KR200294968Y1 - Reflecting shade for fluorescent illuminator - Google Patents

Abstract

The present invention is to improve the illuminance by preventing the unnecessary loss of light emitted from the fluorescent lamp with excellent reflectance, thereby reducing the energy loss, the upper side of the fluorescent lamp of at least two fluorescent lamps A reflector for a fluorescent lamp fixture provided in the apparatus, comprising: at least a first bending point provided on an upper portion of each fluorescent lamp, a pair of first reflecting surfaces extending inclined upwardly from both sides from the first bending point of each fluorescent lamp; A second reflective surface extending obliquely downward from an end of the first reflective surface toward the adjacent fluorescent lamp among the first reflective surfaces of each fluorescent lamp, and a third reflective surface extending obliquely downward from an end of the second reflective surface of each fluorescent lamp; And a third reflecting surface extending from the second reflecting surface of the adjacent fluorescent lamp between two adjacent fluorescent lamps. A third reflecting surface forming a second bending point, a fourth reflecting surface extending obliquely downward from an end portion of the first reflecting surface facing outward of the fluorescent lamp, among the first reflecting surfaces of the respective fluorescent lamps, and the fourth reflecting surface; And a fifth reflecting surface extending obliquely downward from an end of the reflecting surface and a sixth reflecting surface extending obliquely downward from an end of the fifth reflecting surface. .

Description

Reflecting shade for fluorescent illuminator

The present invention relates to a reflector for a fluorescent lamp, and more particularly to a reflector for a fluorescent lamp that can maximize the reflectance of the light generated from the fluorescent lamp by improving the structure of the reflector of the reflector.

The fluorescent lamp mounted on the fluorescent lamp is a low-pressure discharge lamp, and the filament is preheated by the current supplied through the ballast, and the electrons emitted from the filament stimulate the mercury in the vapor phase of the lamp to generate ultraviolet rays. This ultraviolet light stimulates the fluorescent material applied to the inner surface of the glass tube of the luminaire to produce visible light.

These fluorescent lamps are widely installed in homes, offices, factories, underpasses, and all other places. Fluorescent lamps are usually installed around the world. Depending on their capacity, 20W, 32W, 40W, etc. There are things.

In general, a fluorescent lamp includes a reflector on the rear side of the installed fluorescent lamp, the reflector is formed on the surface facing the fluorescent lamp. This reflecting surface is usually in the shape of a plane or three sides at a constant angle. By the way, although the reflecting surface formed in the conventional fluorescent lamp fixture can reflect the fluorescent light to some extent, the reflectance has a limit.

Since light reflects and refracts, the reflector must be designed so that light can be reflected and refracted without interference in order to more efficiently use the light emitted from the fluorescent lamp in the space where the fluorescent lamp is installed. This is particularly important in terms of energy saving. When using a reflector with good reflectivity, fewer fluorescent lamps can be used while reducing unnecessary light fluxes, thereby saving electric energy more.

Increasing the reflectivity of the reflector as described above is very important for fluorescent lighting fixtures. As a method of increasing the reflectivity of the reflector, there is a method of using a material having a high reflectance as a reflector of the reflector, and a method of blocking the light flux unnecessarily reflected and refracted by adjusting the reflector angle of the reflector.

However, the first method of improving the reflector material has its own limitations. That is, since the reflecting plate is very close to the fluorescent lamp, material deformation may occur due to the heat of the fluorescent lamp, and such deformation of the material may cause a rapid decrease in the reflectance of the reflecting plate. At present, it is known that the oxide film formed on high purity aluminum is the most excellent reflector material having a reflectance of about 95%.

On the other hand, the second method of adjusting the angle of the reflection plate of the reflection shade has been developed in various ways at present. The reflection plate of the reflection shade generally used in the prior art is simply to reflect the light emitted from the fluorescent lamp downward, there is a limit in the light reflecting the space efficiently. This does not take into account the angle of light emitted from the fluorescent lamp and the angle of light reflected from the reflective surface, it simply depends on the material of the reflective surface, such reflector is very low reflectance and also lower the illuminance.

In particular, in the case of a multi-luminescent fluorescent light fixture as shown in Figure 1, the total reflectance of the light fixture is only about 50% due to the light emitted by the adjacent fluorescent light. The fluorescent lamp shown in Figure 1 represents a four-lamp luminaire equipped with four fluorescent lamps, the reflector (2) of the luminaire has a flat surface (3) is extended to the top of the fluorescent lamp (1) outside both ends of the fluorescent lamp, Reflecting surfaces 4 are formed to be inclined downwardly outward from both ends of the flat surface 3.

In the reflection shade 2 as described above, since the light R1 emitted vertically upward from the fluorescent lamp 1 is reflected on the flat surface 3 and irradiated back to the fluorescent lamp 1, the light is blocked by the fluorescent lamp 1. In addition, the light R2 emitted at an angle upwards is also reflected from the flat surface 3 to be blocked by the adjacent fluorescent lamp 1a, thereby reducing the reflectance.

In fact, the reflector including the reflector having the above structure is known to exhibit a reflectance of about 70% even when the reflector is formed of a material having an excellent reflectance of 95% as described above.

As such, the decrease in reflectance of the fluorescent lamp lowers the illuminance, thereby lowering the overall efficiency of the lamp, and in order to obtain the same brightness, it is necessary to increase the number of fluorescent lamps.

The present invention has been made to solve the above problems, the object of the present invention is to provide a reflector for fluorescent lamps excellent in reflectance.

Another object of the present invention is to provide a reflector for a fluorescent lamp fixture that prevents unnecessary loss of light emitted from a fluorescent lamp and improves illuminance, thereby reducing energy loss.

1 is a schematic cross-sectional view showing a reflection shade of a conventional general four-light fluorescent lamp fixture,

Figure 2 is a schematic cross-sectional view showing a reflector of the fluorescent lamp fixture for a second lamp according to an embodiment of the present invention,

Figure 3 is a schematic cross-sectional view showing a reflector of the fluorescent lamp for three lamps according to an embodiment of the present invention,

Figure 4 is a schematic cross-sectional view showing a reflector of the fluorescent lamp fixture for four lamps according to an embodiment of the present invention,

5 is a light distribution diagram of Test Example 1 according to the present invention;

6 is a light distribution diagram of Test Example 2 according to the present invention;

7 is a light distribution diagram of the comparative example as shown in FIG. 1.

In order to achieve the above object, the present invention is a reflection lamp for a fluorescent lamp fixture installed on the upper side of the fluorescent lamp among at least two fluorescent lamps, at least a first bending point provided on the upper portion of each fluorescent lamp and And a pair of first reflecting surfaces extending obliquely upward from both of the first bending points of the respective fluorescent lamps and obliquely extending downward from an end portion of the first reflecting surface toward the adjacent fluorescent lamp among the first reflecting surfaces of the respective fluorescent lamps. A third half extending downward from an end of the second reflecting surface and the second reflecting surface of each fluorescent lamp to form a third reflecting surface, the third half extending from a second reflecting surface of adjacent fluorescent lamps between two adjacent fluorescent lamps; A third reflection surface that meets a slope to form a second bending point, and a stage of a first reflection surface facing outward of the fluorescent light fixture among the first reflection surfaces of the respective fluorescent lamps; A fourth reflection surface extending obliquely downward from the second reflection surface, a fifth reflection surface extending obliquely downward from an end of the fourth reflection surface, and a sixth reflection surface extending obliquely downward from an end of the fifth reflection surface It provides a reflector for a fluorescent light fixture, characterized in that consisting of.

According to another feature of the present invention, the pair of first reflecting surface of each fluorescent lamp may be provided to form an angle of 159 degrees to 161 degrees around the first bending point.

According to another feature of the present invention, the first reflection surface and the second reflection surface toward the adjacent fluorescent lamp of the first reflection surface of each fluorescent lamp may be provided to form an angle of 149 degrees to 151 degrees.

According to another feature of the present invention, the second and third reflective surface may be provided to form an angle of 144 degrees to 146 degrees.

According to another feature of the present invention, the third reflecting surfaces of the adjacent fluorescent lamps may be provided to form an angle of 69 degrees to 71 degrees with respect to the second bending point.

According to another feature of the present invention, the first reflection surface and the fourth reflection surface toward the outside of the first reflection surface of each fluorescent lamp may be provided to form an angle of 159 degrees to 161 degrees.

According to another feature of the present invention, the fourth and fifth reflecting surface may be provided to form an angle of 159 degrees to 161 degrees.

According to another feature of the present invention, the fifth and sixth reflecting surface may be provided to form an angle of 149 degrees to 151 degrees.

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

Figure 2 is a schematic diagram for explaining the structure of the reflector for the fluorescent lamp fixture according to an embodiment of the present invention, Figure 2 shows a fluorescent lamp for two lamps equipped with two fluorescent lamps.

As shown in FIG. 2, a fluorescent lamp having a reflector for a fluorescent lamp according to the present invention is provided with a lamp body 10 having a ballast and the like, and a reflector 20 mounted to the lamp body 10. Two fluorescent lamps 11a and 11b of the first fluorescent lamp 11a and the second fluorescent lamp 11b are fixed to the lamp main body 10 by fixing rods, respectively. In addition, the reflection shade 20 is installed on the lower surface of the lamp body 10 to the upper portion of the fluorescent lamp (11a) (11b). Such a fluorescent lamp may be a form in which the lamp body 10 is embedded in the ceiling, it may be a form that is exposed. In the fluorescent lamp as described above, the reflector 20 has the following structure.

First, as shown in FIG. 2, first bending points 21a and 21b are respectively formed on the upper portions of the first fluorescent lamp 11a and the second fluorescent lamp 11b. From these first bending points 21a and 21b, a pair of first reflecting surfaces 22a, 22a ', 22b and 22b' extending inclined upwardly on both sides thereof are formed. The first reflecting surfaces 22a and 22a 'of 11a and the first reflecting surfaces 22b and 22b' of the second fluorescent lamp 11b are paired with each other to form the first bending points 21a. It is preferable to achieve symmetry around (21b).

Of the first reflecting surfaces 22a, 22a ', 22b, 22b' of the first and second fluorescent lamps 11a and 11b, the first reflecting surfaces 22a 'and 22b' facing the adjacent fluorescent lamps. At the end portions, second reflecting surfaces 23a and 23b extend inclined downward, respectively. That is, the second reflecting surface 23a extends from an end of the first reflecting surface 22a 'toward the adjacent second fluorescent lamp 11b among the first reflecting surfaces 22a and 22a' of the first fluorescent lamp 11a. Similarly, in the second fluorescent lamp 11b, the second reflecting surface 23b extends from the end of the first reflective surface 22b 'facing the adjacent first fluorescent lamp 11a.

From these second reflecting surfaces 23a and 23b, the third reflecting surfaces 24a and 24b respectively extend so as to be inclined downward from the end thereof, and thus, the first of the two adjacent fluorescent lamps 11a and 11b are extended. The three reflecting surfaces 24a and 24b meet with each other to form a second bending point 25.

On the other hand, of the first reflecting surfaces 22a, 22a ', 22b, 22b' of the first and second fluorescent lamps 11a and 11b, the first reflecting surfaces 22a and 22b toward the outside of the fluorescent light fixture. Fourth reflective surfaces 26a and 26b extend downwardly from the end of each of the fourth reflective surfaces 26a and 26b, and fifth reflective surfaces 27a obliquely downward from the fourth reflective surfaces 26a and 26b, respectively. ) 27b is extended, and the sixth reflective surfaces 28a and 28b extend from the ends of the fifth reflective surfaces 27a and 27b to be inclined downward.

In the reflector 20 for a fluorescent lamp configured as described above, it is possible to further maximize the reflection efficiency of the reflector by determining the angle between each reflecting surface as follows.

That is, the pair of first reflecting surfaces 22a, 22a ', 22b and 22b around the first bending points 21a and 21b of the first fluorescent light 11a and the second fluorescent light 11b. The angle A1 (B1) formed by ') forms an angle of 159 degrees to 161 degrees. In this case, it is possible to achieve an angle of preferably 160 degrees. Next, angles A2 and B2 formed by the first reflecting surfaces 22a 'and 22b' and the second reflecting surfaces 23a and 23b from the respective fluorescent lamps 11a and 11b toward the adjacent fluorescent lamps. ) Is set to 149 degrees to 151 degrees, preferably 150 degrees. The angles A3 and B3 formed by the second reflection surfaces 23a and 23b and the third reflection surfaces 24a and 24b of the respective fluorescent lamps 11a and 11b are 144 degrees to 146 degrees. Preferably at an angle of 145 degrees. In addition, the third reflecting surface 24a and the second fluorescent light 11b of the first fluorescent light 11a around the second bending point 25 which is the middle portion of the first fluorescent light 11a and the second fluorescent light 11b. The angle A7 formed by the third reflective surface 24b of) is set to 69 to 71 degrees, preferably 70 degrees.

Meanwhile, the angles A4 and B4 formed by the first reflecting surfaces 22a and 22b and the fourth reflecting surfaces 26a and 26b facing the outside of the fluorescent lamps 11a and 11b are 159 degrees. To 161 degrees, preferably 160 degrees, and the angles A5 and B5 formed by the fourth reflective surfaces 26a and 26b and the fifth reflective surfaces 27a and 27b are 159 degrees. To 161 degrees, preferably 160 degrees. The angles A6 and B6 formed by the fifth reflective surfaces 27a and 27b and the sixth reflective surfaces 28a and 28b of the respective fluorescent lamps 11a and 11b are 149 degrees to 151 degrees. Preferably it is 150 degree | times.

When the angles of the reflecting surfaces are set as described above, as shown in FIG. 2, the light emitted from each fluorescent lamp is not reflected by the adjacent fluorescent lamp, and as much as possible, may be reflected toward the ground, thereby increasing the illuminance of the fluorescent lamp. It can increase. Looking at this in more detail as follows.

In FIG. 2, the path of the light emitted from the first fluorescent lamp 11a is shown. The path of the light emitted from the second fluorescent lamp 11b may also be the same. The light emitted from the fluorescent lamp is reflected in the normal direction of the direction incident on the reflecting surface. Thus, if the angle of each reflecting surface is not accurately controlled, the light may be blocked by adjacent fluorescent lamps or reflected back to the reflecting plate to return to the original light emitting self.

As shown in FIG. 2, the light emitted directly above the first fluorescent light 11a may be blocked by being projected back to the first fluorescent light 11a, but the light is projected in the direction of the first reflecting surface 22a '. L1 is projected in the normal direction with respect to the first reflecting surface 22a 'and is not blocked by other members, and light L2 (L3) projected onto the second reflecting surface 23a and the third reflecting surface 24a. ) Is not blocked by other members, but is reflected by the reflecting surface and projected into the luminaire lower space. Of course, the light L4 projected to the lower end of the second bending point 25 is projected onto the surface of the adjacent second fluorescent light 11b, but as shown in FIG. 2, the projected light is projected onto the surface of the second fluorescent light 11b. The amount of light is very small. Further, in order to prevent the light L4 directly irradiated by the adjacent fluorescent lamps, a straight line T connecting the lower end of the adjacent fluorescent lamps 11b at the center of the fluorescent lamp 11a positioned at the second bending point located between two adjacent fluorescent lamps. It can also be designed to descend to below. Of course, at this time, the reflection angle of the light incident on the other reflecting surfaces may be changed to be self-blocking, that is, a phenomenon in which the light is emitted by the fluorescent lamp itself.

Due to the angle adjustment of the fluorescent lamp reflector as described above, the overall reflectance of the fluorescent lamp fixture can be maintained to a very high degree.

The reflection surface structure of the reflector as described above can be applied to the multi-luminescent lamp having a large number of fluorescent lamps for the third and fourth lamps in addition to the fluorescent lamp for two lamps, Figure 3 shows the structure of the fluorescent lamp for three lamps, Figure Fig. 4 schematically shows the structure of the fluorescent lamp for four lamps.

As can be seen in Figure 3, the fluorescent lamp fixture for the third lamp according to the present invention, the second bending point (35a) (35b) between the three fluorescent lamps of the first, second, third, and third fluorescent lamps (11a) (11b) (11c) And two first bending points 31a, 31b, and 31c at each of the fluorescent lamps. As described above, reflecting surfaces are formed from each fluorescent lamp. First, first fluorescent lamps are formed from the first bending points 31a and 31b of the first fluorescent lamp 11a and the second fluorescent lamp 11b. As the second bending point 35a between 11a) and the second fluorescent lamp 11b, the first reflective surfaces 32a 'and 32b', the second reflective surfaces 33a and 33b, and the third reflective surface Fields 34a and 34b are sequentially formed, and the second fluorescent lamp 11b and the second fluorescent lamp 11b are formed from the first bending points 31b and 31c of the second fluorescent lamp 11b and the third fluorescent lamp 11c, respectively. The first reflecting surfaces 32b 'and 32c', the second reflecting surfaces 33b and 33c and the third reflecting surfaces 34b are also used as the second bending point 35b between the three fluorescent lamps 11c. 34c are formed in order, respectively. The first reflecting surfaces 32a and 32c and the fourth reflecting surface are sequentially located from the first bending points 31a and 31c to the outside of the first fluorescent lamp 11a and the third fluorescent lamp 11c. Fields 36a and 36c, fifth reflective surfaces 37a and 37c and sixth reflective surfaces 38a and 38c are formed, respectively. At this time, the first reflecting surface 32b 'of the second fluorescent lamp 11b does not have a reflecting surface facing outward, but only a reflecting surface facing an adjacent fluorescent lamp, so that the first bending point of the second fluorescent lamp 11b ( Since both sides are symmetrical with respect to 31b), both reflection surfaces are denoted by the same reference numerals.

On the other hand, the angle formed by each of the reflective surfaces, the angle (A1) (B1) (C1) formed by the pair of first reflecting surfaces 32a, 32a ', 32b, 32b', 32c, 32c ' First reflecting surfaces 32a ', 32b' and 32c 'with angles ranging from 159 degrees to 161 degrees, preferably 160 degrees, and directed toward adjacent fluorescent lamps from the respective fluorescent lamps 11a, 11b and 11c. The angles A2, B2, and C2 formed by the second reflective surfaces 33a, 33b, and 33c are set to 149 to 151 degrees, preferably 150 degrees. Also, the angles A3, B3, and C3 formed by the second reflection surfaces 33a, 33b, 33c and the third reflection surfaces 34a, 34b, and 34c are also 144 to 146 degrees. The angle A7 formed by the third reflecting surface 34a of the first fluorescent lamp 11a and the third reflecting surface 34b of the second fluorescent lamp 11b and the second fluorescent lamp ( The angle C7 formed by the third reflection surface 34b of 11b) and the third reflection surface 34c of the third fluorescent lamp 11c is also set to 69 to 71 degrees, preferably 70 degrees. In addition, the angles A4 and C4 formed by the first reflection surfaces 32a and 32c and the fourth reflection surfaces 36a and 36c facing the outside of the fluorescent lamps 11a and 11c located outside. Is 159 to 161 degrees, preferably 160 degrees, and the angles A5 and C5 formed by the fourth reflective surfaces 36a and 36c and the fifth reflective surfaces 37a and 37c are also 159 degrees. To 161 degrees, preferably to 160 degrees, and the angles A6 and C6 formed by the fifth reflective surfaces 37a and 37c and the sixth reflective surfaces 38a and 38c are also 149 degrees to 151 degrees, preferably 150 degrees.

In the case of the three-luminescent fluorescent lamp having such a structure, as in the case of the two-luminescent fluorescent lamp, the blocking effect of light by adjacent fluorescent lamps is suppressed as much as possible, thereby obtaining a very good reflectance overall.

This is of course the same also in the case of a fluorescent lamp for four-lamp, such as in FIG. The fluorescent lamp fixture for four lamps shown in FIG. 4 is the number of fluorescent lamps added to the fluorescent lamp fixture for three lamps of FIG. 3, and its members are the same. That is, the second bending points 45a, 45b, 45c are located between the four fluorescent lamps 11a, 11b, 11c, and 11d, and each fluorescent lamp 11a, 11b, 11c, and 11d is located. First reflective surfaces 42a ', 42b', 42c ', 42d', and second reflective surfaces 43a (to the second bent points 45a, 45b, 45c) 43b) 43c (43d) and 3rd reflection surfaces 44a (44b) 44c (44d) are formed in order, and it faces outward of the 1st fluorescent lamp 11a and the 4th fluorescent lamp 11d. The first reflecting surfaces 42a and 42d, the fourth reflecting surfaces 46a and 46d, the fifth reflecting surfaces 47a and 47d and the sixth reflecting surfaces 48a and 48d, respectively, are sequentially. Is formed. In addition, the angles between the respective reflecting surfaces, that is, the angles of A1 to A7, B1 to B3, C1 to C3, and D1 to D7, are also the same as described above. At this time, the angle B7 formed between the third reflecting surface 44b of the second fluorescent lamp 11b and the third reflecting surface 44c of the third fluorescent lamp 11c is preferably set to 69 to 71 degrees. You can make it 70 degrees. As described above, in the case of the four-lamp fluorescent lamp as shown in FIG. 4, the second fluorescent lamp 11b and the third fluorescent lamp 11c have symmetrical reflection surfaces with respect to each of the first bending points 41b and 41c.

Since the operation of this four-lamp fluorescent lamp is the same as described above, a detailed description thereof will be omitted.

Next, the effect of the fluorescent lamp according to the preferred test examples of the present invention as described above by requesting the Korea Institute of Lighting Equipment test will be described the results.

<Test Example 1>

A fluorescent lamp for three lamps having a structure as shown in FIG. 3 is a structure exposed to the ceiling, and provided with three three-wavelength fluorescent lamps, the reflecting surface of the aluminum plate of Mirro 4, ALANOD, Germany, 0.5 mm The aluminum plate had an aluminum purity of 99.85%, a tensile strength of 160 to 200 kg / cm 2, and a reflectance of 95%.

<Test Example 2>

A fluorescent lamp for four lamps having a structure as shown in FIG. 4 is a structure exposed to the ceiling, and provided with three three-wavelength fluorescent lamps, the reflecting surface of the aluminum plate of Mirro 4, ALANOD, Germany, 0.5 mm The aluminum plate had an aluminum purity of 99.85%, a tensile strength of 160 to 200 kg / cm 2, and a reflectance of 95%.

Comparative Example

A fluorescent lamp for four lamps having a structure as shown in FIG. 1 is exposed to the ceiling, and provided with three three-wavelength fluorescent lamps, and the reflecting surface is 0.5 mm of an aluminum plate of model name 33P-G of ALANOD, Germany. The aluminum plate has an aluminum purity of 99.85%, a tensile strength of 160 to 200 kg / cm 2, and a reflectance of 86%.

Table 1 below shows the results of the light distribution test at 24 ± 3 ° C. and a humidity of 65% or less using the test examples 1 and 2 and the comparative example.

Roughness Illumination Name Angle (°) reflectivity(%) Roughness (cd) Test Example 1 Test Example 2 Comparative example Test Example 1 Test Example 2 Comparative example Direct illuminance A 0 93.9 93.9 71 320 320 220 Side roughness B 20 93.9 93.9 71 330 330 238 C 40 93.9 93.9 71 243 243 244 D 60 93.9 93.9 71 117 117 144

Light distribution curves of Test Examples 1 and 2 and Comparative Examples according to Table 1 are shown in FIGS. 5, 6, and 7, respectively.

In the light of Table 1 and FIGS. 5, 6, and 7, it can be seen that the reflector of the fluorescent lamp fixture according to the present invention exhibits a much higher reflectance than the conventional reflector. Although in the above experiments, in the case of the conventional reflector used a material having a lower reflectance than in the case of the test examples according to the present invention, while the reflector of the comparative example shows a reflectance of 71% with a reflector material of 86%, The examples are 95% reflector material with 93.9% reflectance, representing a significant difference in reflectance reduction.

In addition, in the case of the test examples according to the present invention it can be seen that the excellent roughness, the excellent roughness ratio.

According to the present invention having the configuration as described above, the reflectance of the reflector for the fluorescent lamp fixture can be maintained at about the same level as the reflectance of the raw material forming the reflector, it is possible to reduce the light loss due to reflection as possible.

In addition, the roughness can be increased by maintaining a high reflectance.

In addition, according to the high illuminance, an excellent lighting effect can be obtained even with a smaller number of fluorescent lamps, and the energy reduction effect can also be enhanced.

In the present specification, the present invention has been described with reference to a limited embodiment, but various embodiments are possible within the scope of the present invention. In addition, although not described, equivalent means will also be combined as it is in the present invention. Therefore, the true scope of protection of the present invention should be defined by the following claims.

Claims (8)

In the fluorescent lamp fixture having at least two fluorescent lamps, the reflector for the fluorescent lamp fixture installed above the fluorescent lamp, A first bending point provided on the upper portion of each fluorescent lamp; A pair of first reflecting surfaces extending obliquely upward from both sides of the first bending points of the respective fluorescent lamps; A second reflection surface extending obliquely downward from an end portion of the first reflection surface toward the adjacent fluorescent lamp among the first reflection surfaces of each fluorescent lamp; The second reflecting surface extends obliquely downward from an end of the second reflecting surface to form a third reflecting surface, and meets a third reflecting surface extending from the second reflecting surface of the adjacent fluorescent lamp between two adjacent fluorescent lamps A third reflecting surface forming a point; A fourth reflection surface extending obliquely downward from an end portion of the first reflection surface toward the outside of the fluorescent light fixture among the first reflection surfaces of the respective fluorescent lamps; A fifth reflective surface inclined outwardly downward from an end of the fourth reflective surface; and And a sixth reflective surface inclined outwardly downward from an end of the fifth reflective surface. The method of claim 1, The pair of first reflecting surfaces of the fluorescent lamps are formed to form an angle of 159 degrees to 161 degrees around the first bending point. The method of claim 1, Reflector for fluorescent lamps, characterized in that the first reflecting surface and the second reflecting surface of the first reflecting surface of each fluorescent lamp toward the adjacent fluorescent lamp to form an angle of 149 degrees to 151 degrees. The method of claim 1, The second reflecting surface and the third reflecting surface is a reflector for a fluorescent lamp, characterized in that provided to form an angle of 144 degrees to 146 degrees. The method of claim 1, And the third reflecting surfaces of the adjacent fluorescent lamps form an angle of 69 degrees to 71 degrees with respect to the second bending point. The method of claim 1, Reflector for fluorescent lamps, characterized in that the first reflection surface and the fourth reflection surface toward the outside of the first reflection surface of each fluorescent lamp to form an angle of 159 degrees to 161 degrees. The method of claim 1, The fourth reflecting surface and the fifth reflecting surface is a reflector for a fluorescent lamp, characterized in that provided to form an angle of 159 degrees to 161 degrees. The method of claim 1, The fifth reflecting surface and the sixth reflecting surface of the fluorescent lamp fixture, characterized in that provided to form an angle of 149 degrees to 151 degrees.