JPH0467558A - Illumination lamp device - Google Patents

Abstract

PURPOSE:To prevent the scattering of fragments with a protective outer tube when a xenon lamp is ruptured for some reasons and prevent the breakage of an outer casing by providing the protective outer tube. CONSTITUTION:A cylindrical protective outer tube 9 is arranged inside a support member 8 to cover a lamp 6, and its longitudinal, lateral or vertical movement is limited by the support member 8. The protective outer tube 9 is made of transparent or semi-transparent ceramic glass such as high-purity quartz glass with the content 95% or above of silicon dioxide or high-purity aluminum oxide. One end of the support member 8 is connected to one of feed sections on both ends of the lamp 6 via a lead wire 16, and one end of a lead wire 10 is connected to a support ring 8b by spot welding. The other feed section is connected to a contact 12 in a base section 3 with a lead wire.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Application Field) The present invention relates to an illumination lamp device, and more particularly to an illumination lamp in which a lamp that generates arc discharge in high-pressure gas, such as a xenon lamp, is sealed in a hard glass envelope. It is related to the device.

(Prior art) Xenon short arc lamps (hereinafter simply referred to as xenon lamps) have a spectral distribution that is extremely similar to that of natural sunlight, so they have been tested for light resistance and weather resistance in combination with various filters. It was used as a simulated sunlight light source for commercial purposes, and as a light source for projection.

In the original xenon lamps, the quartz glass body with which the electrodes were sealed was exposed, so if your hand touched the quartz glass body and fingerprints got on it, the part where the fingerprints were attached would become brittle and shorten the life of the lamp. There was a fear that it would become shorter.

Therefore, the original xenon lamps were handled by those with specialized knowledge and their use was primarily limited to commercial use.

However, in recent years, in addition to the above-mentioned uses, attention has been focused on the sterilizing effect of a pseudo-sunlight light source, and it has been used for sunbathing in general households, and has been used in small stores etc. by taking advantage of its color rendering properties as a pseudo-sunlight light source. They are also becoming widely used for consumer purposes, such as in displays and as lighting lamps in various exhibition halls.

Therefore, the inventors of the present invention have applied for patent application No. 63-73216.
No. 2, we proposed an illumination lamp device with a structure in which a xenon lamp is sealed inside a hard glass envelope so that the xenon lamp body is not directly touched.

(Problems to be Solved by the Invention) The conventional illumination lamp device described above had the following problems.

Although it is extremely rare, if a xenon lamp is subjected to a power that greatly exceeds its maximum rating or is used far beyond its specified lifespan, it may explode.

If a xenon lamp explodes, the quartz glass in the main body will break,
The problem was that the fragments collided with the hard glass outer tube, and although it was extremely rare, the quartz glass fragments would burst the outer tube, scattering the quartz glass fragments and the hard glass fragments.

Moreover, the rupture of the mantle produced a loud popping sound.
The problem was that it gave a sense of fear to the people around them.

An object of the present invention is to solve the above-mentioned problems, and to provide a structure in which even if a xenon lamp ruptures for some reason, its fragments will not be scattered outside and the explosion noise will be small. An object of the present invention is to provide an illumination lamp device.

(Means for Solving the Problems) In order to achieve the above object, the present invention takes the following measures.

(1) In an illumination lamp device in which a xenon lamp is disposed within an airtight outer tube, a protective outer tube is disposed between the outer tube and the xenon lamp so as to cover the xenon lamp.

(2) A cylindrical wire mesh cover covering the protective outer cylinder is further disposed.

(Function) According to the configuration described above, the following effects are achieved.

(1) Since the protective outer cylinder is provided, even if the xenon lamp explodes, the protective outer cylinder prevents the fragments from scattering, and the outer jacket will not be damaged.

(2) Even if the scattering energy of the fragments is large, the scattering energy of the fragments is absorbed by the destruction of the protective outer cylinder, so the outer jacket will not be damaged.

(3) Since a wire mesh case is provided around the protective outer cylinder, even if the bursting energy of the xenon lamp is greater, the wire mesh case prevents the fragments from scattering and the outer jacket is not damaged.

(Example) The present invention will be described in detail below with reference to the drawings.

FIG. 1 is a sectional view of an embodiment of the present invention, in particular, FIG. 1(a) is a side sectional view, and FIG.
It is an enlarged sectional view taken along the B line.

As shown in the figure, the illumination lamp device of this embodiment includes an outer tube 1, a lamp part 2 incorporated inside the outer tube 1,
and a base portion 3 provided at the rear of the mantle tube l.

The mantle tube 1 is composed of a concave quadratic curved surface reflecting mirror 4 and a cover 5 fixed to the front surface of the reflecting mirror 4. The inside and outside of the mantle tube 1 are airtight, and the mantle tube 1
The inside is filled with inert gas.

The reflecting mirror 4 and the cover 5 are made of hard glass, and the surface of the cover 5 is coated to adjust the spectrum of light passing through the cover 5, if necessary. The coating comprises zirconium oxide,
This is done by depositing a thin film of oxide such as titanium oxide.

Further, a metal such as aluminum or silver is vacuum-deposited on the reflecting mirror 4 to form a reflecting surface. Whether the reflective surface is a total reflection surface or a cold mirror depends on the application.

The lamp section 2 includes a xenon lamp 6 and a support member 8 that supports the lamp 6 at a predetermined position inside the mantle tube 1. The support member 8 has support rings 8a and 8b, and the straight pipe portions at both ends of the lamp 6 are inserted through the support rings 8a and 8b, so that the lamp 6 is fixed to the support member 8.

A cylindrical protective outer cylinder 9 is arranged inside the support member 8 so as to cover the lamp 6, and its movement in the front-rear, left-right, and up-down directions is restricted by the support member 8. The protective outer cylinder 9 is
It is made of transparent or translucent ceramic glass such as high-purity quartz glass with a silicon dioxide content of 95% or more or high-purity aluminum oxide.

One end of the support member 8 is connected to one of the power supply parts at both ends of the lamp 6 via a conductor 16, and a conductor 10 is connected to the support ring 8b.
One end is connected by spot welding. The other power supply part is connected to the contact 12 by a conductive wire inside the base part 3. In the lighting lamp device having the above structure, the screw base 7 is screwed into the socket of the lamp, and the screw base 7 and the contact are connected to each other by a conductor. When electricity is applied between the lamp 12 and the lamp 6, the lamp 6 lights up.

The cap is not limited to the screw cap, but a plug cap having a pin that can be inserted into a groove formed in the socket of the lamp used can also be used.

According to such a configuration, even if the xenon lamp 6 ruptures due to some other cause, the fragments will scatter or the protective outer cylinder 9 will be destroyed.
Therefore, the outer tube 1 will not be damaged by the fragments of the xenon lamp 6.

Furthermore, even if the bursting energy of the xenon lamp 6 is large and the energy of the scattered fragments is large enough to destroy the protective outer cylinder 9, the energy of the scattered fragments is absorbed when the protective outer cylinder 9 is destroyed. Furthermore, the outer tube 1 will not be damaged.

Furthermore, since the provision of the protective outer tube 9 prevents the outer tube 1 from bursting, according to the results of experiments conducted by the inventors of the present invention, in the prior art structure, even the outer tube 1 would burst. Even if a xenon lamp is ruptured with a certain amount of energy, according to the structure of this embodiment, the outer tube 1 will not burst, so the rupture sound will be reduced from the conventional approximately 110 dB to 70 dB.
decreased to

Therefore, even if the xenon lamp 6 explodes for some reason, it will not cause fear to people around it.

FIG. 2 is a sectional view of another embodiment of the present invention, and the same reference numerals as in FIG. 1 represent the same or equivalent parts.

In this embodiment, a cylindrical wire mesh cover 17 made of aluminum or stainless steel is provided on the outside of the support member 8.
It is characterized in that it is arranged so as to cover the protective outer cylinder 9.

According to such a configuration, even if the bursting energy of the xenon lamp 6 is very large and the scattering energy of the fragments after the protective outer cylinder 9 is destroyed is still large enough to burst the reflector 4 or the cover 5. However, since the scattering of the fragments is prevented by the wire mesh cover 17, the reflecting mirror 4 and the cover 5 are not destroyed.

Note that the wire mesh cover 17 is designed not only to cover only the side surfaces of the protective outer cylinder 9 but also to cover one end facing the cover 5 in order to prevent fragments of the xenon lamp 6 from scattering from the end of the protective outer cylinder 9. , or may have a shape that also covers the other end.

(Effects of the Invention) As is clear from the above description, according to the present invention, the following effects are achieved.

(1) Since the protective outer tube is provided, even if the xenon lamp ruptures for some reason, the protective outer tube will prevent the fragments from scattering, and the outer jacket will not be damaged.

(2) Even if the bursting energy of the xenon lamp is large and the scattering energy of the fragments is large, the protective outer cylinder is destroyed and the scattering energy of the fragments is absorbed, so that the outer jacket will not be damaged.

(3) Since a wire mesh case is provided around the protective outer cylinder, even if the bursting energy of the xenon lamp is greater, the wire mesh case prevents the fragments from scattering and the outer jacket is not damaged.

(4) As mentioned above, by providing a protective outer cylinder and wire mesh case,
Since the jacket is prevented from being damaged due to the xenon lamp bursting, even if the xenon lamp bursts, it will not make a loud bursting sound and will not cause fear to people around it.

[Brief explanation of the drawing]

FIG. 1 is a cross-sectional view of one embodiment of the present invention, and FIG. 2 is a cross-sectional view of another embodiment. 1... Mantle tube, 2... Lamp part, 3... Base part,
4...Reflector, 5...Cover, 6...Lamp, 7
...Screw cap, 8...Supporting member, 9...Protective outer cylinder, 12...Contact, 17...Wire mesh agent Patent attorney Michito Hiraki and 1 other person (b)

Claims (4)

[Claims] (1) An airtight mantle tube, a xenon short arc lamp disposed within the mantle tube, and a transparent protection disposed between the mantle tube and the xenon short arc lamp to cover the xenon short arc lamp. An illumination lamp device comprising: an outer tube; and a base provided at one end of the outer tube. (2) The illumination lamp device according to claim 1, further comprising a cylindrical wire mesh cover that covers the protective outer cylinder. (3) The illumination lamp device according to claim 2, wherein at least one of both end surfaces of the cylindrical wire mesh cover is covered with a wire mesh. (4) The protective outer cylinder has a silicon dioxide content of 95%.
The illumination lamp device according to any one of claims 1 to 3, characterized in that it is constructed of one of the above-mentioned quartz glass and high-purity aluminum oxide.