JP5629985B2 - Discharge lamp device - Google Patents

Description

  The present invention relates to a discharge lamp device comprising a double tube lamp having a discharge lamp and an ultraviolet radiation auxiliary light source in an outer tube, and a reflecting mirror.

  In the lighting field, a discharge lamp having a luminous tube made of translucent ceramics has been developed, which has advantages of longer life and higher efficiency than a quartz glass arc tube, and is enclosed in the arc tube. In order to stably evaporate the luminescent substance, the outside air and the discharge lamp are shut off, and the entire discharge lamp is hermetically arranged in a translucent outer tube in order to prevent the arc tube from being cooled beyond the set conditions. A double tube lamp structure is known.

Such a double tube lamp is incorporated in a reflecting mirror and used as a discharge lamp device in order to control the direction of emitted light.
Such a technique is described in Japanese Patent Application Laid-Open No. 2002-110100.

On the other hand, in order to improve the startability of the discharge lamp, a technique for irradiating the discharge space with ultraviolet rays when starting the lamp is known.
In order to radiate ultraviolet rays, an ultraviolet radiation auxiliary light source is used separately from the discharge lamp. Such a technique is described in Patent Document 2 (Japanese Patent Laid-Open No. 2002-151006).
Patent Document 2 describes a double tube lamp structure in which a discharge lamp and an ultraviolet radiation auxiliary light source are hermetically arranged in an outer tube.

FIG. 5 is an explanatory diagram of a discharge lamp device comprising a double tube lamp and a reflecting mirror in which a discharge lamp and an ultraviolet radiation auxiliary light source are hermetically arranged in an outer tube.
As shown in FIG. 5, the discharge lamp device includes a discharge lamp 1 having a pair of electrodes 11 and 12 and an ultraviolet radiation auxiliary light source 2 that emits light when the discharge lamp 1 is turned on in a translucent outer tube 3. It consists of a double tube lamp 4 and a reflecting mirror 5 that are hermetically arranged.

The reflecting mirror 5 has a front opening 51 that emits light and a neck opening 52 into which the outer tube 3 is inserted.
Reference numeral 8 denotes a front glass that closes the front opening 51.

  In such a discharge lamp device, the arrangement position of the ultraviolet radiation auxiliary light source 2 is not particularly considered, and the ultraviolet radiation auxiliary light source 2 is simply disposed in the outer tube 3 and in the vicinity of the discharge lamp 1. It had been.

Then, a part of the ultraviolet radiation auxiliary light source 2 has a front opening of the reflecting mirror 5 with respect to a virtual line L connecting the tip of the electrode 11 positioned on the neck opening 52 side of the reflecting mirror 5 and the opening edge 5a of the neck opening 52. In this case, the light emitted from the discharge lamp 1 and originally irradiated on the reflecting surface of the reflecting mirror 5 is shielded by a part of the ultraviolet radiation auxiliary light source 2, and the irradiation surface There was a problem that the distribution of light distribution was disturbed.
JP 2002-110100 A JP 2002-151006 A

  The present invention has been made in view of the above-described problems, and an object of the present invention is to provide a discharge lamp device that improves startability and has excellent light distribution characteristics on an irradiation surface. .

The discharge lamp device according to claim 1 includes a discharge lamp in which a pair of electrodes are opposed to each other in an arc tube and sealing portions are formed at both ends, and an ultraviolet radiation auxiliary light source that emits light when the discharge lamp is turned on. In the discharge lamp apparatus comprising: a double tube lamp hermetically disposed in a light outer tube; a reflecting mirror surrounding the double tube lamp and reflecting light emitted from the double tube lamp; The radiation auxiliary light source includes a container having a cavity filled with a rare gas and a seal part. One side of the metal foil extends into the cavity of the container, and the other side of the metal foil is hermetically sealed by the seal part. A linear outer conductor wound around the outer surface of the container, and the reflecting mirror has a front opening for emitting light and a neck opening into which the outer tube is inserted , and seals one of the discharge lamps. Of the stop and the ultraviolet radiation auxiliary light source It is said is arranged to be positioned within the neck of the reflector, the UV radiation auxiliary light source, to a virtual surface connecting the periphery of the opening of the discharge lamp the neck opening and the electrode tip located on the side the neck opening of the The reflecting mirror is disposed on the side opposite to the front opening side.

  The discharge lamp device according to claim 2 is the discharge lamp device according to claim 1, and in particular, a longitudinal axis of the ultraviolet radiation auxiliary light source intersects with an electrode axis connecting each electrode of the discharge lamp. It is characterized by that.

  The discharge lamp device of the present invention includes a double tube lamp in which a discharge lamp and an ultraviolet radiation auxiliary light source are hermetically disposed in a translucent outer tube, and a reflecting mirror that reflects light emitted from the double tube lamp. The reflecting mirror has a front opening that emits light and a neck opening into which the outer tube is inserted, and the ultraviolet radiation auxiliary light source has an electrode tip positioned on the neck opening side of the discharge lamp and an opening periphery of the neck opening. Since it is arranged on the opposite side to the front opening side of the reflecting mirror with respect to the virtual surface to be connected, the light irradiated on the reflecting surface of the reflecting mirror is not blocked by the ultraviolet radiation auxiliary light source, The distribution of light distribution is not disturbed.

  Furthermore, since the discharge lamp apparatus of the present invention intersects the longitudinal axis of the ultraviolet radiation auxiliary light source and the electrode axis connecting the respective electrodes of the discharge lamp, the ultraviolet radiation emitted from the ultraviolet radiation auxiliary light source is efficiently obtained. It can radiate towards the discharge lamp.

It is explanatory drawing of the discharge lamp apparatus of this invention. It is explanatory drawing of the double tube type lamp used for the discharge lamp apparatus of this invention. It is explanatory drawing of the ultraviolet radiation auxiliary light source of the double tube type lamp used for the discharge lamp apparatus of this invention. It is explanatory drawing of the other double tube type lamp used for the discharge lamp apparatus of this invention. It is explanatory drawing of the conventional discharge lamp apparatus.

FIG. 1 is an explanatory view of a discharge lamp device of the present invention.
The discharge lamp device according to the present invention is made of quartz glass. The discharge lamp 1 has a pair of electrodes 11 and 12 disposed opposite to each other in an arc tube 10 and an ultraviolet radiation auxiliary light source 2 that emits light when the discharge lamp 1 is turned on. A double tube lamp 4 hermetically arranged in a translucent outer tube 3, and a reflecting mirror 5 surrounding the double tube lamp 4 and reflecting light emitted from the double tube lamp 4. is there.
The reflecting mirror 5 has a front opening 51 that emits light and a neck opening 52 into which the outer tube 3 is inserted. A base 7 on which a spiral base 6 is formed is attached to the neck 50 of the reflecting mirror 5, and the outer tube 3 of the double tube lamp 4 is fixed to the base 7 through the neck opening 52. Yes.
Both the sealing part of the discharge lamp and the ultraviolet radiation auxiliary light source 2 are arranged so as to be located in the neck part 50 of the reflecting mirror 5.
Reference numeral 8 denotes a front glass that closes the front opening of the reflecting mirror 5.

FIG. 2 is an explanatory view showing only a double tube lamp.
In the discharge lamp 1, a pair of electrodes 11, 12 made of tungsten or the like is disposed in an arc tube 10 made of a translucent ceramic container such as polycrystalline alumina or YAG, and protrudes from sealing portions at both ends of the arc tube 10. The external leads 13a and 13b are connected to power supply members 14a and 14b arranged in the outer tube 3, respectively.
The power supply members 14a and 14b are connected to the molybdenum metal foils 15a and 15b at the seal portion 3a of the outer tube 3, and the molybdenum metal foils 15a and 15b are connected to the external power supply members 16a and 16b, respectively.
The outer tube 3 is evacuated, and although not shown, a getter member that adsorbs impure gas may be disposed in the outer tube 3.

  An ultraviolet radiation auxiliary light source 2 is disposed in the outer tube 3, and the ultraviolet radiation auxiliary light source 2 includes a hermetically sealed quartz glass container 21 and a metal foil 22 disposed in the container 21. The external leads 23 connected to the metal foil 22 and projecting to the outside and the linear external conductors 24 wound around the outer surface of the container 21 are provided. The external leads 23 and the linear external conductors 24 are discharged. It is connected to power supply members 14a and 14b arranged in the outer tube 3 so as to be in parallel with the external leads 13a and 13b of the lamp 1.

FIG. 3 is an explanatory view showing only the ultraviolet radiation auxiliary light source.
The container 21 of the ultraviolet radiation auxiliary light source 2 includes a hollow portion 21a in which a rare gas is sealed and a seal portion 21b.
A metal foil 22 is disposed in the container 21, one side of the metal foil 22 extends into the cavity 21a, and the other side of the metal foil 22 is hermetically sealed with a seal portion 21b.
An external lead 23 is connected to the other end of the metal foil 22, and the external lead 23 projects outward from the seal portion 21b.
A linear outer conductor 24 is densely wound around the cavity 21a and the seal 21b outside the container 21 by a plurality of turns.

  The external lead 23 of the ultraviolet radiation auxiliary light source 2 is electrically connected to the external lead 13a of the discharge lamp 1, and the linear external conductor 24 of the ultraviolet radiation auxiliary light source 2 is electrically connected to the external lead 13b of the discharge lamp 1. Thus, the start voltage when the discharge lamp 1 is turned on is applied to the external lead 23 and the linear external conductor 24 of the ultraviolet radiation auxiliary light source 2, and the metal foil in the container 21 A dielectric barrier discharge occurs between the line 22 and the linear outer conductor 24 outside the container 21, and ultraviolet rays are generated in the cavity 21 a of the container 21.

  As a result, when the discharge lamp 1 is started, ultraviolet rays are emitted from the ultraviolet radiation auxiliary light source 2 and the emitted ultraviolet rays are irradiated into the arc tube 10 of the discharge lamp 1, thereby improving the startability of the discharge lamp 1. Can do.

Returning to FIG. 1, continuing the explanation of the discharge lamp device of the present invention, the ultraviolet radiation auxiliary light source 2 connects the tip of the electrode 11 located on the neck opening 52 side of the discharge lamp 1 and the opening periphery 5 a of the neck opening 52. With respect to the virtual plane L, the reflecting mirror 5 is disposed on the side opposite to the front opening 51 side.
As a result, the light emitted from the discharge lamp 1 is irradiated on the reflecting surface of the reflecting mirror 5 without being blocked by the ultraviolet radiation auxiliary light source 2, so that the light emitted from the discharge lamp device is irradiated on the irradiation surface. The designed light distribution can be maintained, and the light distribution is not disturbed.

FIG. 4 is an explanatory diagram of another double tube type lamp used in the discharge lamp apparatus of the present invention.
In this double tube lamp, the longitudinal axis L1 of the ultraviolet radiation auxiliary light source 2 and the electrode axis L2 connecting the electrodes 11 and 12 of the discharge lamp 1 intersect each other.
The angle θ formed by the longitudinal axis L1 and the electrode axis L2 is 0 ° ≦ θ ≦ 90 °, and the best range is 0 ° ≦ θ ≦ 10 °.
Since other structures are the same as those in FIG. 2, description thereof is omitted.

  As a result, the ultraviolet rays radiated from the ultraviolet radiation auxiliary light source 2 can be efficiently emitted toward the discharge lamp 1, and the lighting performance of the discharge lamp 1 can be further improved.

DESCRIPTION OF SYMBOLS 1 Discharge lamp 11 Electrode 12 Electrode 2 Ultraviolet radiation auxiliary light source 3 Outer tube 4 Double tube type discharge lamp 5 Reflective mirror 51 Front opening 52 Top opening

Claims (2)

A discharge lamp in which a pair of electrodes are arranged opposite to each other in the arc tube and sealing portions are formed at both ends, and an ultraviolet radiation auxiliary light source that emits light at the time of starting the discharge lamp is hermetically arranged in a translucent outer tube. In a discharge lamp device comprising a tube lamp, a reflecting mirror surrounding the double tube lamp and reflecting light emitted from the double tube lamp,
The ultraviolet radiation auxiliary light source has a container having a cavity filled with a rare gas and a seal part, and one side of the metal foil extends into the cavity of the container, and the other side of the metal foil is hermetically sealed by the seal part. A linear outer conductor that is sealed and wound around the outer surface of the container;
The reflecting mirror has a front opening that emits light and a neck opening into which the outer tube is inserted,
Both the sealing part of the discharge lamp and the ultraviolet radiation auxiliary light source are arranged so as to be located in the neck part of the reflecting mirror,
The ultraviolet radiation auxiliary light source is disposed on a side opposite to the front opening side of the reflecting mirror with respect to a virtual plane connecting an electrode tip located on the neck opening side of the discharge lamp and an opening periphery of the neck opening. A discharge lamp device comprising:   2. The discharge lamp device according to claim 1, wherein a longitudinal axis of the ultraviolet radiation auxiliary light source intersects with an electrode axis connecting each electrode of the discharge lamp.

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