JPH0572041U - High intensity lighting lamp - Google Patents

Abstract

(57) [Summary] [Structure] A glass which has a wavelength limit range of 350 to 430 nm in the bulb glass 12 or the bulb front glass 14 and has an ultraviolet ray cutting function with a wavelength inclination width of 20 nm or less. High-intensity lighting lamp formed by. [Effect] Prevents the UV damage of the member on the irradiated surface side.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a high-intensity illumination lamp that can efficiently cut an ultraviolet component from irradiation light emitted from a high-intensity light source and irradiate the surface to be irradiated with light.

[0002]

[Prior Art]

 Recently, high-intensity lighting lamps such as halogen lamps having a heat radiation source and metal halide lamps having a luminescence source are used as headlights and fog lamps for automobiles, or as display lighting and projection type. There are many examples of use as spot lighting lamps for LCD TVs and the like.

Further, in the high-intensity lighting lamp which is used in such a manner, the bulb glass and the front glass of the light bulb constituting the lamp are usually quartz glass, borosilicate glass and aluminum silicic acid. Glass such as glass that allows transmission of ultraviolet rays having a wavelength in the range of 250 to 400 nm is used.

Moreover, the high-brightness illumination lamps have been gradually increasing in illumination light density as their performance has been improved, and correspondingly, the irradiation density of ultraviolet rays emitted from the light source tends to be further increased.

On the other hand, in recent automobiles, there is a strong demand for reducing the air resistance of the vehicle body surface, and as a result, headlamps and fog lamps are also made of synthetic resin having the same height as the vehicle body surface. It is becoming increasingly common to find a product that uses a structure in which a manufactured outer cover is covered.

[0006]

[Problems to be solved by the device]

 By the way, when the high-intensity illumination lamp is used, it is possible to obtain an excellent effect in that the surface to be illuminated can be illuminated brighter than ever with the irradiation light.

However, when this kind of high-brightness illumination lamp is used as a headlamp of a passenger car or a spot illumination lamp of a display illumination or a projection type liquid crystal television, the irradiation density of irradiation light is further increased. As the radiation density increases, the ultraviolet rays that are increasing in density also pass through the bulb glass and the bulb front glass. Therefore, for example, the outer cover that covers the vehicle body surface of an automobile, the exhibits made of textile products such as clothing and the like arranged on the irradiated surface, and the liquid crystal panel that is essentially susceptible to deterioration by ultraviolet rays Since it was exposed to high-density ultraviolet rays, there were inconveniences that the transmitted ultraviolet rays deteriorated the quality performance of the members located on the surface to be irradiated, and caused fading. Further, in particular, since light having a wavelength of 315 nm or less is harmful to the human body, improvement in safety has been desired.

[0008]

[Means for Solving the Problems]

 The present invention has been made in view of the above problems in the prior art, and is aimed at providing a high-intensity illumination lamp capable of efficiently cutting ultraviolet rays and irradiating the irradiation surface with irradiation light. The characteristic feature of the structure is that high-intensity irradiation light emitted from a heat radiation light source or a luminescence light source is transmitted through the bulb glass and / or the bulb front glass to irradiate the surface to be illuminated. The above-mentioned bulb glass and / or the front glass of a light bulb is a high-intensity illuminating lamp, which has a transmission limit wavelength in the wavelength range of 350 to 430 nm and a wavelength inclination width of 20 nm or less. It is formed of glass having a function.

[0009]

[Action]

 For this reason, the irradiation light emitted from the light source of the high-intensity lighting lamp has its ultraviolet components efficiently cut by the bulb glass and / or the front glass of the bulb, and irradiates the irradiated surface. It is possible to protect the members located on the side from ultraviolet ray damage such as discoloration and quality deterioration, and to enhance their durability, and at the same time, prevent adverse effects on the human body.

[0010]

【Example】

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

FIG. 1 shows a part of a high-intensity illumination lamp according to the present invention in which high-intensity irradiation light emitted from a heat radiation source or a luminescence source is transmitted through a bulb glass to irradiate a surface to be illuminated. 2 is a cutaway sectional view, FIG. 2 is an enlarged front view of the halogen lamp of FIG. 1, and FIG. 3 is a front view of another metal halide lamp according to the present invention.

Of these, the high-intensity illumination lamp 11 shown in FIG. 1 incorporates a halogen lamp. In this halogen lamp, as shown in detail in FIG. 2, in addition to inert argon, a filling gas 16 such as iodine or bromine is filled in a bulb glass 12 with a base 21 to incandescently heat a tungsten filament 15. It is designed to be able to irradiate the dense light generated by incandescent light. The light emitted from this halogen lamp is formed so that it can be condensed by passing through the bulb front glass 14 while being reflected by the reflecting surface 13, and can be emitted to the illuminated surface side.

Further, the high-intensity lighting lamp 11 shown in FIG. 3 is a metal halide lamp that can be suitably used as a spot lighting lamp such as a display lighting and a projection type liquid crystal television because of its excellent color rendering properties. This is an example, and in a bulb glass 17 with a base 21, a quartz arc tube 18 in which argon, a metal halide, in addition to mercury is sealed, is arranged. The electrodes 19, 20 in the quartz arc tube 18 are arranged. The light emitted from the metal atoms decomposed in the mercury arc generated between the two is used as a luminescence light source to irradiate the surface to be illuminated, usually with a reflector (not shown). Further, a front glass (not shown) of a light bulb is also provided so that it can be used for intensive illumination in one direction.

In the high-intensity lighting lamp 11 thus formed, the bulb glass 12 or 17 and / or the bulb front glass 14 of the present invention has a transmission limit wavelength in the range of 350 to 430 nm. A glass material in the wavelength range having a wavelength inclination width of 20 nm or less and having an ultraviolet blocking function, that is, a glass material in which CuCl _x Br _1-x (x: 0 to 1.0) fine particles are deposited It is formed by that.

When a glass material in which such fine particles of CuCl _x Br _1-x (x: 0 to 1.0) are deposited is used, it is obtained because of the light absorbing action of the crystal particles themselves. It is possible to give the bulb glass 12 or 17 and / or the bulb front glass 14 an extremely sharp cut function with a wavelength inclination width of 20 nm or less in the ultraviolet region.

Further, the transmission limit wavelength of fine particle deposition glass is usually in the range of 350 to 380 nm for CuCl and in the range of 400 to 430 nm for CuBr, but the size of the fine particles deposited is controlled respectively. By doing so, the transmission limit wavelength can be controlled to be wider or narrower as desired.

Further, since CuCl and CuBr form a complete solid solution in the entire structure region, by precipitating fine particles of an arbitrary composition of CuCl _x Br _1-x (x: 0 to 1.0), The transmission limit wavelength can also be controlled within the range of 380 to 400 nm.

Therefore, by appropriately combining the above methods, a glass material having a transmission limit wavelength in the wavelength range of 350 to 430 nm can be formed.

As for the glass material used for forming the bulb glass constituting the present invention, any crystal material of CuCl _x Br _1-x (x: 0 to 1.0) may be deposited. It can be used without particular limitation.

Further, when forming the bulb glass 12 or 17 and / or the bulb front glass 14 having the above-mentioned ultraviolet ray cutting function, heat treatment is required after melting and shaping the glass material for precipitation of fine crystals. Therefore, the transmission limit wavelength and the wavelength inclination width can be controlled by controlling the size of the microcrystals to be precipitated by the heat treatment conditions.

The heat treatment in this case can be carried out, for example, after molding the bulb glass 12 or 17 and / or the bulb front glass 14 and gradually cooling, and also in an online slow cooling step after melting and shaping. It can also be carried out by precipitating fine crystals at the same time as the slow cooling operation. In any case, the production method is not limited in any way, and the well-known melting, forming, slow cooling and heat treatment steps are performed. Can be done with.

Further, the bulb glass according to the present invention can be formed as a hollow spherical body having an appropriate shape to cover the light source like the bulb glass 12 or 17 in the illustrated example, and can also be formed as a tubular body. In addition, it can be formed as an outer bulb for covering the lamp itself. Furthermore, the bulb front glass 14 can be formed into a desired shape such as a curved surface or a lens shape in addition to a flat surface by pressing.

Since the high-intensity illumination lamp 11 according to the present invention is configured in this way, it is emitted from the thermal radiation light source having the fragment 15 or the luminescence light source having the quartz arc tube 18 to the outside. The irradiation light to be emitted has a transmission limit wavelength in the wavelength range of 350 to 430 nm, and has a wavelength inclination width of 20 nm or less, and has a function of cutting ultraviolet rays. By passing through the front glass 14 of the light bulb, the ultraviolet ray component at the time of generation can be efficiently cut and radiated to the irradiated surface side, and this can be illuminated.

Therefore, a member made of a synthetic resin material or a fiber material, which is located on the surface to be irradiated side, is irradiated with light without being damaged by ultraviolet rays such as discoloration and deterioration of quality, and the durability of the member itself is dramatically improved. In particular, it will be possible to enjoy the lighting effects with high illumination light density.

FIG. 4 shows the radiant energy distribution measured by the method described below in order to confirm the ultraviolet blocking function using the high-intensity lighting lamp according to the present invention.

That is, an alkali borosilicate glass compounded to contain each of CuCl and CuBr in an amount of 1.0 wt% was melted at 1450 ° C. to form a tube, and then heat-treated at 500 ° C. for 1 hour to form a tubular body (valve Glass) formed.

The tubular body (bulb glass) thus obtained was covered with a commercially available metal halide lamp, and the distribution state of energy radiated through the tubular body (bulb glass) was measured.

In the figure, the solid line portion 2 between 300 and 400 nm of the distribution curve 1 is the radiant energy distribution when the metal halide lamp is not covered with the tubular body (bulb glass), and the broken line portion 3 is The radiant energy distribution when a tubular body (bulb glass) is covered with a metal halide lamp is shown.

Also from the figure, the bulb glass (tubular body) obtained by the above-mentioned manufacturing method has a transmission limit wavelength of 390 nm and an ultraviolet ray cutting function with a wavelength inclination width of 10 nm. It has been confirmed that the use of the bulb glass constituting the present invention makes it possible to efficiently cut the ultraviolet component from the irradiation light emitted from the light source.

[0030]

[Effect of the device]

 As described above, according to the present invention, the ultraviolet light emitted from the light source of the high-intensity lighting lamp is efficiently cut by the bulb glass and / or the bulb front glass to irradiate the surface to be illuminated. Therefore, it is possible to protect the member located on the irradiated surface side from ultraviolet damage such as discoloration and quality deterioration, and improve its durability, and at the same time, prevent adverse effects on the human body.

[Submission date] October 9, 1992

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a high-intensity illumination lamp that can efficiently cut an ultraviolet component from irradiation light emitted from a high-intensity light source and irradiate the surface to be irradiated with light.

[0002]

[Prior Art]

 Recently, high-intensity lighting lamps such as halogen lamps having a heat radiation source and metal halide lamps having a luminescence source are used as headlights and fog lamps for automobiles, or as display lighting and projection type. There are many examples of use as spot lighting lamps for LCD TVs and the like.

Further, in the high-intensity lighting lamp which is used in such a manner, the bulb glass and the front glass of the light bulb constituting the lamp are usually quartz glass, borosilicate glass and aluminum silicic acid. Glass such as glass that allows transmission of ultraviolet rays having a wavelength in the range of 250 to 400 nm is used.

Moreover, the high-brightness illumination lamps have been gradually increasing in illumination light density as their performance has been improved, and correspondingly, the irradiation density of ultraviolet rays emitted from the light source tends to be further increased.

On the other hand, in recent automobiles, there is a strong demand for reducing the air resistance of the vehicle body surface, and as a result, headlamps and fog lamps are also made of synthetic resin having the same height as the vehicle body surface. It is becoming increasingly common to find a product that uses a structure in which a manufactured outer cover is covered.

[0006]

[Problems to be solved by the device]

 By the way, when the high-intensity illumination lamp is used, it is possible to obtain an excellent effect in that the surface to be illuminated can be illuminated brighter than ever with the irradiation light.

However, when this kind of high-brightness illumination lamp is used as a headlamp of a passenger car or a spot illumination lamp of a display illumination or a projection type liquid crystal television, the irradiation density of irradiation light is further increased. As the radiation density increases, the ultraviolet rays that are increasing in density also pass through the bulb glass and the bulb front glass. Therefore, for example, the outer cover that covers the vehicle body surface of an automobile, the exhibits made of textile products such as clothing and the like arranged on the irradiated surface, and the liquid crystal panel that is essentially susceptible to deterioration by ultraviolet rays Since it was exposed to high-density ultraviolet rays, there were inconveniences that the transmitted ultraviolet rays deteriorated the quality performance of the members located on the surface to be irradiated, and caused fading. Further, in particular, since light having a wavelength of 315 nm or less is harmful to the human body, improvement in safety has been desired.

[0008]

[Means for Solving the Problems]

 The present invention has been made in view of the above problems in the prior art, and is aimed at providing a high-intensity illumination lamp capable of efficiently cutting ultraviolet rays and irradiating the irradiation surface with irradiation light. The characteristic feature of the structure is that high-intensity irradiation light emitted from a heat radiation light source or a luminescence light source is transmitted through the bulb glass and / or the bulb front glass to irradiate the surface to be illuminated. The above-mentioned bulb glass and / or the front glass of a light bulb is a high-intensity illuminating lamp, which has a transmission limit wavelength in the wavelength range of 350 to 430 nm and a wavelength inclination width of 20 nm or less. It is formed of glass having a function.

[0009]

[Action]

 For this reason, the irradiation light emitted from the light source of the high-intensity lighting lamp has its ultraviolet components efficiently cut by the bulb glass and / or the front glass of the bulb, and irradiates the irradiated surface. It is possible to protect the members located on the side from ultraviolet ray damage such as discoloration and quality deterioration, and to enhance their durability, and at the same time, prevent adverse effects on the human body.

[0010]

【Example】

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

FIG. 1 shows a part of a high-intensity illumination lamp according to the present invention in which high-intensity irradiation light emitted from a heat radiation source or a luminescence source is transmitted through a bulb glass to irradiate a surface to be illuminated. 2 is a cutaway sectional view, FIG. 2 is an enlarged front view of the halogen lamp of FIG. 1, and FIG. 3 is a front view of another metal halide lamp according to the present invention.

Of these, the high-intensity illumination lamp 11 shown in FIG. 1 incorporates a halogen lamp. In this halogen lamp, as shown in detail in FIG. 2, in addition to inert argon, a filling gas 16 such as iodine or bromine is filled in a bulb glass 12 with a base 21 to incandescently heat a tungsten filament 15. It is designed to be able to irradiate the dense light generated by incandescent light. The light emitted from the halogen lamp is formed so that it can be condensed by passing through the bulb front glass 14 while being reflected by the reflection surface 13 and emitted to the surface to be illuminated.

Further, the high-intensity lighting lamp 11 shown in FIG. 3 is a metal halide lamp that can be suitably used as a spot lighting lamp such as a display lighting and a projection type liquid crystal television because of its excellent color rendering properties. This is an example, and in a bulb glass 17 with a base 21, a quartz arc tube 18 in which argon, a metal halide, in addition to mercury is sealed, is arranged. The electrodes 19, 20 in the quartz arc tube 18 are arranged. The light emitted from the metal atoms decomposed in the mercury arc generated between the two is used as a luminescence light source to irradiate the surface to be illuminated, usually with a reflector (not shown). Further, a front glass (not shown) of a light bulb is also provided so that it can be used for intensive illumination in one direction.

In the high-intensity lighting lamp 11 thus formed, the bulb glass 12 or 17 and / or the bulb front glass 14 of the present invention has a transmission limit wavelength in the range of 350 to 430 nm. A glass material in the wavelength range having a wavelength inclination width of 20 nm or less and having an ultraviolet blocking function, that is, a glass material in which CuCl _x Br _1-x (x: 0 to 1.0) fine particles are deposited It is formed by that.

When a glass material in which such fine particles of CuCl _x Br _1-x (x: 0 to 1.0) are deposited is used, it is obtained because of the light absorbing action of the crystal particles themselves. It is possible to give the bulb glass 12 or 17 and / or the bulb front glass 14 an extremely sharp cut function with a wavelength inclination width of 20 nm or less in the ultraviolet region.

Further, the transmission limit wavelength of fine particle deposition glass is usually in the range of 350 to 380 nm for CuCl and in the range of 400 to 430 nm for CuBr, but the size of the fine particles deposited is controlled respectively. By doing so, the transmission limit wavelength can be controlled to be wider or narrower as desired.

Further, since CuCl and CuBr form a complete solid solution in the entire structure region, by precipitating fine particles of an arbitrary composition of CuCl _x Br _1-x (x: 0 to 1.0), The transmission limit wavelength can also be controlled within the range of 380 to 400 nm.

Therefore, by appropriately combining the above methods, it is possible to form a glass material having a transmission limit wavelength in the wavelength range of 350 to 430 nm.

As for the glass material used for forming the bulb glass constituting the present invention, any crystal material of CuCl _x Br _1-x (x: 0 to 1.0) may be deposited. It can be used without particular limitation.

Further, when forming the bulb glass 12 or 17 and / or the bulb front glass 14 having the above-mentioned ultraviolet ray cutting function, heat treatment is required after melting and shaping the glass material for precipitation of fine crystals. Therefore, the transmission limit wavelength and the wavelength inclination width can be controlled by controlling the size of the microcrystals to be precipitated by the heat treatment conditions.

The heat treatment in this case can be carried out, for example, after molding the bulb glass 12 or 17 and / or the bulb front glass 14 and gradually cooling, and also in an online slow cooling step after melting and shaping. It can also be carried out by precipitating fine crystals at the same time as the slow cooling operation. In any case, the production method is not limited in any way, and the well-known melting, forming, slow cooling and heat treatment steps are performed. Can be done with.

Further, the bulb glass according to the present invention can be formed as a hollow spherical body having an appropriate shape to cover the light source like the bulb glass 12 or 17 in the illustrated example, and can also be formed as a tubular body. In addition, it can be formed as an outer bulb for covering the lamp itself. Furthermore, the bulb front glass 14 can be formed into a desired shape such as a curved surface or a lens shape in addition to a flat surface by pressing.

Since the high-intensity illumination lamp 11 according to the present invention is configured in this way, it is emitted from the thermal radiation light source having the filament 15 or the luminescence light source having the quartz arc tube 18 to the outside. The irradiation light to be applied has a transmission limit wavelength in a wavelength range of 350 to 430 nm and has a wavelength inclination width of 20 nm or less, and has a UV cut function and has a bulb glass 12 or 17 and / or a bulb front glass. By passing through 14, it is possible to efficiently cut the ultraviolet ray component at the time of generation and irradiate it on the surface to be irradiated and illuminate it.

Therefore, a member made of a synthetic resin material or a fiber material, which is located on the surface to be irradiated side, is irradiated with light without being damaged by ultraviolet rays such as discoloration and deterioration of quality, and the durability of the member itself is dramatically improved. In particular, it will be possible to enjoy the lighting effects with high illumination light density.

FIG. 4 shows the radiant energy distribution measured by the method described below in order to confirm the ultraviolet blocking function using the high-intensity lighting lamp according to the present invention.

That is, an alkali borosilicate glass compounded to contain each of CuCl and CuBr in an amount of 1.0 wt% is melted at 1450 ° C. to form a tube, and then heat-treated at 500 ° C. for 1 hour to form a tubular body (bulb). Glass) formed.

The tubular body (bulb glass) thus obtained was covered with a commercially available metal halide lamp, and the distribution state of energy radiated through the tubular body (bulb glass) was measured.

In the figure, the solid line portion 2 between 300 and 400 nm of the distribution curve 1 is the radiant energy distribution when the metal halide lamp is not covered with the tubular body (bulb glass), and the broken line portion 3 is , Shows the radiant energy distribution when a metal halide lamp is covered with a tubular body (bulb glass).

Also from the figure, the bulb glass (tubular body) obtained by the above-mentioned manufacturing method has a transmission limit wavelength of 390 nm and an ultraviolet ray cutting function with a wavelength inclination width of 10 nm. It has been confirmed that the use of the bulb glass constituting the present invention makes it possible to efficiently cut the ultraviolet component from the irradiation light emitted from the light source.

[0030]

[Effect of the device]

 As described above, according to the present invention, the ultraviolet light emitted from the light source of the high-intensity lighting lamp is efficiently cut by the bulb glass and / or the bulb front glass to irradiate the surface to be illuminated. Therefore, it is possible to protect the member located on the irradiated surface side from UV damage such as discoloration and quality deterioration, and enhance its durability, and at the same time, prevent adverse effects on the human body.

[Brief description of drawings]

FIG. 1 is a partially cutaway sectional view of a high-intensity illumination lamp incorporating a halogen lamp according to the present invention.

FIG. 2 is an enlarged front view of the halogen lamp shown in FIG.

FIG. 3 is a front view of a metal halide lamp according to the present invention.

FIG. 4 is a graph showing a comparison of UV light component cut states between a high-intensity illumination lamp formed using a bulb glass and a high-intensity illumination lamp formed using a conventional bulb glass according to the present invention.

[Explanation of symbols]

 1 Distribution curve 2 Solid line part 3 Broken line part 11 High-intensity illumination lamp 12 Bulb glass 13 Reflective surface 14 Light bulb front glass 15 Tungsten filament 16 Encapsulated gas 17 Bulb glass 18 Quartz arc tube 19 Electrode 20 Electrode 21 Base

[Procedure amendment]

[Submission date] October 9, 1992

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

[Name of device] High-intensity lighting lamp

[Scope of utility model registration request]

[Brief description of drawings]

FIG. 1 is a partially cutaway sectional view of a high-intensity illumination lamp incorporating a halogen lamp according to the present invention.

FIG. 2 is an enlarged front view of the halogen lamp shown in FIG.

FIG. 3 is a front view of a metal halide lamp according to the present invention.

FIG. 4 is a graph showing a comparison of UV light component cut states between a high-intensity illumination lamp formed using a bulb glass and a high-intensity illumination lamp formed using a conventional bulb glass according to the present invention.

[Explanation of symbols] 1: Distribution curve 2: Solid line part 3: Broken line part 11: High-brightness illumination lamp 12: Bulb glass 13: Reflective surface 14: Light bulb front glass 15: Tungsten filament 16: Enclosed gas 17: Bulb glass 18: Quartz arc tube 19: Electrode 20: Electrode 21: Base

Claims (1)

[Scope of utility model registration request] 1. A high-brightness illumination lamp, wherein high-brightness irradiation light emitted from a thermal radiation light source or a luminescence light source is transmitted through a bulb glass and / or a bulb front glass to irradiate the surface to be illuminated. , The bulb glass and / or the bulb front glass has a transmission limit wavelength of 350 to 4
A high-intensity illumination lamp, which is formed of glass having a wavelength range of 30 nm and a wavelength inclination width of 20 nm or less and having an ultraviolet blocking function.