prevent the occurrence of back-lighting and to prevent the glare by implementing the cut-off light distribution, so that the illumination of the road is high and uniform. This can be provided.

1 is a view showing the appearance of a conventional street light.

Figure 2 is an exploded perspective view showing the overall configuration of the lighting fixture according to the present invention.

Figure 3 is a cross-sectional view showing a cross section of a state in which the housing is coupled to the refractive unit according to the present invention.

Figure 4 is a view showing a structure in which the ballast is coupled to the other end of the refraction portion and the housing in accordance with the present invention coupled state.

5A and 5B illustrate a light distribution structure of a lighting device according to the present invention.

Figure 6 is a view showing a state in which the lighting fixture according to the present invention is installed on the street lamp pole.

<Description of the symbols for the main parts of the drawings>

101: refracting portion 102: housing

103: fluorescent lamp 104: lamp holder

105: first through 106 106: second through

107: set screw 108: nut

109: prism 110: ballast box

111: Arm 112: Paul

Claims (2)

A refracting portion having a semi-cylindrical cross-sectional structure, the entire surface of which is made of a transparent material so that light is transmitted, and a plurality of prism for refracting light are protruded on the inner side, and an opening is formed on the upper side; It has a semi-cylindrical structure with an opening formed in the lower portion so as to be symmetrical with the refraction portion, a reflecting plate for reflecting light on the inner surface is mounted, the round electrodeless fluorescent lamp is fixed to the lamp holder bolted to the lower surface, A housing bolted to the refracting portion such that the openings abut against each other; A ballast coupled to the other end of the refraction portion and the housing, coupled to an arm end bent or refracted by the street lamp pole, and a ballast containing a ballast for limiting the supply and current of the starting voltage to the electrodeless fluorescent lamp, The inner surface of the refraction portion is divided into a plurality of sections, and each of the sections has a plurality of prisms protruding into a triangular prism that causes the light emitted from the electrodeless fluorescent lamp to be refracted to the ground. Light fixture for exclusive use of electrodeless fluorescent lamps, characterized in that the angles are different. The method of claim 1, The inner side of the refraction portion is divided into five sections, The first section from one end of the inner surface of the refraction portion to a predetermined length toward the other side has a plurality of prisms protruding in a triangle to cause light emitted from the electrodeless fluorescent lamp to be refracted to the ground, and protrude downward from the prism. The inner angle of the protrusion is 95 ° ~ 90 °, the inner angle of one side is 40 ° ~ 35 °, one side of the protrusion is formed longer than the other side of the protrusion, In the second section from the other end of the first section to a predetermined length extending in the other direction, a plurality of prisms are formed to protrude in a triangle to cause light emitted from the electrodeless fluorescent lamp to be refracted to the ground. The inner angle of the protruding part is 90 ° to 85 °, the inner side of one side is 35 ° to 30 °, and one side of the protruding part is formed longer than the other side of the protruding part, In the third section from the other end of the second section to a predetermined length extending in the other direction, a plurality of prisms are formed to protrude in a triangle to cause the light emitted from the electrodeless fluorescent lamp to be refracted to the ground. The inner angle of the protruding part is 85 ° to 80 °, the inner side of one side is 30 ° to 25 °, and one side of the protruding part is formed longer than the other side of the protruding part, In the fourth section from the other end of the third section to a predetermined length extending in the other direction, a plurality of prisms are formed to protrude in a triangle to cause light emitted from the electrodeless fluorescent lamp to be refracted to the ground. The inner angle of the protruding part is 80 ° to 75 °, the inner side of one side is 25 ° to 20 °, and one side of the protruding part is formed longer than the other side of the protruding part, In the fifth section from the bottom to the bottom of the fourth section, a plurality of prisms are formed in a triangle to project light emitted from the electrodeless fluorescent lamp into the ground, and the projections downwardly protruding from the prism An interior angle of 85 ° ~ 80 °, one side of the inner angle is 25 ° ~ 20 °, the luminaire dedicated for electrodeless fluorescent lamps, characterized in that one side of the protrusion is formed longer than the other side of the protrusion.

Images