JP5573828B2 - One-end sealed short arc flash lamp - Google Patents

Description

  The present invention relates to a one-end sealed short arc flash lamp having a structure in which an opening of a bottomed cylindrical container is hermetically sealed by a stem member.

  Conventionally, for example, a short arc flash lamp is used as a strobe light source of a camera or a light source for high image processing. FIG. 2 is an explanatory diagram showing a configuration of an example of a conventional short arc flash lamp. This short arc type flash lamp has a container 91 made of hollow cylindrical hard glass, and a plurality of stems 92 made of hard glass are provided at the bottom of one end (lower end in FIG. 2) of the container 91. Each of the stems 92 is provided with a plurality of lead pins 93 extending through the stems 92 in an airtight manner. In the container 91, an anode 94 and a cathode 95 are disposed so as to face each other with a space therebetween, and a trigger electrode 96 is disposed between the anode 94 and the cathode 95. Reference numeral 97 denotes a sparker electrode. Each of the anode 94, the cathode 95, the trigger electrode 96, and the sparker electrode 97 is electrically connected to and held by the lead pin 93. The container 91 is filled with an inert gas such as xenon gas. The short arc type flash lamp having such a configuration is described in Patent Document 1 below.

  Thus, recently, there has been a demand for a short arc type flash lamp capable of emitting high output light. In order to obtain such a short arc type flash lamp, for example 3 It is necessary to be filled with an inert gas at atmospheric pressure or higher and to be lit by a large input power, for example, an input power having an energy of 5 J or more per pulse.

However, when a conventional short arc type flash lamp that emits high-power light is configured, it turns out that a long service life cannot be obtained because the container is damaged when it is lit a number of times. did.
The reason why such a problem occurs is estimated as follows.
For example, in a short arc type flash lamp in which xenon gas is sealed, ultraviolet rays having a short wavelength are emitted together with visible rays, and the radiation intensity of the ultraviolet rays increases as the input power increases. Therefore, the container 91 is damaged as a result of internal distortion caused by absorption of high radiation intensity ultraviolet rays in the container 91.

Japanese Patent Laid-Open No. 04-106832

  The present invention has been made on the basis of the circumstances as described above, and its purpose is to radiate high-power light and to prevent damage to the container even if the lamp is turned on many times. An object of the present invention is to provide a one-end-sealed short arc type flash lamp which can be prevented or suppressed and, therefore, has a long service life.

One end sealed short arc type flash lamp of the present invention comprises a bottomed cylindrical container having a light emitting part made of a light transmissive material, a pair of discharge electrodes disposed in the container, and a sparker electrode. A one-side sealed short arc flash lamp having a structure in which the opening of the container is hermetically sealed by a stem member,
The light emitting portion in the container has a light wavelength of 200 nm or less with a transmittance of 50%, and an inert gas of 3 atm or more is enclosed in the container,
It is lit by energy of 5 J or more per pulse.

  According to the one-end-sealed short arc flash lamp of the present invention, an inert gas of 3 atm or more is sealed in the container and is lit by energy of 5 J or more per pulse. In addition, since the light emitting portion in the container has a light wavelength of 200 nm or less at a transmittance of 50%, the generation of internal stress due to absorption of ultraviolet rays in the light emitting portion is suppressed. Even if it is lit repeatedly, it is possible to prevent or suppress damage to the container, and thus a long service life is obtained.

It is explanatory drawing which shows the structure in an example of the one end sealing type short arc type flash lamp of this invention. It is explanatory drawing which shows the structure in an example of the conventional short arc type flash lamp.

Hereinafter, embodiments of the one-end sealed short arc type flash lamp of the present invention will be described.
FIG. 1 is an explanatory view showing a configuration in an example of a one-end sealed short arc type flash lamp of the present invention. In this one-end sealed short arc type flash lamp (hereinafter simply referred to as “flash lamp”), a bottomed cylindrical container 10 having a light emitting portion 11 made of a light transmitting material from which light is emitted is provided. A sealing structure in which the opening of the container 10 is hermetically sealed by the stem member 20 is formed. More specifically, the stem member 20 is a disc having a diameter matching the inner diameter of the metal tube 21 in the metal tube 21 made of a circular tubular Kovar having an outer diameter substantially equal to the outer diameter of the container 10. The stem base 22 is arranged, and the stem base 22 is hermetically fused to the inner surface of the metal tube 21. On the other hand, the container 10 is configured such that a joint portion 13 made of Kovar glass is formed at one end of the light emitting portion 11 on the opening side via a step joint portion 12. Then, the metal tube 21 in the stem member 20 is hermetically bonded to the joint portion 13 in the container 10 by fusing the joint portion 13, whereby the opening of the container 10 is hermetically sealed by the stem member 20. A sealing structure is formed.
A plurality of lead pins 25, 26, 27, 28 for supplying power to discharge electrodes 30, 31, a trigger electrode 32 and a sparker electrode 33, which will be described later, are formed on the stem base 22 of the stem member 20. 20 is provided to extend in the axial direction of the container 10 through the thickness direction thereof.

In the light emitting portion 11 of the container 10, a pair of discharge electrodes 30 and 31 made of a refractory metal such as tungsten, various oxide-doped tungsten, and emitter-impregnated tungsten are arranged along the axial direction (vertical direction in the drawing) of the container 10. The trigger electrode 32 made of tungsten, which is disposed so as to face each other apart from each other and extends in a direction perpendicular to the axial direction of the container 10, is disposed so that the tip thereof is positioned between the pair of discharge electrodes 30, 31. Each of the pair of discharge electrodes 30, 31 and the trigger electrode 32 is electrically connected to and held by vertically bent tip portions 25a, 26a, 27a in each of the lead pins 25, 26, 27. .
Further, in the light emitting portion 11, a sparker electrode 33 is provided which is composed of an alumina insulating rod 33a and a thin tungsten wire 33b inserted into the insulating rod 33a and protruding from one end of the insulating rod 33a. . The tip of the tungsten wire 33 b in the sparker electrode 33 is joined and electrically connected to the tip of the lead pin 28, and the insulating rod 33 a is held at the center of the lead pin 25 that holds one discharge electrode 30. Yes.

The light emitting part 11 in the container 10 has a wavelength of light with which the transmittance is 50% is 200 nm or less. When the wavelength of light at which the transmittance in the light emitting unit 11 is 50% exceeds 200 nm, the container is likely to be damaged when turned on many times, so that it is difficult to obtain a long service life.
Here, the wavelength of light at which the transmittance is 50% is the wavelength of light at which the transmittance of the light emitting unit 11 is evaluated and the transmittance is 50%.

  The thickness of the light emitting portion 11 in the container 10 is preferably 0.3 to 3.0 mm. If this thickness is too small, it is difficult to obtain a container 10 having sufficient strength. On the other hand, when the thickness is excessive, it may be difficult to configure the light emitting unit 11 having a light wavelength of 200 nm or less at which the transmittance is 50%.

As the light transmissive material constituting the light emitting unit 11 in the container 10, quartz glass, borosilicate glass (for example, UV transmissive glass “8337B” manufactured by Schott) or the like can be used.
Further, the joint portion 12 is configured by integrally laminating a plurality of glass layers of different materials along the axial direction of the container 11, and each of the glass layers is a light-transmitting material that constitutes the light emitting portion 11. For example, it has a linear thermal expansion coefficient that is higher than the linear thermal expansion coefficient of quartz glass and lower than the linear thermal expansion coefficient of Kovar glass that constitutes the joint portion 13, and linear thermal expansion from the light emitting portion 11 side toward the joint portion 13. They are stacked so that the coefficient is high.
In addition, when a material having a linear thermal expansion coefficient equal to or close to that of Kovar constituting the metal tube 21 in the stem member 20 is used as the light transmissive material constituting the light emitting portion 11, the stepped portion 12 is formed. This is unnecessary, and therefore, the light emitting portion 11 and the joint portion 13 may be directly connected.

  An example of the specific dimensions of the container 10 is that the total length is 40 mm, the outer diameter is 22 mm, the wall thickness is 0.7 mm, the length of the light emitting part 11 is 30 mm, the total length of the stepped part 12 and the joint part 13. Is 10 mm.

An inert gas is sealed in the container 10. As the inert gas, xenon gas, krypton gas, argon gas, or a mixed gas thereof can be used.
The filling pressure of the inert gas is 3 atm or more, preferably 3 to 8 atm. When the filling pressure of the inert gas is less than 3 atmospheres, it becomes difficult to emit high output light. On the other hand, when the filling pressure of the inert gas exceeds 8 atm, the flash lamp is difficult to turn on, which is not preferable.

  In the flash lamp of the present invention, the lead pins 25, 26, 27, and 28 are connected to a power supply device (not shown), and the flash lamp device includes the flash lamp and the power supply device. The flash lamp of the present invention is powered by a power feeding device and is lit by energy of 5 J or more, preferably 5 to 300 J per pulse. When the energy per pulse is less than 5 J, it is difficult to emit high output light. When the energy per pulse exceeds 300 J, the emitter material of the discharge electrode serving as the cathode of the pair of discharge electrodes 30 and 31 evaporates, so that the life of the discharge electrode is remarkably shortened. Not right.

  According to the above flash lamp, since an inert gas of 3 atm or more is sealed in the container 10 and is lit by energy of 5 J or more per pulse, high-power light can be emitted, Moreover, since the light emitting section 11 in the container 10 has a light wavelength of 200 nm or less with a transmittance of 50%, the generation of internal stress due to the absorption of ultraviolet rays in the light emitting section 11 is suppressed. As is clear, even if the lamp is turned on many times, the container 10 can be prevented or suppressed from being damaged, and thus a long service life can be obtained.

  Hereinafter, specific examples of the flash lamp of the present invention will be described, but the present invention is not limited to these examples.

<Example 1>
A flash lamp having the following specifications was manufactured according to the configuration shown in FIG.
[Container (10)]
Light emitting part (11) material: quartz glass, bonding part (13) material: Kovar glass, dimensions: total length = 40 mm, outer diameter = 29 mm, wall thickness = 0.7 mm, light emitting part (11) length = 30 mm , The total length of the stepped portion (12) and the joint portion (13) = 10 mm, the wavelength of light (λ ₅₀ ) = 170 nm at which the transmittance in the light emitting portion (11) is 50%
[Stem member (20)]
Metal tube (21) material: Kovar, metal tube (21) dimensions: outer diameter = 29 mm, inner diameter = 28 mm, length = 16 mm, stem base (22) material: Kovar glass, stem base (22) dimensions : Outer diameter = 26.6 mm, thickness = 5 mm
[Lead pin (25, 26, 27, 28)]
Material: Kovar, outer diameter = 2.0mm, 1.0mm
[Discharge electrodes (30, 31)]
Material of one discharge electrode (anode): tungsten, Material of the other discharge electrode (cathode): BaO-based oxide-impregnated tungsten, Dimensions: Outer diameter = 4 mm, Length = 5 mm, Distance between electrodes = 3.00 mm
[Trigger electrode (32)]
Material: Tungsten, outer diameter = 0.5mm
[Sparker electrode (33)]
Insulating pipe (33a) made of 98% alumina having an outer diameter of 1 mm and an inner diameter of 0.5 mm and a tungsten wire (33b) having an outer diameter of 0.4 mm [inert gas]
Gas type: Xenon gas, enclosed pressure = 5 atm

<Example 2>
The material of the light emitting part (11) in the container (10) was changed from quartz glass to borosilicate glass (UV transmitting glass “8337B” manufactured by Schott) and the transmittance in the light emitting part (11) was 50%. A flash lamp having the same configuration as in Example 1 was manufactured except that the wavelength of light (λ ₅₀ ) = 195 nm).

<Comparative example 1>
The material of the light emitting part (11) in the container (10) was changed from quartz glass to borosilicate glass (domestic ultraviolet transparent glass) (wavelength of light at which the transmittance in the light emitting part (11) is 50%) Except that (λ ₅₀ ) = 230 nm), a flash lamp having the same configuration as in Example 1 was manufactured.

<Comparative example 2>
The material of the light emitting part (11) in the container (10) was changed from quartz glass to Kovar glass (wavelength of light (λ ₅₀ ) = 350 nm at which the transmittance in the light emitting part (11) is 50%), A flash lamp having the same configuration as in Example 1 was produced.

<Durability test of container>
The flash lamps according to Examples 1 and 2 and Comparative Examples 1 and 2 are supplied with electric power having an energy per pulse of 5 J (10 μF, 1000 V) and 10 J (20 μF, 1000 V). Each of these was turned on repeatedly, and the number of times of lighting until the container was damaged was measured. The results are shown in Table 1 below.

  As is clear from the results in Table 1, according to the flash lamps according to Examples 1 and 2, the container may be damaged even when repeatedly turned on many times under the condition that the energy per pulse is 5 J or more. It has been confirmed that when power is supplied that is prevented or suppressed, especially when the energy per pulse is 5 J, it can be lit until a failure occurs in the discharge electrode, and thus a long service life can be obtained.

DESCRIPTION OF SYMBOLS 10 Container 11 Light emission part 12 Step part 13 Junction part 20 Stem member 21 Metal tube 22 Stem base 25,26,27,28 Lead pin 25a, 26a, 27a Tip part 30,31 Discharge electrode 32 Trigger electrode 33 Sparker electrode 33a Insulating soot pipe 33b Tungsten wire 91 Container 92 Stem 93 Lead pin 94 Anode 95 Cathode 96 Trigger electrode 97 Sparker electrode

Claims (1)

A bottomed cylindrical container having a light emitting portion made of a light transmissive material, a pair of discharge electrodes disposed in the container, and a sparker electrode, and the opening of the container is hermetically sealed by a stem member. One-end sealed short arc flash lamp having a stopped structure,
The light emitting portion in the container has a light wavelength of 200 nm or less with a transmittance of 50%, and an inert gas of 3 atm or more is enclosed in the container,
One-end sealed short arc flash lamp characterized by being lit by energy of 5 J or more per pulse.

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