JPH08250071A - Lamps and light sources - Google Patents

Abstract

(57) [Summary] [Purpose] When the light is placed in the condenser mirror and turned on, the opening of the condenser mirror does not cause cracks in the sealing tube located on the opening side of the condenser mirror. Provide a lamp with a low percentage of light blocked by the side cap.
To provide a light source device capable of efficiently irradiating an object to be irradiated with light emitted from a lamp without reducing the amount of light irradiated to the object to be irradiated. [Constitution] A lamp 10 of the present invention is a lamp arranged in a condenser mirror, and a base 15 on the opening side of the condenser mirror.
In addition, a fin member 20 having a fin extending parallel to the optical axis of the condenser mirror is provided.
The light source device of the present invention comprises a condenser mirror, a lamp arranged in the condenser mirror, and a cooling means for cooling the lamp.
It is a lamp of the present invention.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lamp and a light source device having the lamp.

[0002]

2. Description of the Related Art For example, in the manufacturing process of a liquid crystal panel,
As a light source for peripheral exposure of the panel, a light source device including an elliptical focusing mirror and a short arc type discharge lamp arranged in the elliptical focusing mirror is known.

FIG. 1 is an explanatory view showing a light source part which is a main part of such a light source device. Reference numeral 1 is an elliptical focusing mirror, and 2 is a discharge lamp. The discharge lamp 2 that constitutes this light source device has a bulb composed of a bulging portion 3 that forms a light emitting space and subsequent sealing tube portions 4 and 5, and bases 6 and 7 are provided at both ends of the bulb. Has been.

The discharge lamp 2 is arranged along the optical axis of the elliptical focusing mirror 1, and the emitted light from this discharge lamp 2 is
The object to be irradiated is irradiated through the elliptical focusing mirror 1 and an optical system (not shown) such as a mirror and a lens.

This light source device is provided with a cooling fan (not shown), and the cooling air generated by this cooling fan flows, for example, from the top side of the elliptical focusing mirror 1 toward the opening side (flow of cooling air). The direction is indicated by an arrow), whereby the elliptical focusing mirror 1 and the discharge lamp 2 are cooled.

[0006]

However, when the light source device as described above is used (when the discharge lamp is lit), the base of the discharge lamp (base 7 in FIG. 1) located on the opening side of the elliptical focusing mirror is The temperature is raised to about 220 to 250 ° C., and along with this, the temperature of the adjacent sealing pipe portion (sealing pipe portion 5 in FIG. 1) also reaches about 250 to 400 ° C. Then, when the temperature of the sealing tube rises to such a temperature, the molybdenum foil for power supply connection embedded in the sealing tube undergoes an oxidation reaction, and the volumetric expansion of the molybdenum foil accompanying the oxidation reaction causes sealing. There is a problem in that the tube portion is cracked, and the bulb of the discharge lamp is damaged. Such a problem becomes remarkable especially when a high-power lamp of 500 W or more is used.

In order to solve the above problems, the cooling effect is enhanced by increasing the amount of cooling air blown by the cooling fan, and the temperatures of the base and sealing tube located on the opening side of the elliptical focusing mirror are lowered. It is possible. However, by increasing the cooling effect, the temperature of the entire bulb of the discharge lamp is lowered, and it becomes impossible to completely evaporate the luminescent substance (for example, mercury) enclosed in the bulging portion of the bulb. Creates a new problem.

Further, by using a base of the discharge lamp located on the opening side of the elliptical focusing mirror that is larger than the base used in the past, the contact area with air (cooling air) is expanded. It is also possible to improve the heat radiation effect from the base. However, when a large base is used, the ratio of the light blocked by the base to the emitted light from the discharge lamp or the reflected light from the elliptical focusing mirror increases, and the amount of light irradiated to the irradiation target ( A new problem arises that the illuminance) decreases.

The present invention has been made based on the above circumstances. A first object of the present invention is to prevent damage such as cracks in the sealing tube portion located on the opening side of the light collecting mirror when the light is placed in the light collecting mirror and turned on. An object of the present invention is to provide a lamp in which the proportion of light blocked by the base on the opening side of the optical mirror is small. A second object of the present invention is to efficiently irradiate the object to be irradiated with the light emitted from the lamp without reducing the irradiation light amount to the object to be irradiated by incorporating such a lamp into the light source device. It is to provide a light source device capable of

[0010]

The lamp of the present invention is a lamp arranged in a condenser mirror, and extends in a base on the opening side of the condenser mirror in parallel with the optical axis of the condenser mirror. A fin member having a fin is attached. Further, the lamp of the present invention is a lamp arranged in a condenser mirror, and a fin extending parallel to an optical axis of the condenser mirror is formed on a base of the condenser mirror on an opening side. Is characterized by. The light source device of the present invention includes a condenser mirror, a lamp disposed in the condenser mirror, and a cooling mirror for cooling the lamp, from the opening side of the condenser mirror toward the top side or the condenser mirror. From the top side to the opening side of the lamp, the cooling means for generating cooling air flowing substantially parallel to the axial direction of the lamp is provided, and the lamp constituting the light source device is the lamp of the present invention. Characterize.

[0011]

[Action]

(1) Since the fins forming the lamp of the present invention have a large contact area with air (cooling air), the heat dissipation effect is high. Therefore, when the lamp of the present invention is placed in the condenser mirror and turned on, the temperatures of the base and the sealing tube located on the opening side of the condenser mirror can be sufficiently lowered. Does not cause damage such as cracks in parts. Also,
Since the fins that compose the lamp of the present invention extend parallel to the optical axis of the condenser mirror, most of the emitted light from the lamp light emitting portion and the reflected light from the condenser mirror are collected without being blocked by the fins. As a result, the light utilization rate hardly decreases.

(2) By bringing cooling air from the cooling means into contact with the fins of the lamp constituting the light source device of the present invention, the lamp base and sealing tube portion of the lamp located on the opening side of the condenser mirror are The temperature can be lowered sufficiently,
No damage such as cracks is generated in the sealing tube portion. Further, most of the light emitted from the lamp light emitting portion and the light reflected from the light collecting mirror are used without being blocked by the fins, so that the amount of light emitted to the object to be irradiated hardly decreases.

[0013]

Hereinafter, embodiments of the present invention will be described.
The scope of the present invention is not limited by these.

<The Lamp of the Present Invention> FIG. 2 is an explanatory view showing an example of the lamp of the present invention. Discharge lamp 1 of this embodiment
0 has a bulb 11 including a bulging portion 11A forming a light emitting space and sealing pipe portions 11B and 11C following the bulging portion 11A,
The cathode 12 and the anode 13 are arranged to face each other in the bulging portion 11A of the valve 11, and the bases 14 and
It is a short arc type lamp provided with 15. A fin member 20 is attached to the base 15 of the discharge lamp 10, which is a feature of the lamp of this embodiment.

FIGS. 3A and 3B are a plan view and a side view showing the fin member 20, respectively. The fin member 20 is composed of a circular pipe-shaped base holding portion 21 and five fins 22 formed so as to project in the radial direction of the base holding portion 21, which are made of aluminum,
It is integrally formed of a metal material having high thermal conductivity such as copper.

A base holding portion 21 constituting the fin member 20.
The height L is 0.5 to 1.5 times the height of the base 15 (length in the lamp axis direction). If the height L of the mouthpiece holder 21 is smaller than 0.5 times the height of the mouthpiece 15, it is not possible to secure a contact area with air (cooling air), and a sufficient heat dissipation effect can be obtained. Absent. Further, when the height L is larger than the height of the base 15 of 1.5, when the lamp is arranged in the condenser mirror and the lamp is turned on, the light emitted from the lamp light emitting portion and the condenser mirror emits light. The reflected light is easily blocked by the fins 22, and the light utilization rate is reduced.

The protruding length H of the fin 22 is determined by the base 15
The diameter is 0.2 to 1.5 times. When the protruding length H of the fin 22 is smaller than 0.2 times the diameter of the die 15, the contact area with the air (cooling air) cannot be secured and a sufficient heat dissipation effect cannot be obtained. Further, when the protrusion length H is larger than 1.5 times the diameter of the base 15, when the lamp is placed in the condenser mirror and the lamp is turned on, the light emitted from the lamp light emitting portion or the condenser mirror is emitted. The reflected light from the is easily blocked by the fins 22, and the light utilization rate decreases.

The fins 22 forming the fin member 20 have a wall thickness of 1 to 5 mm. When the wall thickness of the fin 22 is less than 1 mm, the thermal conductivity to the fin 22 is deteriorated, and a sufficient heat radiation effect cannot be obtained. If the wall thickness is larger than 5 mm, when the lamp is placed in the condenser mirror and the lamp is turned on, the fins 22 block the emitted light from the lamp emission section and the reflected light from the condenser mirror. As a result, the light utilization rate decreases.

A slit 23 extends from the outer peripheral surface of the mouthpiece holding portion 21 to the inner peripheral surface thereof, and the slit 23 is formed so as to extend in the height L direction of the mouthpiece holding portion 21.
Reference numerals 24 and 25 are small holes for jig attachment formed so as to face each other across the slit 23.

The fin member 20 is constructed as described above, and a jig is inserted into the small holes 24 and 25 to form the slit 2
The fin member 20 is expanded by opening the fin member 3. Then, when the fin member 20 is attached to the mouthpiece 15 through the opening of the slit 23 and the jig is removed, the inner peripheral surface of the mouthpiece holding portion 21 is moved to the mouthpiece 15 by the restoring force of the opened slit 23. The outer peripheral surface of the lamp is pressed, whereby the fin member 20 is attached to the base 15 of the lamp 10.

The inner peripheral surface of the mouthpiece holding portion 21 and the mouthpiece 1
When the outer peripheral surface of No. 5 is not in contact, it is preferable to fill the gaps on both surfaces with grease. Thereby, the heat conductivity from the base 15 to the fin member 20 is improved, and the cooling effect of the base 15 can be enhanced.

The fins 22 of the above-mentioned fin member 20
Has a large contact area with the air (cooling air), and thus has a high heat dissipation effect. Therefore, when the lamp of the present embodiment in which the fin member 20 is attached to the base 15 is arranged and turned on so that the base 15 is located on the opening side in the condenser mirror, the base 15 and sealing are performed. The temperature of the pipe portion 11C can be sufficiently lowered, and damage such as cracks does not occur in the sealing pipe portion 11C. Further, by disposing the lamp of this embodiment along the optical axis of the condenser mirror, the extending direction of the fins 22 coincides with the optical axis of the condenser mirror. Most of the reflected light from the mirror is collected without being blocked by the fins 22, and therefore the light utilization rate is hardly reduced.

In the present invention, the number of fins projecting from the mouthpiece holding portion is not particularly limited. For example, as shown in FIGS.
The fin member may be composed of six or eight fins. Further, the shape of the fin is not particularly limited.

In the lamp of the present invention, a fin disposed in the condenser mirror and located on the opening side may be integrally formed with a fin extending parallel to the optical axis of the condenser mirror. When the fin is formed on the base itself, the operation of attaching the fin member to the base and the operation of filling the grease are unnecessary, and since the base and the fin are integrally formed, heat transfer There is no loss, and the die temperature can be lowered more efficiently.

<Light Source Device of the Present Invention> Next, the light source device of the present invention will be described. FIG. 5: is explanatory drawing which shows an example of the light source device of this invention. In FIG. 5, 30 is a lamp house, 40 is an elliptical focusing mirror housed in the lamp house 30, 50 is a discharge lamp arranged along the optical axis in the elliptical focusing mirror 40, and 60 is a fin member. 70 is an air suction port, 81 and 82 are a pair of cold mirrors, 8
An optical unit 3 includes an integrator lens and the like.

The elliptical focusing mirror 40 is a concave reflecting mirror whose inner surface is coated with an ultraviolet reflecting layer.
The size of the opening of 0 varies depending on the size of the discharge lamp 50 and the like, but is, for example, 150 to 200 mm.

The discharge lamp 50 arranged in the elliptical focusing mirror 40 is a short arc type discharge lamp having the same structure as the discharge lamp 10 shown in FIG.
Reference numeral 1 is a bulging portion of the valve, 52 and 53 are sealing tube portions of the valve, and 54 and 55 are caps provided at both ends of the valve. The base 55 of the discharge lamp 50 includes
A fin member 60 having the same structure as the fin member 20 shown in FIG. 3 is attached.

The air suction port 70 is provided on the wall surface of the lamp house 30, and is connected to a suction type cooling fan (not shown) arranged outside the lamp house 30. By exhausting the air in the lamp house 30 from the air suction port 70, cooling air flowing from the top side to the opening side is generated in the elliptical focusing mirror 40 (cooling air in the lamp house 30). The flow direction is indicated by an arrow).

When the light source device of this embodiment is used (when the discharge lamp 50 is turned on), the light emitted from the discharge lamp 50 reaches the cold mirror 81 through the elliptical focusing mirror 40 or directly, and the cold light is emitted. It is reflected by the mirror 81, passes through the optical unit 83 and the cold mirror 82, and is irradiated onto the irradiation target S through the irradiation window 31 of the lamp house 30.

According to the light source device of the present embodiment, the fins of the fin member 60 are brought into contact with the cooling air generated by the cooling fan, so that the base 5 of the discharge lamp 50 is brought into contact.
5 and the temperature of the sealing tube portion 53 can be sufficiently lowered, the sealing tube portion 53 is not damaged such as cracks, and can be used stably until the lamp life. Further, most of the emitted light from the lamp light emitting portion and the reflected light from the condenser mirror reach the optical unit 83 without being blocked by the fins, so that the irradiation light amount to the irradiation target S does not decrease.

<Experimental Example> A light source device of the present invention having a structure as shown in FIG. 5 was manufactured. The specific configuration of this light source device is as follows.

[A] The size of the lamp house (30) is
The height is 560 mm, the width is 360 mm, the depth is 400 mm, and the internal volume is 80,640 cm ³ . [B] The size (diameter) of the opening of the elliptical focusing mirror (40) is 200 mm. [C] The discharge lamp (50) is a short arc type super high pressure mercury lamp as shown in FIG. 2, having a lamp input of 800 W, a bulb length of 45 mm, and a bulb outer diameter of 30 mm. A fin member (60) is attached to the base (55) located on the opening side of the elliptical focusing mirror. The fin member is made of aluminum, and the mouthpiece holding portion of the fin member has a height of 20 mm and an inner diameter of 13.
The thickness of the fins is 9 mm and the wall thickness is 2.5 mm. The five fins protruding from the mouthpiece holder have a wall thickness of 2 mm and a protruding length of 6
mm. [D] The amount of exhaust air from the air suction port (70), that is, the amount of cooling air blown by the cooling fan was set to 1 m ³ per second.

With respect to the above light source device, the cooling fan was operated, the discharge lamp was turned on, and the surface temperature of the base (55) after 30 minutes from the start of lighting was measured to be 153.7 ° C. . Further, when an illuminance meter was placed 4 mm away from the irradiation window (31) of the lamp house and the illuminance was measured, it was 1790 mW / cm ² . Further, the base temperature and the illuminance were measured in the same manner except that the fin members attached to the base (55) were changed to those shown in FIGS. 4A to 4D, and the base temperature was 157 to 170. C, illuminance is 1700 to 1
It was 900 mW / cm ² .

<Comparative Experimental Example> The cap temperature and the illuminance were measured in the same manner as in the above experimental example except that a discharge lamp having no fin member attached to the cap (55) was used. ℃, illuminance is 1850mW /
cm ² .

<Evaluation> From the above experimental examples and comparative experimental examples, the following can be understood. (1) By attaching the fin member to the base located on the opening side of the elliptical focusing mirror, the temperature of the base when the lamp is turned on can be reduced from 250 ° C to 170 ° C or lower. As described above, each fin member used in the experimental example has an excellent heat dissipation effect. (2) The reduction rate of the illuminance by attaching the fin member to the base is only 2 to 3%. In this way, if the fins of the fin member are configured to extend parallel to the optical axis of the elliptical focusing mirror, the light utilization rate is hardly affected. (3) Oxidation of the molybdenum foil embedded in the sealing tube and cracks in the sealing tube are prevented by the simple structure in which the fin member is attached to the mouthpiece located on the opening side of the elliptical focusing mirror. Therefore, the durability of the discharge lamp can be remarkably improved.

[0036]

Since the lamp of the present invention has fins excellent in heat dissipation effect, when the lamp is placed in the condenser mirror and turned on, it is caused by overheating such as cracks in the sealing tube. Do not damage the valve. Moreover, since the fins constituting the lamp of the present invention extend parallel to the optical axis of the condenser mirror, most of the emitted light from the lamp light emitting section and the reflected light from the condenser mirror are not blocked by the fins. Since the light is condensed, the light utilization rate is hardly reduced.

According to the light source device of the present invention, most of the emitted light from the lamp light emitting portion and the reflected light from the condenser mirror are used without being blocked by the fins, so that the irradiation light amount to the irradiation object is Almost no decrease. Therefore, the light emitted from the lamp can be efficiently applied to the irradiation target.

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing a main part of a conventional light source device.

FIG. 2 is an explanatory diagram showing an example of the lamp of the present invention.

FIG. 3 is a plan view and a side view showing an example of a fin member.

FIG. 4 is a plan view showing another example of the fin member.

FIG. 5 is an explanatory diagram showing an example of a light source device of the present invention.

[Description of sign]

 10 Discharge Lamp 11 Bulb 12 Cathode 13 Anode 14, 15 Cap 20 Fin Member 21 Cap Holder 22 Fin 23 Slit 24, 25 Small Hole 30 Lamp House 31 40 Elliptical Condensing Mirror 50 Discharge Lamp 51 Bulging Part 52, 53 Sealed Tube Part 54, 55 Base 60 Fin member 70 Air suction port 81, 82 Cold mirror 83 Optical unit

Claims (3)

[Claims] 1. A lamp arranged in a condenser mirror, wherein a fin member having a fin extending parallel to an optical axis of the condenser mirror is attached to a base on an opening side of the condenser mirror. A lamp characterized by that. 2. A lamp arranged in a condenser mirror, wherein a fin extending parallel to an optical axis of the condenser mirror is formed on a base of the condenser mirror on an opening side. A lamp to 3. A condenser mirror, a lamp arranged in the condenser mirror, and from the opening side to the top side of the condenser mirror, or the top portion of the condenser mirror for cooling the lamp. Side to the opening side, the cooling means for generating cooling air flowing substantially parallel to the axial direction of the lamp is provided, and the lamp is the lamp according to claim 1 or 2. Light source device.