JP4764076B2 - Discharge tube - Google Patents

Description

  The present invention relates to a discharge tube, and 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 starting 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, when the number of discharges of the discharge tube 60 is increased, a small amount of impure gas contained in the discharge gas or impure gas mixed in the sealing process of the hermetic envelope 66 is caused by the discharge electrode portion 68 or the coating 80. The work function of the discharge electrode portion 68 and the film 80 changes due to the adsorption on the surface or the sputtering of the discharge electrode portion 68 and the film 80 due to the impact during discharge, resulting in an increase in the initial discharge start voltage. As a result, an initial discharge delay may occur. This initial discharge delay is particularly noticeable when the discharge tube 60 is used in the dark. This is because, when the discharge tube 60 is left in the dark for a long time, electrons and ions as a seed of discharge in the hermetic envelope 66 are reduced.

  The present invention has been made in view of the above-described conventional problems, and an object thereof is to realize a discharge tube capable of suppressing an initial discharge delay.

As a result of various investigations on the constituent materials of the coating film formed on the surface of the discharge electrode, the present inventors have applied a mixture of a mixture of cesium bromide (CsBr), titanium (Ti) and potassium tungstate (K ₂ WO ₄ ). In this case, the inventors have found that an increase in the initial discharge start voltage can be effectively prevented, and have completed the present invention.
That is, the discharge tube according to the present invention is
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, cesium bromide, titanium and potassium tungstate are formed on the surface of the discharge electrode. A coating film containing a mixture is formed , and the mixing ratio of the cesium bromide, titanium, and potassium tungstate is 40% by weight for cesium bromide, 40% by weight for titanium, and 20% by weight for potassium tungstate. It is characterized by being.

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

In the discharge tube according to the present invention, the surface of the discharge electrode, cesium bromide, made by forming a coating mixture is contained potassium titanium and tungsten acid, the cesium bromide, potassium titanium and tungsten acid The mixing ratio is 40% by weight of cesium bromide, 40% by weight of titanium, and 20% by weight of potassium tungstate , thereby preventing an increase in initial discharge start voltage and suppressing initial discharge delay. it can.

  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 provide a stable discharge starting voltage even when the operation is repeated in a short cycle. A discharge tube can be realized.

  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 film 30 containing a mixture of cesium bromide (CsBr), titanium (Ti), and potassium tungstate (K ₂ WO ₄ ) is formed on the surface of the discharge electrode portion 18.
This coating 30 is formed by applying a mixture of cesium bromide powder, titanium powder and potassium tungstate powder to a binder consisting of a sodium silicate solution and pure water on the surface of the discharge electrode portion 18. can do. Alternatively, a mixture obtained by adding a titanium powder and a potassium tungstate powder to the binder to which cesium bromide has been added may be applied to the surface of the discharge electrode portion 18.
In this case, the mixing ratio of cesium bromide, titanium, and potassium tungstate is 10 to 70 wt% for cesium bromide, 10 to 70 wt% for titanium, and 10 to 70 wt% for potassium tungstate. This is preferable for effectively preventing an increase in the discharge start voltage.
The blending ratio of the mixture of cesium bromide, titanium and potassium tungstate and the binder is 0.01 to 40% by weight of the mixture of cesium bromide, titanium and potassium tungstate, and 99.99 to 60% by weight of the binder. %.
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.

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 initial discharge start voltage is obtained by forming the coating 30 containing the mixture of cesium bromide, titanium and potassium tungstate on the surface of the discharge electrode portion 18. Can be prevented, and a long-life discharge tube 10 capable of suppressing the initial discharge delay can be realized.
The potassium tungstate contained in the coating 30 of the discharge tube 10 of the present invention has excellent sputter resistance, so the amount of the constituent material of the sputtered coating 30 attached to and deposited on the trigger discharge film 28 is reduced. As a result, it is considered that the trigger discharge (creeping corona discharge) generation function of the trigger discharge film 28 is prevented from being damaged and contributes to the suppression of the initial discharge delay.
In addition, since the titanium contained in the coating 30 has a very high ionization tendency, the titanium ionizes discharge gas molecules, and as a result, a large amount of ions serving as a discharge igniter are contained in the hermetic envelope 16. The fact that it can be supplied also contributes to the suppression of the initial discharge delay.
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.

FIG. 3 shows a discharge tube 10 of the present invention in which a coating 30 containing a mixture of cesium bromide, titanium and potassium tungstate is formed on the surface of the discharge electrode portion 18, and potassium iodide (KI) as a comparative example. In a conventional discharge tube 60 in which a coating film 80 containing the above is formed on the surface of the discharge electrode portion 68, and in a discharge tube in which a coating containing only cesium bromide is formed on the surface of the discharge electrode portion as a comparative example, in the dark It is a graph which shows the relationship between the frequency | count of discharge and an initial stage 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.
The discharge tube 10 of the present invention is obtained by adding a mixture of 2 g of cesium bromide powder, 2 g of titanium powder, and 1 g of potassium tungstate powder to 20 g of binder (12 g of sodium silicate solution + 8 g of pure water). Coating 30 was formed on the surface of part 18. Therefore, in this case, the mixing ratio of cesium bromide, titanium and potassium tungstate is 40% by weight for cesium bromide, 40% by weight for titanium and 20% by weight for potassium tungstate, that is, 2: 2: 1 by weight. It is made.
The blending ratio of the mixture of cesium bromide, titanium and potassium tungstate (5 g) and the binder (20 g) is 20 wt% for the mixture of cesium bromide, titanium and potassium tungstate, 80 wt% for the binder, That is, the weight ratio is 1: 4.

As shown in the graph of FIG. 3, in the case of the conventional discharge tube 60 (graph B of FIG. 3), the number of discharges is about 100,000 times and the initial discharge start voltage exceeds 1000 V, making it unsuitable for use. . Further, in the case of a discharge tube in which a coating containing only cesium bromide is formed on the surface of the discharge electrode portion (graph C in FIG. 3), although an increase in the initial discharge start voltage can be suppressed as compared with the conventional discharge tube 60, The initial discharge start voltage gradually increases, the number of discharges is about 450,000 times, and the initial discharge start voltage exceeds 1000 V, making it unsuitable for use.
On the other hand, in the case of the discharge tube 10 of the present invention (graph A in FIG. 3), the initial discharge start voltage is almost constant even when the number of discharges reaches 500,000, and therefore a discharge delay occurs even in the dark. Long life has been achieved without any problems.

4 and 5 show a modified example of the discharge tube 10 according to the present invention. In the modified example of the discharge tube 10, a recess 32 is formed on the surface of the discharge electrode portion 18, and the inner surface of the recess 32 is shown. The coating film 30 containing a mixture of cesium bromide, titanium, and potassium tungstate is formed, 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, it is required to obtain a stable discharge start voltage 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).
The modification of the discharge tube 10 of the present invention realizes the discharge tube 10 having excellent frequency characteristics by forming the recess 32 on the surface of the discharge electrode portion 18 and forming the coating 30 on the inner surface of the recess 32. be able to.

FIG. 6 is a chart showing the transition of the discharge start voltage when a modification of the discharge tube 10 of the present invention in which the discharge start voltage is set to 800 V is operated at a frequency of 400 Hz (about 2.5 ms). As can be seen from the chart, the modification of the discharge tube 10 of the present invention has a stable discharge start voltage of 800 V and is excellent in frequency characteristics.
A variation of the discharge tube 10 according to the present invention is that the coating 30 is formed on the inner surface of the recess 32 formed on the surface of the discharge electrode portion 18, whereby discharge is generated only on the inner surface of the recess 29 on the surface of the discharge electrode portion 18. Become. As a result, the occurrence of early firing and continuation is suppressed, and it is considered that stable discharge can be generated at the specified voltage (800 V in the case of FIG. 6) even when the operation is repeated repeatedly with a short period.

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 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 a schematic sectional drawing which shows the modification of the discharge tube which concerns on this invention. It is BB schematic sectional drawing of FIG. It is a chart which shows transition of the discharge start voltage at the time of making the modification of the discharge tube which concerns on this invention operate | move by frequency 400Hz (about 2.5 ms) space | interval. It is sectional drawing which shows the conventional discharge tube.

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

Claims (2)

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, cesium bromide, titanium and potassium tungstate are formed on the surface of the discharge electrode. A coating film containing a mixture is formed , and the mixing ratio of the cesium bromide, titanium, and potassium tungstate is 40% by weight for cesium bromide, 40% by weight for titanium, and 20% by weight for potassium tungstate. A discharge tube characterized by being made . The discharge tube according to claim 1, wherein a recess is formed on the surface of the discharge electrode, and the coating is formed on the inner surface of the recess.

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