JP3125265U - Discharge tube - Google Patents

Abstract

A long-life discharge tube capable of suppressing an increase in initial discharge start voltage when used in a dark environment in a high temperature environment.
An airtight envelope 16 is formed by hermetically sealing the opening portions at both ends of a case member 12 with a pair of lid members 14 and 14 that also serve as discharge electrodes, and the inside of the airtight envelope 16 is formed. In addition, a discharge gas 22 is sealed in, and a discharge gap 22 is formed between the discharge electrode portions 18 and 18 of the lid members 14 and 14, and both ends of the inner wall 24 of the case member 12 are covered with the lid members 14 and 14. A plurality of trigger discharge films 28 disposed with a small discharge gap 26 therebetween are formed, and a coating 30 containing titanium carbide is formed on the surface of the discharge electrode portion 18.
[Selection] Figure 1

Description

  The present invention relates to a discharge tube, in particular, as a switching spark gap for supplying a constant voltage for lighting or ignition to a high-pressure discharge lamp such as a projector or a metal halide lamp of an automobile, or an ignition plug of a gas cooker, or The present invention relates to a discharge tube that can be suitably used as a gas arrester for absorbing surge voltage.

  As this type of discharge tube, the present applicant has previously proposed Japanese Patent Application Laid-Open No. 2003-7420. As shown in FIG. 7, the discharge tube 60 is hermetically sealed with a pair of lid members 64, 64 that also serve as discharge electrodes, at both ends of a cylindrical case member 62 made of an insulating material that is open at both ends. Thus, an airtight envelope 66 is formed, and a predetermined discharge gas is sealed in the airtight envelope 66.

The lid member 64 includes a flat discharge electrode portion 68 that protrudes greatly toward the center of the hermetic envelope 66, and a joint portion 70 that contacts the end surface of the case member 62. A predetermined discharge gap 72 is formed between the discharge electrode portions 68 and 68.
A plurality of pairs of trigger discharge films 78 and 78 are formed in the circumferential direction of the inner wall surface 74 of the case member 62 so as to face each other with a minute discharge gap 76 therebetween. Of the pair of trigger discharge films 78, 78, one trigger discharge film 78 is electrically connected to one discharge electrode portion 68, and the other trigger discharge film 78 is electrically connected to the other discharge electrode portion 68. It is connected.

On the surface of the discharge electrode portion 68, an insulating film 80 containing an alkali iodide effective for stabilizing the discharge start voltage is formed. As this alkali iodide, the simple substance or mixture of alkali iodides, such as potassium iodide (KI), sodium iodide (NaI), cesium iodide (CsI), and rubidium iodide (RbI), corresponds.
As the discharge gas sealed in the hermetic envelope 66, for example, a rare gas such as argon, neon, helium, xenon, or an inert gas such as nitrogen gas or a mixed gas is applicable. Further, a mixed gas of a rare gas or an inert gas or a mixed gas of a gas containing halogen or a negative gas such as O ₂ is applicable.

When a voltage equal to or higher than the discharge start voltage of the discharge tube 60 is applied between the discharge electrode portions 68, 68 of the discharge tube 60 having the above-described configuration, an electric field is generated in the minute discharge gap 76 between the trigger discharge films 78, 78. As a result, electrons are emitted into the minute discharge gap 76, and creeping corona discharge as a trigger discharge is generated. Next, this creeping corona discharge shifts to glow discharge due to an electron priming effect. Then, this glow discharge is transferred to the discharge gap 72 between the discharge electrode portions 68 and 68, and is transferred to arc discharge as the main discharge.
JP 2003-7420 A

By the way, the coating film 80 containing alkali iodide, particularly potassium iodide (KI) has a function of lowering a discharge starting voltage because it has a small work function and excellent electron emission characteristics. When the discharge tube 60 is used in the dark under a high temperature environment (for example, 150 ° C.), the initial discharge start voltage gradually increases and a discharge delay occurs, which eventually becomes unsuitable for use. there were.
Note that the initial discharge start voltage gradually increases in the dark and the discharge delay occurs. When the discharge tube 60 is left in the dark for a long time, the electrons and the seeds of discharge in the hermetic envelope 66 This is because ions are reduced.

This invention has been made in view of the above-mentioned problems, and its purpose is as follows:
An object of the present invention is to provide a long-life discharge tube capable of suppressing an increase in initial discharge start voltage when used in a dark environment under a high temperature environment.

As a result of various investigations on the constituent materials of the coating film formed on the surface of the discharge electrode, the inventors of the present invention effectively prevented the initial discharge starting voltage from increasing in a dark high temperature environment. We have found what we can do and have come to complete this invention.
That is, the discharge tube according to the present invention is a discharge tube in which a plurality of discharge electrodes are arranged with a discharge gap and sealed in a hermetic envelope together with a discharge gas, on the surface of the discharge electrode, A film containing titanium carbide is formed.

  A recess may be formed on the surface of the discharge electrode, and the coating may be formed on the inner surface of the recess.

  The content ratio of titanium carbide in the coating is preferably 0.01 to 50% by weight.

You may make it add potassium molybdate and / or titanium in the said film | membrane containing titanium carbide.
When potassium molybdate and titanium are added to the coating film containing titanium carbide, titanium carbide, potassium molybdate and titanium are mixed in an amount of 1 to 70% by weight for titanium carbide and 1 to 70% for potassium molybdate. It is preferable that 1% by weight and 70% by weight of titanium are formed.

  In the discharge tube according to the present invention, a film containing titanium carbide is formed on the surface of the discharge electrode, thereby suppressing an increase in initial discharge start voltage when used in a high temperature environment in the dark. And a long-life discharge tube can be realized.

  In addition, when the concave portion is formed on the surface of the discharge electrode and the coating film is formed on the inner surface of the concave portion, excellent frequency characteristics are obtained that can always obtain a stable discharge starting voltage even when the operation is repeated in a short cycle. A discharge tube can be realized.

When potassium molybdate is added to the film containing titanium carbide, since the potassium molybdate is excellent in sputtering resistance, the film is prevented from being sputtered and contributes to the suppression of the increase in the initial discharge start voltage.
In addition, when titanium is added to the above-mentioned film containing titanium carbide, titanium has a very high ionization tendency, so that the titanium ionizes discharge gas molecules, and as a result, discharge seeds are ignited in the hermetic envelope. A large amount of ions to be supplied can be supplied, which contributes to suppression of an increase in initial discharge start voltage.

  As shown in FIGS. 1 and 2, a discharge tube 10 according to the present invention has a pair of lids that serve as discharge electrodes at both ends of a cylindrical case member 12 made of ceramic as an insulating material having both ends open. The hermetic envelope 16 is formed by hermetically sealing with the members 14 and 14.

The lid member 14 includes a planar discharge electrode portion 18 projecting greatly toward the center of the hermetic envelope 16, and a joint portion 20 in contact with the end surface of the case member 12. A predetermined discharge gap 22 is formed between the discharge electrode portions 18 and 18.
The lid member 14 provided with the discharge electrode portion 18 and the joint portion 20 is made of oxygen-free copper or zirconium copper containing oxygen-free copper containing zirconium (Zr). Note that the end face of the case member 12 and the joint portion 20 of the lid member 14 are hermetically sealed through a sealing material (not shown) such as silver solder.

In addition, a plurality of linear trigger discharge films 28 are formed on the inner wall surface 24 of the case member 12 so that both ends of the case member 12 are spaced apart from the lid members 14 and 14 that also serve as discharge electrodes and a minute discharge gap 26. ing. 1 and 2 exemplify a case where eight trigger discharge films 28 are formed at intervals of 45 degrees in the circumferential direction of the inner wall surface 24 of the case member 12.
The trigger discharge film 28 is made of a conductive material such as a carbon-based material. The trigger discharge film 28 can be formed, for example, by rubbing a core material made of a carbon-based material.

A coating 30 containing titanium carbide (TiC) is formed on the surface of the discharge electrode portion 18.
This coating 30 can be formed by applying titanium carbide powder to a binder made of a sodium silicate solution and pure water on the surface of the discharge electrode portion 18.
In this case, the content ratio of titanium carbide in the coating 30 formed by adding titanium carbide powder to a binder composed of a sodium silicate solution and pure water is 0.01 to 50% by weight in a high temperature environment. It is preferable for effectively preventing an increase in the initial discharge start voltage.
The mixing ratio of the sodium silicate solution and pure water in the binder is such that the sodium silicate solution is 0.01 to 70% by weight and the pure water is 99.99 to 30% by weight.

In addition, when potassium molybdate (K ₂ MoO ₄ ) is added to the coating film 30, since the potassium molybdate has excellent sputtering resistance, the coating film 30 is prevented from being sputtered, and the rise of the initial discharge start voltage is suppressed. Contribute.
Further, when titanium (Ti) is added to the coating film 30, since the titanium has a very high ionization tendency, the titanium ionizes the discharge gas molecules, and as a result, becomes a seed of discharge in the hermetic envelope. A large amount of ions can be supplied, which contributes to the suppression of the increase in the initial discharge start voltage.
When potassium molybdate and titanium are added to the coating film 30 containing titanium carbide, titanium carbide, potassium molybdate and titanium are mixed in an amount of 1 to 70% by weight for titanium carbide and 1 for potassium molybdate. It is preferable that it is made up to 70% by weight and titanium is 1 to 70% by weight.
Moreover, it is preferable that the compounding ratio of the mixture of titanium carbide, potassium molybdate and / or titanium with respect to the binder consisting of a sodium silicate solution and pure water is 0.01 to 50% by weight.

A predetermined discharge gas is sealed in the hermetic envelope 16. As this discharge gas, for example, a rare gas such as argon, neon, helium, or xenon, or an inert gas such as nitrogen gas or a mixed gas is applicable. Further, a mixed gas of a rare gas or an inert gas or a mixed gas of a gas containing halogen or a negative gas such as O ₂ is applicable.

  In the discharge tube 10 of the present invention, when a voltage equal to or higher than the discharge start voltage of the discharge tube 10 is applied between the pair of lid members 14 and 14 also serving as discharge electrodes, the trigger discharge film 28 The electric field concentrates in the minute discharge gap 26 between the both ends and the lid members 14 and 14, whereby electrons are emitted into the minute discharge gap 26 to generate creeping corona discharge as a trigger discharge. Next, this creeping corona discharge shifts to glow discharge due to an electron priming effect. Then, the glow discharge is transferred to the discharge gap 22 between the discharge electrode portions 18 and 18, and the arc discharge is performed as the main discharge.

Thus, in the discharge tube 10 of the present invention, the coating tube 30 containing titanium carbide is formed on the surface of the discharge electrode portion 18, so that the discharge tube 10 is in a high temperature environment (for example, 150 ° C.) in the dark. In this environment, an increase in the initial discharge start voltage can be suppressed, and a long-life discharge tube can be realized.
The initial discharge start voltage refers to the first discharge start voltage when the discharge tube is repeatedly operated, and the second and subsequent discharge start voltages subsequent to the initial discharge start voltage are referred to as follow-up discharge start voltages.

FIGS. 3 and 4 show a first modification of the discharge tube 10 according to the present invention. The first modification of the discharge tube 10 is formed by forming a recess 32 on the surface of the discharge electrode portion 18. This is characterized in that the coating film 30 containing titanium carbide is formed on the inner surface of the recess 32, and the other configuration is substantially the same as that of the discharge tube 10.
Thus, when the discharge tube 10 of the present invention is used as a switching spark gap, a stable discharge start voltage is required even when it is repeatedly operated at least at a frequency of 200 Hz (5 ms). Depending on the application, it is required that a stable discharge start voltage be obtained even when the operation is repeated at intervals of 400 Hz (2.5 ms).
A first modification of the discharge tube 10 of the present invention is that the recess 32 is formed on the surface of the discharge electrode portion 18, and the coating 30 is formed on the inner surface of the recess 32, so that the discharge tube 10 having excellent frequency characteristics is provided. Can be realized. That is, in the first modification of the discharge tube 10 of the present invention, the inner surface of the recess 29 on the surface of the discharge electrode 18 is formed by forming the coating 30 on the inner surface of the recess 32 formed on the surface of the discharge electrode 18. Only a discharge is generated. As a result, the occurrence of early firing and continuation is suppressed, and it is considered that discharge can be stably generated at a specified voltage even when the operation is repeated in a short cycle.

FIG. 5 is an enlarged cross-sectional view of a main part showing a second modification of the discharge tube 10 according to the present invention. The second modification of the discharge tube 10 is formed on the inner surface of the recess 32 of the discharge electrode portion 18. A feature is that a large number of bottomed hole portions 34 are formed, and the coating film 30 containing titanium carbide is formed on the inner surfaces of the recess portions 32 and the hole portions 34.
Thus, in the second modification of the discharge tube 10, a large number of holes 34 are formed on the inner surface of the recess 32 of the discharge electrode portion 18, and the coating 30 is formed on the inner surfaces of the recess 32 and the hole 34. As a result, the adhesion between the coating 30 and the discharge electrode portion 18 is improved, and sputtering of the coating 30 due to an impact during discharge is suppressed. As a result, the work function of the coating 30 is prevented from changing due to sputtering, and the effect of suppressing the initial discharge delay is obtained.

In the following, results of experiments performed on the discharge tube 10 according to the present invention and the conventional discharge tube 60 are shown.
FIG. 6 shows a discharge electrode (A) 10 of the present invention formed by forming a coating 30 containing titanium carbide on the surface of the discharge electrode portion 18, and a coating 30 containing titanium carbide, potassium molybdate and titanium. The discharge tube (B) 10 of the present invention formed on the surface of 18, and a conventional discharge tube (C) in which a coating 80 containing potassium iodide (KI) is formed on the surface of the discharge electrode portion 68 as a comparative example. 6 is a graph showing the relationship between the number of discharges in a high temperature environment of 150 ° C. in the dark and the initial discharge start voltage. Any of these discharge tubes is used in which the discharge start voltage is set to 800 V. In this case, if the initial discharge start voltage exceeds 1000 V, it becomes unsuitable for use.
As the discharge tube 10 of the present invention, the one of the second modification example described above, which “is formed by forming a large number of holes 34 in the inner surface of the recess 32 of the discharge electrode portion 18” was used.
The discharge tube (A) 10 of the present invention used in the experiment is composed of 0.2 g of titanium carbide (content: 1% by weight) with respect to 20 g of the binder (sodium silicate solution: pure water = 2 g: 18 g). ) To form a coating 30.
The discharge tube (B) 10 of the present invention is formed by forming a coating 30 by containing 0.2 g of titanium carbide, 1 g of potassium molybdate, and 2 g of titanium with respect to 20 g of the binder. Therefore, the mixing ratio of titanium carbide, potassium molybdate and titanium is 6.25% by weight of titanium carbide, 31.25% by weight of potassium molybdate, and 62.5% by weight of titanium. Moreover, the mixture ratio of the mixture of titanium carbide, potassium molybdate and titanium with respect to the binder is 16% by weight.

As shown in the graph of FIG. 6, in the case of the conventional discharge tube (C) 60 (graph C of FIG. 6), the number of discharges is about 600,000 times, and the initial discharge start voltage exceeds 1000 V and is suitable for use. It is gone.
On the other hand, in the case of the discharge tube (A) 10 of the present invention (graph A in FIG. 6), the initial discharge start voltage is maintained at 900 V or less even when the number of discharges reaches 1 million, so that the high temperature environment Even in the dark underneath, there is no delay in discharge and a long life is realized.
Further, in the case of the discharge tube (B) 10 of the present invention (graph B in FIG. 6), even when the number of discharges reaches 1,000,000, the initial discharge start voltage is almost constant and thus is constant. Even in the dark underneath, there is no delay in discharge and a long life is realized.

It is a schematic sectional drawing which shows the discharge tube which concerns on this invention. It is an AA schematic sectional drawing of FIG. It is a schematic sectional drawing which shows the 1st modification of the discharge tube which concerns on this invention. It is a BB schematic sectional drawing of FIG. It is a principal part expanded sectional view which shows the 2nd modification of the discharge tube which concerns on this invention. It is a graph which shows the relationship between the frequency | count of discharge and the initial stage discharge start voltage in the discharge tube which concerns on this invention, and the discharge tube of a comparative example. It is sectional drawing which shows the conventional discharge tube.

Explanation of symbols

10 discharge tube
12 Case material
14 Lid member
16 Airtight envelope
18 Discharge electrode
22 Discharge gap
26 Micro discharge gap
28 Trigger discharge membrane
30 coating
32 recess
34 hole

Claims (5)

  In a discharge tube in which a plurality of discharge electrodes are arranged with a discharge gap and sealed together with a discharge gas in an airtight envelope, a film containing titanium carbide is formed on the surface of the discharge electrode. A discharge tube characterized by that.   The discharge tube according to claim 1, wherein a recess is formed on a surface of the discharge electrode, and the coating is formed on an inner surface of the recess.   The discharge tube according to claim 1 or 2, wherein a content ratio of titanium carbide in the coating is 0.01 to 50% by weight.   4. The discharge tube according to claim 1, wherein potassium molybdate and / or titanium is added to the coating film containing titanium carbide. In the coating film containing titanium carbide, potassium molybdate and titanium are added, and the mixing ratio of titanium carbide, potassium molybdate and titanium is 1 to 70% by weight of titanium carbide, 1 to 1 of potassium molybdate. The discharge tube according to claim 4, wherein 70% by weight and 1 to 70% by weight of titanium are formed.

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