JP2012202928A - Light irradiation apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a light irradiation apparatus having a novel structure which is useful as a light source for a weather resistance test device of a solar cell panel.SOLUTION: A light irradiation apparatus comprises a plurality of external electrode type rare gas discharge lamps which are disposed in an attitude extending in parallel with each other and a plurality of inverters, corresponding to the rare gas discharge lamps, electrically connected to power feeding sections formed in one-side terminal portions of the rare gas discharge lamps in an axial direction. At a plurality of level positions where separation distances in a direction vertical to a lamp arrangement surface on which the rare gas discharge lamps are arranged side by side are different from each other, the plurality of inverters are disposed while being displaced in the axial direction of the rare gas discharge lamps so as to be positioned at a terminal portion side where the power feeding sections are formed in the axial direction of the rare gas discharge lamps as the level positions to dispose the inverters become far from the lamp arrangement surface.

Description

  The present invention relates to a light irradiation apparatus used for, for example, a weather resistance test apparatus for a solar cell panel.

  In recent years, clean energy that does not involve much fossil fuel consumption has been demanded from the viewpoint of conservation of the global environment. Among these, solar cells that can use solar energy that can be said to be inexhaustible are attracting attention, and solar power generation systems and the like are being introduced and developed. The life characteristics of solar cells are most influenced by ultraviolet rays emitted from the sun, and physical and chemical deterioration occurs due to sunlight irradiation, and accordingly, the performance and functions of the solar cells deteriorate. Therefore, for example, knowing the state of deterioration due to sunlight irradiation in advance for each use condition is a very important factor in product design, for example, a weather resistance test for measuring the weather resistance characteristics by intentionally irradiating ultraviolet rays. Devices etc. have been proposed.

  In such a weather resistance test apparatus, for example, the solar cell is exposed to severe conditions such as intentionally radiating ultraviolet rays of 5 times or more the amount of ultraviolet rays emitted from the sun, and the degradation is intentionally advanced. For example, a metal halide lamp is suitably used as an ultraviolet ray source because it is excellent in terms of spectral distribution and irradiance (Patent Document 1). reference.).

JP 2005-241487 A

However, the metal halide lamp not only generates a large amount of heat, but also has many problems such as variability in the amount of radiated light, difficulty in instantaneous lighting, and large size. Also, the metal halide lamp has a short lamp life and must be replaced frequently.
Therefore, the present inventors have a spectrum distribution similar to sunlight in the ultraviolet region, and the heat generation amount is small compared to a metal halide lamp, the variability of the amount of radiated light is small, and instantaneous lighting is possible. In addition, we focused on an external electrode type rare gas discharge lamp having features such as a small size. Rare gas discharge lamps are widely used in various applications such as light sources for sterilization devices, document illumination devices, backlights, etc., but they are used as light sources for solar cell panel weather resistance testing devices, especially for large areas. Conventionally, it is not known to use a plurality of rare gas discharge lamps side by side in order to deal with solar cells.

  This invention is made | formed based on the above situations, Comprising: It aims at providing the light irradiation apparatus which has a novel structure useful as a light source of the weather resistance test apparatus of a solar cell panel.

The light irradiation apparatus of the present invention is electrically connected to a plurality of external electrode type rare gas discharge lamps arranged in a posture extending in parallel to each other, and a power supply section formed at one end in the axial direction of the rare gas discharge lamp. A plurality of inverters corresponding to each of the rare gas discharge lamps,
In the plurality of inverters, the level position where the inverter is arranged becomes farther from the lamp arrangement surface at a plurality of level positions where the separation distances in the direction perpendicular to the lamp arrangement surface where the rare gas discharge lamps are arranged are different from each other. The gas discharge lamp is disposed in a state of being displaced in the axial direction of the rare gas discharge lamp so as to be positioned on the end side where the power feeding portion is formed in the axial direction of the gas discharge lamp.

In the light irradiation device of the present invention, at one level position, two inverters are arranged apart from each other in the axial direction of the rare gas discharge lamp,
A structure in which an inverter located on the same side in the axial direction of the rare gas discharge lamp at each level position is connected to an end portion on the same side in the axial direction of the corresponding rare gas discharge lamp to form a power feeding unit. It is preferable that

  In the light irradiation device of the present invention, it is preferable that a cooling air passage extending in a direction perpendicular to the lamp arrangement surface is formed in a region between the two inverters.

  The light irradiation apparatus of this invention is used for the weather resistance test apparatus for solar cell panels.

According to the light irradiation apparatus of the present invention, since a plurality of inverters are arranged in a so-called hierarchical structure, it is possible to avoid an increase in the size of the light irradiation apparatus, and the level position where the inverter is located is a lamp. It is configured to be arranged in a state displaced in the axial direction of the rare gas discharge lamp so as to be positioned closer to the end side where the power feeding part is formed in the corresponding rare gas discharge lamp as it is farther from the arrangement surface. Therefore, for each rare gas discharge lamp, the difference in the length of the power supply line connecting the rare gas discharge lamp and the inverter can be made as small as possible. It is possible to prevent the variation in ultraviolet radiation efficiency, or to suppress the variation in ultraviolet radiation efficiency, and to radiate ultraviolet rays with the intended radiation distribution. It is possible.
Further, since the rare gas discharge lamp has a configuration in which the phosphor layer emits light by the action of ultraviolet rays (vacuum ultraviolet rays) in a predetermined wavelength region generated in the inner space of the arc tube, an extra light component is removed from the solar cell panel. Therefore, the intended weather resistance test can be performed with high reliability.

It is sectional drawing for description along the lamp | ramp central axis of the rare gas discharge lamp which shows the outline of a structure in an example of the light irradiation apparatus which concerns on the 1st Embodiment of this invention. It is sectional drawing for description when the light irradiation apparatus shown in FIG. 1 is seen from the arrow A direction (lamp central axis direction of a rare gas discharge lamp). BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the outline of a structure in an example of the rare gas discharge lamp used in the light irradiation apparatus of this invention, Comprising: (a) Sectional drawing along a lamp | ramp central axis, (b) BB sectional view in (a) FIG. It is a figure which shows the connection state of a noble gas discharge lamp and an inverter. It is explanatory drawing which shows roughly an example of the example of arrangement | positioning with respect to the solar cell panel of the light irradiation apparatus of this invention in the weather test apparatus of a solar cell panel. It is the side view seen from the direction where a noble gas discharge lamp is shown, which shows the outline of the composition in an example of the light irradiation apparatus concerning a 2nd embodiment of the present invention. It is the side view which looked at the light irradiation apparatus shown in FIG. 6 from the arrow A direction (lamp central axis direction of a noble gas discharge lamp). It is the side view seen from the direction where a noble gas discharge lamp is shown, which shows the outline of the composition in an example of the light irradiation apparatus concerning a 3rd embodiment of the present invention. It is the side view which looked at the light irradiation apparatus shown in FIG. 8 from the arrow A direction (lamp central axis direction of a noble gas discharge lamp). It is the side view seen from the direction where a noble gas discharge lamp is shown, which shows the outline of the composition in the other example of the light irradiation apparatus concerning a 3rd embodiment of the present invention. It is the side view which looked at the light irradiation apparatus shown in FIG. 10 from the arrow A direction (lamp central axis direction of a noble gas discharge lamp). It is a figure which shows the outline of a structure in the other example of the light irradiation apparatus which concerns on the 2nd Embodiment of this invention.

Hereinafter, embodiments of the present invention will be described in detail.
[First Embodiment]
FIG. 1 is a sectional view for explanation along the central axis of a rare gas discharge lamp showing an outline of the configuration of an example of a light irradiation apparatus according to the first embodiment of the present invention, and FIG. It is sectional drawing for description when the light irradiation apparatus shown is seen from the arrow A direction (the lamp | ramp central-axis direction of a noble gas discharge lamp). The number of rare gas discharge lamps used in the light irradiation apparatus of the present invention is, for example, 20 to 40. However, in order to facilitate understanding, an example in which the number of rare gas discharge lamps is set to 12 is taken as an example. I will give you a description.
The light irradiation device 10 includes a plurality of (for example, 12) external electrode type rare gas discharge lamps (hereinafter, referred to as “11” unless a specific one is described). The lamp center axis C is positioned in the same plane and extends in parallel with each other, for example, a plurality of lamp accommodating portions 15 arranged at equal intervals, for example, and a plurality (for example, 12) corresponding to each of the rare gas discharge lamps 11. And an inverter housing portion 20 in which other electrical components are housed and arranged.

As shown in FIG. 3, each rare gas discharge lamp 11 includes a straight tube-shaped arc tube 12 having both ends sealed, and inside the arc tube 12 is xenon gas or xenon gas. A predetermined amount of a mixed gas containing as a main component is enclosed.
For example, barium glass, kovar glass, tungsten glass, soda lime glass, borosilicate glass, or the like can be used as the glass material constituting the arc tube 12.
The outer diameter of the arc tube 12 is, for example, 6 mm or more and 15 mm or less, and the wall thickness is 0.3 to 0.6 mm or less. In particular, since the luminous efficiency can be increased, the outer diameter of the arc tube 12 is preferably 9.8 to 14 mm.

On the inner peripheral surface of the arc tube 12, for example, a phosphor layer 13 is formed over substantially the entire area. The phosphor layer 13 is formed by, for example, applying a phosphor slurry in which a phosphor material that emits visible light or ultraviolet light is mixed with a solvent in which nitroacetate is mixed with nitrocellulose to the inner surface of the arc tube 12 and firing. Can be formed. As the phosphor material, for example, blue light-emitting material, green light-emitting material, and red light-emitting material are used in combination. For example, as the ultraviolet light-emitting phosphor, LaMgAl ₁₁ O ₁₉ : Ce, Ce- ( Examples of the red phosphor include (Y, Gd) BO ₃ : Eu or Y ₂ O ₃ : Eu, and examples of the green phosphor include green, phosphor, and the like. Can exemplify LaPO ₄ : Ce, Tb and the like, and as the blue phosphor, BaMgAl ₁₀ O ₁₇ : Eu and the like can be exemplified, but the phosphor substance is not limited thereto.
The thickness of the phosphor layer 13 is, for example, 10 to 25 μm, and the size that is brightest is selected depending on the combination of phosphor materials used. The optimum thickness of the phosphor layer 13 is usually 13 to 17 μm.
The region where the phosphor layer 13 is formed does not have to be substantially the entire inner peripheral surface of the arc tube 12, and the region where the phosphor layer 13 is not formed on a part of the inner peripheral surface of the arc tube 12, or A region where the thickness of the phosphor layer 13 is small may be formed.

On the outer peripheral surface of the arc tube 12, a pair of substantially strip-shaped electrodes 14 </ b> A and 14 </ b> B extend along the tube axis (lamp center axis C) of the arc tube 12 at positions facing each other across the lamp center axis C. One electrode 14A functions as a high-voltage side electrode, and the other electrode 14B functions as a low-voltage side electrode.
Each of the electrodes 14A, 14B is made of, for example, a metal tape such as aluminum or copper cut into a strip shape and attached to the outer peripheral surface of the arc tube 12, or a conductive paste material such as a silver paste. Is made of a thin film formed by screen printing on the outer peripheral surface of the arc tube 12 and baked. For example, when it is made of a thin film of silver paste, the thickness may be in the range of 2 to 20 μm. preferable.
Further, each of the electrodes 14A and 14B can be configured such that a slit or an opening for radiating light generated inside the arc tube 12 is formed. For example, a technique for forming a slit in an electrode is disclosed in, for example, Japanese Patent Application Laid-Open No. 09-298049.

  As shown in FIG. 4, each rare gas discharge lamp 11 is connected to an inverter 30 via a feeder line 18 connected at one end of each electrode 14A, 14B. The operation state is controlled by the control unit 31 that detects the lamp current by the current detection means and performs feedback control.

  As a specific configuration example of the rare gas discharge lamp 11, the arc tube 12 has a length of 450 mm, an outer diameter of φ10 mm, and an emission length of about 430 mm. The amount of xenon gas sealed in the arc tube 12 is in the range of 10 to 40 kPa, for example, 20 kPa. The width of each electrode 14A, 14B is within a range of 0.2 to 4 mm, for example, 3 mm. The rated lighting power is about 20W.

As described above, a plurality of inverters 30 and other electrical components corresponding to each of the plurality of rare gas discharge lamps 11 are accommodated and arranged in the inverter accommodating portion 20.
In this example, the inverter accommodating portion 20 has an internal space defined in each of the three level positions L1, L2, and L3 having different separation distances in the direction perpendicular to the lamp arrangement surface S in which the rare gas discharge lamps 11 are arranged. A plurality of inverter accommodating chambers (hereinafter, the reference numeral “21” is attached except for the case where a specific one is described) is arranged with two separated in the axial direction of the rare gas discharge lamp 11. At the same time, the two are formed and configured so as to be arranged without gaps in the direction in which the rare gas discharge lamps 11 are arranged (left and right in FIG. 2).

The region between the inverter accommodating chambers 21 (A _{1 to} A ₃ ) and 21 (B _{1 to} B ₃ ) that are separated from each other in the axial direction of the rare gas discharge lamp 11 is configured by, for example, a blower fan 25 at the top. A cooling air supply mechanism is provided, and a plurality of flat cooling air passage partition walls 26 are arranged in parallel at predetermined intervals so as to extend along a plane perpendicular to the lamp central axis C of the rare gas discharge lamp 11. Thus, a plurality of independent cooling air passages 28 extending in a direction perpendicular to the lamp arrangement surface S are formed. Each cooling air passage 28 is communicated with the internal space of the corresponding lamp housing chamber 21 through a wind guide vent 23 formed in a central side wall 22A that partitions the inverter housing chamber 21. And in the side wall 22B opposite to the side wall 22A in which each of the lamp housing chambers 21 is formed with the air guide vent 23, an air exhaust vent 24 for discharging the cooling air from the lamp housing chamber 21 is formed. ing. Although not shown in the figure, the circulating air blowing system is constructed such that the warmed cooling air discharged from each lamp housing chamber 21 is introduced into the air blowing fan 25 through an appropriate heat exchanger. May be.

Each of the inverters 30 arranged in the inverter accommodating chamber 21 at each of the level positions L1, L2, and L3 located on the same side in the axial direction of the rare gas discharge lamp 11 is respectively in the axial direction of the corresponding rare gas discharge lamp 11. Is connected to the end portion on the same side, and a power feeding portion is formed. Specifically, the rare gas discharge lamp 11 is disposed in the inverter accommodating chambers 21A ₁ , 21A ₂ , 21A ₃ at the respective level positions L1, L2, L3 located on one end side (left side in FIG. 1) in the axial direction. Each of the inverters 30 is connected to a power supply line 18 on one end side, and this power supply line 18 is connected to one end (left end in FIG. 1) of the electrodes 14A and 14B in the axial direction of the rare gas discharge lamp 11. A power feeding unit is formed. On the other hand, inverters arranged in the inverter accommodating chambers 21B ₁ , 21B ₂ , 21B ₃ at the respective level positions L1, L2, L3 located on the other end side in the axial direction of the rare gas discharge lamp 11 (right side in FIG. 1). Each of 30 is connected to a power supply line 18 on the other end side, and this power supply line 18 is connected to the other end (right end in FIG. 1) of the electrodes 14A and 14B in the axial direction of the rare gas discharge lamp 11. Thus, a power feeding unit is formed. And the rare gas discharge lamp 11A in which the power feeding part is formed at one end in the axial direction and the rare gas discharge lamp 11B in which the power feeding part is formed at the other end in the axial direction are alternately positioned one by one. It is in a state.

Each of the inverters 30 is rarely positioned so that the level position where the inverter accommodating chamber 21 is located becomes farther from the lamp placement surface S so that the inverter 30 is positioned on the end side where the power feeding part is formed in the corresponding rare gas discharge lamp 11. The gas discharge lamp 11 is disposed in a displaced state in the axial direction. Specifically, the one end side of the inverter housing portion 20, in the lamp arrangement surface level position with respect to S of the lowest lower inverter accommodation chamber 21A _1, close to the side wall 22A of the air guide ventilation port 23 is formed position and the inverter 30 are disposed, in this inverter accommodation chamber higher level middle inverter accommodating chamber 21A in ₂ which is located at a position from 21A _1, for air exhaust from the inverter 30 of the lower inverter accommodating chamber 21A in ₁ to approach the side wall 22B of vents 24 are formed, the inverter 30 is displaced in the axial direction one end side of the rare gas discharge lamp 11 position is arranged, furthermore, a higher level position than the inverter accommodating chamber 21A ₂ inverter 30 of the upper inverter accommodation chamber 21A ₃ are located, the middle part of the inverter housing chamber 21A in ₂ The inverter 30 is arranged at a position displaced toward one end in the axial direction of the rare gas discharge lamp 11 so as to approach the side wall 22B where the exhaust vent 24 is formed from the inverter 30 of FIG. Similarly, in the other end side of the inverter housing portion 20, in the lower part of the inverter housing chamber 21B _1, and the inverter 30 is disposed at a position close to the side wall 22A of the air guide ventilation port 23 is formed, the middle of in the inverter accommodating chamber 21B in _2, to approach the side wall 22B of exhaust air vents 24 are formed from the inverter 30 of the lower inverter accommodation chamber 21B _1, on the other axial end side of the rare gas discharge lamp 11 displaced inverter 30 is disposed at a position further inverter 30 of the upper inverter accommodating chamber 21B in _3, side walls exhaust air vents 24 from the inverter 30 of the middle row of the inverter accommodating chamber 21B in ₂ is formed The inverter 30 is disposed at a position displaced toward the other axial end of the rare gas discharge lamp 11 so as to approach 22B.

If the specific structural example of said light irradiation apparatus is shown, as mentioned above, the number of the noble gas discharge lamps 11 is practically 20-40, for example, and the inverter arrange | positioned at one level position. The number of 30 is 10 at the maximum, and the separation distance (distance between the lamp center axes) between the adjacent rare gas discharge lamps 11 in the lamp housing 15 is, for example, 30 to 60 mm. In order to maintain the surface temperature of the solar cell panel 41 at, for example, around 60 ° C., the cooling air supplied by the blower fan 25 has a temperature of, for example, 30 to 50 ° C., and a flow rate of, for example, 0.3 to 2 m / sec. The amount is, for example, 4.4 to ³⁰ m ³ / min.

  The above-described light irradiation device is used as a light source of a solar cell panel weather resistance test device. For example, as shown in FIG. 5, a sun on which a lamp arrangement surface S in which a plurality of rare gas discharge lamps 11 are arranged is arranged on a stage 40. The battery panel 41 is disposed so as to face the battery panel 41 while being spaced apart from each other. Here, the separation distance between the light irradiation surface 41A of the solar cell panel 41 and the lamp arrangement surface S in the lamp unit 10 is 150 to 500 mm, for example, 300 mm.

In each rare gas discharge lamp 11, for example, when a high-frequency voltage is supplied to one electrode 14 </ b> A functioning as a high-voltage side electrode via an inverter 30, the glass material (dielectric material) constituting the arc tube 12 is interposed. Thus, a dielectric barrier discharge occurs in the inner space of the arc tube 12, excimer molecules are formed by the dielectric barrier discharge, and light emitted from the excimer molecules (172 nm vacuum ultraviolet light in the case of xenon gas) in the phosphor layer 13 The phosphor material is excited and, for example, ultraviolet rays in a wavelength range approximate to the ultraviolet region of sunlight are radiated to the solar cell panel 41 with an ultraviolet ray amount of about five times the maximum of sunlight.
On the other hand, the cooling air supplied by driving the blower fan 25 is introduced into each inverter accommodating chamber 21 via the cooling air passage 28 and also introduced into the lamp accommodating portion 15. The rare gas discharge lamp 11 and the inverter 30 are cooled.

  Thus, when used as a light source for a solar cell panel weather resistance test apparatus, a large number of rare gas discharge lamps 11 are required to radiate a predetermined amount of ultraviolet light to the solar cell panel 41. In addition, a plurality of inverters 30 corresponding to each of the rare gas discharge lamps 11 are required. However, according to the above-described light irradiation device, since the inverter accommodating portion 20 is configured by forming a plurality of inverter accommodating chambers 21 in a so-called hierarchical structure, it is possible to avoid an increase in the size of the light irradiation device. In addition, as the level position where the inverter accommodating chamber 21 is located is farther from the lamp placement surface S, the rare gas discharge is performed so that the corresponding rare gas discharge lamp 11 is positioned closer to the end where the power feeding portion is formed. By being arranged in a state of being displaced in the axial direction of the lamp 11, the difference in the length of the power supply line 18 that connects the rare gas discharge lamp 11 and the inverter 30 for each rare gas discharge lamp 11. Can be made as small as possible, so that variations in the ultraviolet radiation efficiency can be prevented from occurring due to the influence of the voltage drop due to the length of the feeder line 18; Rui can be suppressed small variations in UV radiation efficiency can emit ultraviolet desired radiation distribution.

In addition, since a plurality of inverters 30 are provided corresponding to each of the plurality of rare gas discharge lamps 11, for example, the design of a high-frequency transformer in the inverter 30 is facilitated and problems such as non-lighting occur. In this case, the rare gas discharge lamp 11 can be easily detected.
Furthermore, since the rare gas discharge lamp 11 is configured to cause the phosphor layer 13 to emit light by the action of ultraviolet rays (vacuum ultraviolet rays) in a predetermined wavelength region generated in the inner space of the arc tube 12, an extra light component. Is not radiated to the solar cell panel 41, so that the intended weather resistance test can be performed with high reliability.

[Second Embodiment]
FIG. 6 is a side view showing the outline of the configuration of an example of a light irradiation apparatus according to the second embodiment of the present invention, viewed from the direction in which the rare gas discharge lamps are arranged, and FIG. 7 is the light irradiation shown in FIG. It is the side view which looked at the apparatus from the arrow A direction (lamp central axis direction of a noble gas discharge lamp). Also in this example, for the sake of convenience, it is shown in a state where the number of rare gas discharge lamps (inverters) is smaller than the actual one.
The light irradiation device 10 has a substantially box-shaped casing 50 having a light emission opening 51 that opens downward, and a plurality of (in this example, 16) casings 50 are provided in a lower region in the casing 50. The rare gas discharge lamp 11 is formed with lamp housing portions 15 arranged in, for example, equidistant positions, with the lamp central axis C positioned in the same plane and extending in parallel with each other, and the casing 50. In the upper region of the lamp housing 15 in the inside, a plurality of (in this example, 16) inverters corresponding to each of the rare gas discharge lamps 11 (hereinafter referred to as “30” except for a specific case). Inverter accommodating portion 20 is formed.

  A cooling air supply mechanism composed of, for example, a blower fan 25 is provided at the upper central position of the casing 50, and cooling air is supplied to the lamp housing portion 15 in a region immediately below the blower fan 25 in the casing 50. Two cooling air passage partition walls 26A each defining a cooling air passage 28A for extending the air flow are arranged in parallel at a predetermined interval so as to extend along a plane perpendicular to the lamp central axis C of the rare gas discharge lamp 11. Thus, an air blowing system that supplies cooling air to the inverter housing portion 20 and an air blowing system that supplies cooling air to the lamp housing portion 15 are formed independently of each other. The cooling air supplied to the inverter accommodating portion 20 is discharged to the outside of the casing 50 through the exhaust air vents 24 formed on both side walls of the casing 50.

  In a position between the lamp accommodating portion 15 and the inverter accommodating portion 20 in the casing 50, for example, an air distribution adjusting mechanism 35 configured by a plate member in which a slit, a punch hole or the like is formed is provided. Each of the rare gas discharge lamps 11 can be cooled substantially uniformly by the supplied cooling air.

In the inverter accommodating part 20 in this example, four flat inverter fixing plates 32 (A ₁ , A ₂ ), 32 (B ₁ , B ₂ ) each having the same shape supply cooling air to the lamp accommodating part 15. The inverter fixing plates 32A ₂ are arranged in parallel with each other at a predetermined interval so as to extend in parallel with the cooling air passage partition wall 26A, two on each side of the cooling air passage 28A. (32B ₂ ) is in a state positioned vertically above the lamp placement surface S with respect to the inverter fixing plate 32A ₁ (32B ₁ ) located on the cooling air passage partition wall 26A side.

A plurality (four in this example) of inverters 30 are provided on the outer surfaces of the inverter fixing plates 32 (A ₁ , A ₂ , B ₁ , B ₂ ) (surfaces facing the side walls of the casing 50). At the same level position with respect to the arrangement surface S, they are arranged so as to be spaced apart in the direction in which the rare gas discharge lamps 11 are arranged. Inverter fixing plate _{32A 2} (32B 2) to each of which is provided an inverter _30A 2 which is located on both side walls of the casing 50 (30B _2), the inverter fixed plate which is located in the cooling air passage partition wall 26A side 32A ₁ is positioned (32B ₁₎ of each provided in the inverter _{30A 1} (32B 1) higher levels position L2 (> L1). Here, the separation distance between the inverters 30 arranged on one inverter fixing plate 32 (A ₁ , A ₂ , B ₁ , B ₂ ) is 5 to 15 mm, for example. A distance is secured.

The inverters 30 at the respective level positions located on the same side in the axial direction of the rare gas discharge lamp 11 with respect to the cooling air passage 28A are respectively connected to the end portions on the same side in the axial direction of the corresponding rare gas discharge lamp 11. A power feeding unit is formed by being connected. Specifically, the inverter 30 (A) at each level position located on one end side in the axial direction of the rare gas discharge lamp 11 (left side in FIG. 6) of the cooling air passage 28A for supplying the cooling air to the lamp housing portion 15. ₁ , A ₂ ), the power supply line 18 connected to the lower end side thereof is connected to one end (left end in FIG. 6) of the electrodes 14 A and 14 B in the axial direction of the rare gas discharge lamp 11 to form a power supply unit. Has been. On the other hand, each of the inverters 30 (B ₁ , B ₂ ) at each level position located on the other end side (the right side in FIG. 6) of the cooling air passage 28A in the axial direction of the rare gas discharge lamp 11 has its lower end side. Is connected to the other end (right end in FIG. 6) of the electrodes 14A and 14B in the axial direction of the rare gas discharge lamp 11 to form a power supply section. And the rare gas discharge lamp 11A in which the power feeding part is formed at one end in the axial direction and the rare gas discharge lamp 11B in which the power feeding part is formed at the other end in the axial direction are alternately positioned one by one. It is in a state.

  Also in the light irradiation apparatus according to the second embodiment, the same effect as that of the light irradiation apparatus according to the first embodiment can be obtained.

[Third Embodiment]
FIG. 8 is a side view showing the outline of the configuration of an example of a light irradiation apparatus according to the third embodiment of the present invention, viewed from the direction in which the rare gas discharge lamps are arranged, and FIG. 9 is the light irradiation shown in FIG. It is the side view which looked at the apparatus from the arrow A direction (lamp central axis direction of a noble gas discharge lamp). Also in this example, for the sake of convenience, it is shown in a state where the number of rare gas discharge lamps (inverters) is smaller than the actual one.
The light irradiation device 10 has a substantially box-shaped casing 50 having a light emission opening 51 that opens downward, and a plurality of (in this example, 16) casings 50 are provided in a lower region in the casing 50. The rare gas discharge lamp 11 is formed with lamp housing portions 15 arranged in, for example, equidistant positions, with the lamp central axis C positioned in the same plane and extending in parallel with each other, and the casing 50. In the upper region of the lamp housing portion 15 in the inside, an inverter housing portion 20 is formed in which a plurality of (in this example, 16) inverters 30 corresponding to the rare gas discharge lamps 11 are arranged.

  A cooling air supply mechanism composed of, for example, a blower fan 25 is provided at the upper central position of the casing 50, and cooling air is supplied to the lamp housing portion 15 in a region immediately below the blower fan 25 in the casing 50. Two cooling air passage partition walls 26A each defining a cooling air passage 28A for extending the air flow are arranged in parallel at a predetermined interval so as to extend along a plane perpendicular to the lamp central axis C of the rare gas discharge lamp 11. Thus, an air blowing system for supplying cooling air to the inverter housing portion 20 and an air blowing system for supplying cooling air to the lamp housing portion 15 are formed, which are independent of each other. The cooling air supplied to the inverter accommodating portion 20 is discharged to the outside of the casing 50 through the exhaust air vents 24 formed on both side walls of the casing 50.

  In a position between the lamp accommodating portion 15 and the inverter accommodating portion 20 in the casing 50, for example, an air distribution adjusting mechanism 35 configured by a plate member in which a slit, a punch hole or the like is formed is provided. Each of the rare gas discharge lamps 11 can be cooled substantially uniformly by the supplied cooling air.

In the inverter accommodating portion 20 in this example, four flat inverter fixing plates 32 (A ₁ , A ₂ ), 32 (B ₁ , B ₂ ) each having the same shape are positioned on both sides of the cooling air passage 28A. Two parallel positions along the lamp arrangement surface S at two level positions L1 and L2 that are different from each other in the direction perpendicular to the lamp arrangement surface S in which the rare gas discharge lamps 11 are arranged, two in each of the spaces. The inverter fixing plate 32A ₂ (32B ₂ ) provided so as to extend and located at the second level position L2 has a casing from the inverter fixing plate 32A ₁ (32B ₁ ) located at the first level position L1. The rare gas discharge lamp 11 is displaced in the axial direction so as to approach 50 side walls.

On the upper surface of each inverter fixing plate 32 (A ₁ , A ₂ , B ₁ , B ₂ ), a plurality (four in this example) of inverters 30 are separated in the direction in which the rare gas discharge lamps 11 are arranged. The inverters 30 arranged on the same side of the cooling air passage 28A in the axial direction of the rare gas discharge lamp 11 are arranged on the same side of the corresponding rare gas discharge lamp 11 in the axial direction. A power feeding portion is formed by being connected to the end portion of the. Specifically, each of the inverters 30 (A ₁ , A ₂ ) at each level position located on one end side (left side in FIG. 8) in the axial direction of the rare gas discharge lamp 11 has a power supply line 18 on one end side. The power supply line 18 is connected to one end (left end in FIG. 8) of the electrodes 14A and 14B in the axial direction of the rare gas discharge lamp 11 to form a power supply section. On the other hand, each of the inverters 30 (B ₁ , B ₂ ) at each level position located on the other end side in the axial direction of the rare gas discharge lamp 11 (right side in FIG. 8) is connected to the power supply line 18 on the other end side. The power supply line 18 is connected to the other ends (right ends in FIG. 8) of the electrodes 14A and 14B in the axial direction of the rare gas discharge lamp 11 to form a power supply section. And the rare gas discharge lamp 11A in which the power feeding part is formed at one end in the axial direction and the rare gas discharge lamp 11B in which the power feeding part is formed at the other end in the axial direction are alternately positioned one by one. It is in a state.

In one end of the inverter housing portion 20, each of the inverters 30A ₂ which is positioned at a second level position L2 is closer than each of the inverters 30A ₁ which is located on the first level position L1 on the side wall of the casing 50 As such, the rare gas discharge lamp 11 is disposed at a position displaced toward one end in the axial direction. Similarly, in the other end of the lamp accommodating portion 20, each of the inverters 30B ₂ that is positioned at a second level position L2 is the casing 50 from each of the inverters 30B ₁ that is located at a first level position L1 It arrange | positions in the position displaced to the axial direction other end side of the noble gas discharge lamp 11 so that it may approach a side wall.
Here, the separation distance between the inverters 30 arranged on one inverter fixing plate 32 (A ₁ , A ₂ , B ₁ , B ₂ ) is 5 to 15 mm, for example. A distance is secured.

  Also in the light irradiation apparatus according to the third embodiment, the same effect as that of the light irradiation apparatus according to the first embodiment can be obtained.

As mentioned above, although embodiment of this invention was described, this invention is not limited to said embodiment, A various change can be added.
For example, the rare gas discharge lamp 11 disposed in the lamp housing 15 is configured such that the plurality of rare gas discharge lamps 11 are arranged at the center axis of the lamp on each of the plurality of lamp arrangement surfaces having different level positions with respect to the light emission opening 51 of the casing 50. C may be arranged so as to extend in parallel with each other. 10 and 11, for example, 12 rare gas discharge lamps 11 are arranged in parallel at equal intervals, for example, on each of the first lamp arrangement surface S1 and the second lamp arrangement surface S2 having different level positions. The first rare gas discharge lamp group 11C arranged on the first lamp arrangement surface S1 is configured to be different from the second rare gas discharge lamp group 11D arranged on the second lamp arrangement surface S2. Thus, the rare gas discharge lamps 11 are relatively displaced in the direction in which they are arranged.

In the rare gas discharge lamp 11 of the first rare gas discharge lamp group 11C, a power feeding portion is formed at one end side (left side in FIG. 10) in the axial direction of the electrodes 14A and 14B. Each of the inverters 30 (A _{1 to} A ₃ ) positioned on one end side of the cooling air passage 28A that supplies the cooling air to the section 15 is supplied with the first noble gas via the power supply line 18 connected to the one end side. The discharge lamp group 11C is connected to one end of the electrodes 14A and 14B in the corresponding rare gas discharge lamp 11. Further, in the rare gas discharge lamp 11 of the second rare gas discharge lamp group 11D, a power feeding portion is formed at the other end side (right side in FIG. 10) in the axial direction of the electrodes 14A and 14B. Each of the inverters 30 (B _{1 to} B ₃ ) positioned on the other end side of the cooling air passage 28A that supplies the cooling air to the accommodating portion 15 is connected to the second end via the power supply line 18 connected to the other end side. It is connected to the other ends of the electrodes 14A and 14B in the corresponding rare gas discharge lamp 11 in the rare gas discharge lamp group 11D.

  10 and 11 show a configuration example of the light irradiation apparatus according to the third embodiment. In the light irradiation apparatuses according to the first embodiment and the second embodiment, a plurality of light irradiation apparatuses are used. The noble gas discharge lamps may be arranged in the lamp housing portion as described above.

  As shown in FIG. 12, the cooling air supply mechanism is a suction fan that sucks cooling air from the air introduction vent 23 formed on the side wall of the casing 50 and supplies the cooling air to each inverter 30 in the inverter accommodating portion 20. You may be comprised by 25A. FIG. 12 shows a configuration example of the light irradiation apparatus according to the second embodiment. In the light irradiation apparatuses according to the first embodiment and the third embodiment, such a suction fan is used. The cooling air supply mechanism may be used.

Furthermore, in the light irradiation device of the present invention, the above-described embodiment can be used as long as the length of the power supply line connecting the rare gas discharge lamp and the inverter is set to a substantially constant size. As described above, the feed line is connected so that the rare gas discharge lamp having the power feeding portion formed at one end and the rare gas discharge lamp having the power feeding portion formed at the other end are alternately arranged. It is not limited to the configuration.
Moreover, in the light irradiation apparatus which concerns on 1st Embodiment, it may be set as the structure by which the inverter of each level position is arrange | positioned in the position displaced in the direction where a noble gas discharge lamp is located in a line.

10 light irradiation device 11, 11A, 11B rare gas discharge lamp 11C, 11D rare gas discharge lamps 12 emitting tube 13 a phosphor layer 14A, 14B electrode 15 lamp accommodating portion 18 feed line 20 inverter accommodating portion 21, 21 _(A 1 ~ _{A 3), 21 (B 1} ~B 3) inverter accommodating chamber 22A, 22B side walls 23 wind guide ventilation port 24 exhaust air vents 25 blowing fan 25A suction fan 26,26A cooling air path partition walls 28, 28A, 28B cooling air passage _{30,30 (A 1, A 2)} , 30 (B 1, B 2) inverter 31 control unit _{32 (A 1, A 2)} , 32 (B 1, B 2) inverter fixing plate 35 blowing distribution adjusting Mechanism 40 Stage 41 Solar panel 41A Light irradiation surface 50 Casing 51 Light radiation opening

Claims (4)

A plurality of external electrode type rare gas discharge lamps arranged in a posture extending in parallel with each other, and the rare gas discharge lamp electrically connected to a power feeding portion formed at one end in the axial direction of the rare gas discharge lamp. And a plurality of inverters corresponding to each of the
In the plurality of inverters, the level position where the inverter is arranged becomes farther from the lamp arrangement surface at a plurality of level positions where the separation distances in the direction perpendicular to the lamp arrangement surface where the rare gas discharge lamps are arranged are different from each other. The light irradiation apparatus, wherein the light irradiation device is disposed in a state displaced in an axial direction of the rare gas discharge lamp so as to be positioned on an end portion side where a power feeding portion is formed in the axial direction of the gas discharge lamp. In one level position, two inverters are arranged apart from each other in the axial direction of the rare gas discharge lamp,
Inverters located on the same side in the axial direction of the rare gas discharge lamp at each level position are connected to the corresponding ends on the same side in the axial direction of the rare gas discharge lamp to form a power feeding section. The light irradiation apparatus according to claim 1.   The light irradiation device according to claim 2, wherein a cooling air passage extending in a direction perpendicular to the lamp arrangement surface is formed in a region between the two inverters.   The light irradiation apparatus according to claim 1, wherein the light irradiation apparatus is used for a solar cell panel weather resistance test apparatus.

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