JP2007329075A - High-pressure discharge lamp - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a long-life high-pressure discharge lamp free from devitrification for a long time, and capable of restraining degradation of luminance, damage or blowing out of an arc tube. <P>SOLUTION: The lamp is provided with a rotation mechanism rotating the arc tube 1 around its tube axis 1b, and a part (a top part 1a) of the arc tube 1 where temperature rises highest during lighting is to be shifted. The rotation mechanism is constituted of a motor 9, a worm gear 10, a gear 11 and a spur wheel 12, and is controlled by a rotation control circuit 14. The rotation control circuit 14 decides on driving timing and rotation angles for the arc tube 1 based on power on/off information, lighting time information and driving power information or the like of the arc tube 1 to control the rotation mechanism, and is constituted of a switch 15 putting on/off the arc tube 1, a CPU 16 calculating a driving timing and rotation angles, a memory 17 retaining lighting time information or the like, and a drive circuit 18 receiving signals outputted from the CPU 16 and driving the motor 9. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a high-pressure discharge lamp that is mainly incorporated in a reflecting mirror and used as a light source of an optical device used in a projector device or the like.

  Conventional high-pressure discharge lamps are mainly composed of a lamp unit including a light-emitting tube having a pair of electrodes opposed to each other in a sealed light-emitting space, and a reflector for condensing light, and a lighting device. The arc tube is filled with a rare gas such as argon and mercury and halides for increasing the luminous efficiency. In recent years, demands for miniaturization and higher output of projector devices and the like have increased, and a longer life of high-pressure discharge lamps has been demanded.

  The main determinants of the life of a high-pressure discharge lamp are the widening of the arc gap due to electrode consumption and the loss of transparency (translucency) of the arc tube due to the high temperature of the arc tube wall during lighting. It has become. In particular, devitrification occurs even in the absence of electrode consumption, and further devitrification proceeds due to heat absorption of the devitrified part, causing a decrease in luminance of the arc tube, and eventually resulting in damage and rupture. is there.

As a method for preventing the occurrence of devitrification, for example, in Patent Document 1, the average concentration of alkali metal in the surface region of the silica glass constituting the arc tube up to 1 μm from the outer surface is the depth from the outer surface. Is higher than the deep region deeper than 1 μm, so that the outer surface region of the arc tube is resistant to deformation and hardly scratched, and the inner surface region is less likely to be devitrified even under high temperature conditions. A high pressure mercury lamp is presented.
JP 2004-355874 A

  Thus, high pressure discharge lamps are required to prevent the occurrence of devitrification and maintain sufficient translucency over a long period of time. In patent document 1, although the time until devitrification can be extended using the silica glass which performed the special process as an arc_tube | light_emitting_tube material, the devitrification by long-term use is inevitable. Further, there is a demand for a method for preventing devitrification using a general arc tube material without using an arc tube material that has undergone special treatment.

  The present invention has been made to solve the above-described problems, and is a long-life high-pressure discharge lamp that does not cause devitrification over a long period of time and can suppress the occurrence of luminance reduction, breakage, or rupture of the arc tube. The purpose is to provide.

  The high-pressure discharge lamp according to the present invention forms a sealed light-emitting space, and the light-emitting space includes a light-emitting tube provided with a pair of electrodes facing in the direction of the tube axis, and the tube axis has a horizontal projection component. A high-pressure discharge lamp having an arc tube arranged therein, comprising: a rotation mechanism for rotating the arc tube around the tube axis; and a rotation control means for controlling the rotation mechanism. The angle is determined, and the arc tube is rotated based on the drive timing and the rotation angle.

  According to the present invention, the arc tube is rotated around its tube axis, and the portion with the highest temperature is moved while the arc tube is turned on, so that only the same portion of the arc tube becomes hot. As a result, a long-life high-pressure discharge lamp can be obtained in which devitrification does not occur over a long period of time, and it is possible to suppress the occurrence of luminance reduction, breakage, or rupture of the arc tube.

Embodiment 1 FIG.
The high-pressure discharge lamp according to the first embodiment of the present invention described below is used as a light source for a front or rear projection type projector using liquid crystal and a DMD element, an automobile headlamp, and the like. FIG. 1 is a schematic diagram showing a configuration of a high-pressure discharge lamp according to Embodiment 1 of the present invention, and a lamp unit portion including an arc tube is shown in a sectional view along a tube axis. An arc tube 1 that forms a sealed light emitting space is made of, for example, quartz glass, and includes an elliptical arc tube portion and sealing portions provided to extend outward from both ends of the arc tube portion. I have. The arc tube 1 is filled with a rare gas such as argon (Ar) and mercury and halides for increasing luminous efficiency.

  In the light emitting space of the arc tube 1, a pair of electrodes 19 facing each other in the direction of the tube axis 1 b are provided. In the pair of electrodes 19, a coil made of tungsten is wound around the tips of two cylindrical electrode rods made of tungsten to form a cathode and an anode. In addition, a metal foil made of thin strip-shaped molybdenum for electrically connecting the electrode rod and the wire 2 is embedded in the sealing portion.

  The reflector 6 reflects the light emitted from the arc tube 1 in a desired direction and guides it to the irradiation target portion. The reflector 6 is made of crystallized glass or borosilicate glass, and is mainly composed of an elliptical type and a parabolic type. Are used. In the case of the elliptical type, the arc tube 1 is arranged at the first collecting point, and the light from the arc tube 1 is collected at the second focal point. In the case of a paraboloid type, it becomes parallel light. These are appropriately selected depending on the configuration of the optical system.

  The arc tube 1 and the electrode 19 disposed therein are fixed to the reflector 6 with cement or the like, and supported so that the tube axis 1b is substantially horizontal. In the arc tube 1 thus supported, the temperature of the upper portion 1a of the arc tube 1 is highest due to the convection of the gas inside the arc tube 1 that occurs during lamp operation. Holes 6 a and 6 b for taking out the wire 2 are provided in the side wall and bottom of the reflector 6, respectively. The arc tube 1 is connected to the lamp power source 5 through the wire 2, the cable 3 and the connector 4.

  The lamp unit including the arc tube 1 and the reflector 6 is fixed to the replacement lamp house 7 so that the lamp can be easily replaced. The replacement lamp house 7 is attached to the lamp house 8.

  Further, in the present embodiment, a rotation mechanism that rotates the arc tube 1 around the tube axis 1b is provided. In the present embodiment, the rotation mechanism is composed of a motor 9, a worm gear 10, a gear 11 and a spur gear 12, and does not rotate only the arc tube 1, but a lamp unit composed of the arc tube 1 and the reflector 6, The replacement lamp house 7 is fixed together.

  The motor 9 is composed of a stepping motor or the like, and the rotation of the motor 9 is caused by a worm gear 10 attached to the motor 9 and a flat gear attached to the replacement lamp house 7 via a gear 11 combining a helical gear and a spur gear. It is transmitted to the gear 12. Further, the lamp house 8 is provided with a guide roller 13 for making the replacement lamp house 7 rotate more smoothly.

  These rotation mechanisms are controlled by a rotation control circuit 14 which is a rotation control means. The rotation control circuit 14 determines the drive timing and the rotation angle for the arc tube 1 by using the power on / off information of the arc tube 1, the rotation history information up to that point, the lighting time information, the driving power information, and the like as input information. The arc tube 1 is rotated based on the rotation angle. The switch 15 that turns the arc tube 1 on and off, the CPU 16 that calculates the drive timing and the rotation angle from input information such as the lighting time of the arc tube 1, and the lighting time. It comprises a memory 17 that holds information, rotation history information, drive power information, and the like, and a drive circuit 18 that receives a signal output from the CPU 16 and drives the motor 9.

  Next, the operation of the high pressure discharge lamp in the present embodiment will be described. FIG. 2 is a diagram showing a state in which a lamp unit composed of an arc tube and a reflector is rotated. In FIG. 2, (a) shows a rotation angle of 0 degree, and (b) shows a comparison with (a). When rotated 90 degrees clockwise, (c) is rotated 180 degrees clockwise compared to (a), (d) is 90 degrees counterclockwise compared to (a) (clockwise) 270 degrees). In this embodiment, the lamp unit and the replacement lamp house 7 for fixing the lamp unit are rotated together, but the replacement lamp house 7 is not shown in FIG. In FIG. 2D, the reason for rotating in the counterclockwise direction is to eliminate the twist of the cable 3 connecting the lamp power source 5 and the lamp unit.

  Experiments have shown that the time until devitrification occurs in the high-pressure discharge lamp varies depending on the driving power of the arc tube 1 when the air-cooling condition is constant. For example, when driving at 100 W, devitrification usually occurs after about 100 hours, when driving at 120 W, after several hundred hours. The position where devitrification occurs is usually the upper portion 1a of the arc tube 1 where the temperature becomes highest during lighting.

  Therefore, in the present embodiment, the arc tube 1 is rotated around its tube axis 1b to move the portion of the arc tube 1 (upper portion 1a) where the temperature becomes highest during lighting. However, since the light emission point is slightly shifted by rotating the arc tube 1, it appears as a luminance fluctuation on the screen of a projector or the like. Therefore, it is desirable to set the arc tube 1 so as not to rotate frequently but to rotate as little as possible.

  3 to 5 are diagrams showing a rotation control pattern of the high-pressure discharge lamp in the present embodiment. The angle in the figure with a minus sign is rotated counterclockwise, and the others are rotated clockwise. Is. FIG. 3 determines the driving timing for the arc tube 1 based on the power on / off information of the arc tube 1, and shows the rotation history information of the arc tube 1 up to that point, specifically the rotation angle at the previous and previous power-on times. The example which determines the present rotation angle based on this is shown. 4 and 5 show an example in which the driving timing for the arc tube 1 is determined based on the lighting time information of the arc tube 1, and the rotation angle is determined based on the rotation history information of the arc tube 1 so far. . 3 and 4 are four patterns of rotation angles of 0 degrees, 90 degrees, 180 degrees, and -90 degrees as shown in FIG. 2, and FIG. 5 shows the rotation angles in increments of 30 degrees. is there.

  In the example shown in FIG. 3, the CPU 16 of the rotation control circuit 14 uses the power-on / off information of the arc tube 1 stored in the memory 17 and the rotation history information so far as input information, and rotates at the previous and previous power-on times. The current rotation angle is determined from the angle, and is controlled to four patterns of 0 degree, 90 degrees, 180 degrees, and -90 degrees. In the case of a normal television or data projector, it is rare to energize for 24 hours, so this method is effective. Further, in this method, since the light emission point of the arc tube 1 does not shift during lighting, luminance fluctuation does not occur.

  In the example shown in FIG. 4, the CPU 16 of the rotation control circuit 14 uses the lighting time information of the arc tube 1 and the rotation history information stored so far stored in the memory 17 as input information, and drives the arc tube 1 based on this information. The timing and the rotation angle are determined and controlled to four patterns of 0 degree, 90 degrees, 180 degrees, and -90 degrees. Specifically, every time the lighting time exceeds 100 hours, the rotation angle is changed by 90 degrees. Similarly, in the example shown in FIG. 5, every time the lighting time exceeds 100 hours, the rotation angle is changed by 30 degrees. This method is effective for a monitor that requires energization for 24 hours. Although the luminance fluctuation occurs because the arc tube 1 is rotated during lighting, the influence of the luminance fluctuation can be suppressed by setting the rotation angle in increments of 30 degrees or reducing the frequency of rotation.

  In the examples shown in FIGS. 3 to 5, the driving timing for the arc tube 1 is controlled by the power on / off information or the lighting time information, but the time until devitrification varies depending on the driving power of the arc tube 1. The drive timing for the arc tube 1 may be controlled using the drive power as input information. When the driving power is large, the frequency of rotating the arc tube 1 can be increased, and when the driving power is small, the frequency of rotation can be decreased.

  Further, the driving timing and the rotation angle for the arc tube 1 may be controlled by combining the driving power information of the arc tube 1 and the power on / off information or the lighting time information. As described above, by controlling the driving timing and the rotation angle for the arc tube 1 by combining the driving power information, the power on / off information, and the lighting time information, the influence of the luminance variation can be suppressed to the minimum.

  As described above, according to the present embodiment, by rotating the arc tube 1 about its tube axis 1b, the portion (upper portion 1a) where the temperature becomes highest during lighting of the arc tube 1 is moved, Since only the same part of the arc tube 1 is not heated to a high temperature, devitrification does not occur for a long period of time, and a long-life high-pressure discharge that can suppress the decrease in luminance, breakage, or burst of the arc tube 1 is possible. A lamp is obtained. Furthermore, since devitrification can be prevented without performing special treatment on the material of the arc tube 1, a general arc tube material can be used.

  In the present embodiment, the rotation angle of the arc tube 1 is set to 0 degrees, 90 degrees, 180 degrees, -90 degrees, or 30 degrees, but the rotation angle can be freely set within a range of 360 degrees. it can. For example, you may control in the range of 0 degree-180 degree | times. In this case, the effect of preventing the occurrence of devitrification is slightly reduced, but there is an advantage that the rotation mechanism is simplified because the rotation angle is small. In the present embodiment, the high pressure discharge lamp is described in which the arc tube 1 is arranged so that the tube shaft 1b is substantially horizontal. However, the tube shaft 1b is not necessarily horizontal, and the tube shaft 1b is horizontal. What is necessary is just to arrange | position so that it may have a projection component. For example, the effect of the present invention can be obtained also in a high-pressure discharge lamp in which the arc tube 1 is disposed so that the tube axis 1b is inclined 45 degrees from the horizontal.

Embodiment 2. FIG.
In the first embodiment, in order to rotate the arc tube 1 around the tube axis 1b, the lamp unit composed of the arc tube 1 and the reflector 6 and the replacement lamp house 7 for fixing the lamp unit 1 are both used by the rotation mechanism. Although it is configured to rotate, only the arc tube 1 may be rotated by fixing the replacement lamp house 7 and the reflector 6. In the present embodiment, the rotating mechanism rotates the arc tube 1 without rotating the reflector 6.

  The configuration and arrangement of the rotation mechanism in the present embodiment are different from those in the first embodiment, but the same is true in that the rotation of the motor is transmitted to the arc tube 1 by combining gears and gears. However, when the reflector 6 is fixed and only the arc tube 1 is rotated, the wire 2 can be taken out from the same direction in order to prevent twisting due to the rotation of the two wires 2 connected to the arc tube 1. desirable. Specifically, the two wires 2 may be taken out from the bottom hole 6b without providing the hole 6a in the side wall of the reflector 6.

  The rotation control pattern in the case of rotating only the arc tube 1 is also the same as that in the first embodiment, and the description thereof is omitted (see FIGS. 3 to 5). Also in the present embodiment, the same effect as in the first embodiment can be obtained, and furthermore, the rotating object is lighter than in the first embodiment, so that the rotation mechanism can be simplified.

  The present invention can be applied to a front or rear projection type projector using a liquid crystal and a DMD element, an automobile headlamp, and the like.

It is the schematic which shows the structure of the high pressure discharge lamp in Embodiment 1 of this invention. It is a figure which shows rotation of the lamp unit of the high pressure discharge lamp in Embodiment 1 of this invention. It is a figure which shows the rotation control pattern of the high pressure discharge lamp in Embodiment 1 of this invention. It is a figure which shows the rotation control pattern of the high pressure discharge lamp in Embodiment 1 of this invention. It is a figure which shows the rotation control pattern of the high pressure discharge lamp in Embodiment 1 of this invention.

Explanation of symbols

1 arc tube, 1a top, 1b tube axis, 2 wires, 3 cables, 4 connectors,
5 Lamp power supply, 6 reflector, 6a, 6b hole, 7 replacement lamp house,
8 lamp house, 9 motor, 10 worm gear, 11 gear, 12 spur gear,
13 guide roller, 14 rotation control circuit, 15 switch, 16 CPU,
17 memory, 18 drive circuit, 19 electrodes.

Claims (7)

A sealed luminous space is formed, and the luminous space is provided with a luminous tube provided with a pair of electrodes facing in the direction of the tube axis, and the luminous tube is arranged so that the tube axis has a horizontal projection component. A high-pressure discharge lamp, comprising: a rotation mechanism for rotating the arc tube around the tube axis; and a rotation control means for controlling the rotation mechanism, wherein the rotation control means determines a drive timing and a rotation angle for the arc tube. A high pressure discharge lamp characterized by determining and rotating the arc tube based on the drive timing and the rotation angle. 2. The high-pressure discharge lamp according to claim 1, wherein the rotation control means determines the drive timing based on power on / off information of the arc tube. 2. The high pressure discharge lamp according to claim 1, wherein the rotation control means determines the drive timing based on lighting time information of the arc tube. 4. The high pressure discharge lamp according to claim 3, wherein the rotation control means determines the driving timing based on lighting time information of the arc tube and driving power information of the arc tube. Discharge lamp. 2. The high-pressure discharge lamp according to claim 1, wherein the rotation control means determines the rotation angle based on rotation history information of the arc tube until then. 2. The high pressure discharge lamp according to claim 1, further comprising a reflector for reflecting light from the arc tube, wherein the rotating mechanism rotates the reflector together with the arc tube. 2. The high-pressure discharge lamp according to claim 1, further comprising a reflector that reflects light from the arc tube, wherein the rotating mechanism rotates only the arc tube without rotating the reflector. High pressure discharge lamp.

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