JP2875860B2 - Discharge tube device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a discharge tube device, and more particularly to a device used as a light source.

BACKGROUND OF THE INVENTION It is known to use electromagnetic surface waves to create and maintain a low pressure discharge in a gas, as disclosed, for example, in European Patent No. 0225753A2 (University of California, Patentee). . Surface waves are generated by a power supply (also known as a launcher) that does not extend the full length of the discharge vessel containing the gas, but is located around the outside of the discharge vessel. In such a device, it is not necessary to provide an electrode inside the discharge tube. The power to generate the electromagnetic waves is obtained with a radio frequency power generator.

It has been proposed to use such devices as visible or ultraviolet light sources. In order to obtain a visible light source, a mixture of an inert gas and a mercury gas phase (for example, an argon gas and a mercury gas phase) is sealed in the discharge tube, and 254 nm is coated on the inner surface of the discharge tube.
m It may be a common fluorescent lamp discharge tube coated with phosphorus that converts ultraviolet radiation to visible light. In order to use an ultraviolet light source, the discharge tube is made of quartz glass and contains a mixture of an inert gas and a mercury gas phase, but is not coated with phosphorous. It is good.

However, there is a disadvantage in using a fluorescent lamp type discharge tube device to obtain visible light. As mentioned above, since the discharge vessel enclosing the mixture of the inert gas and the mercury gas phase mainly produces ultraviolet light, phosphorus must be used to convert the ultraviolet light into visible light. During this process, about half of the energy of the UV quanta is lost.

Theoretically, in order to obtain a low-pressure discharge that emits visible light,
It is possible to use volatile metal halides.
Although such metal halides are very reactive, they were investigated for their use in certain types of electrodeless discharge tube devices.

In an E-discharge (also known as inductively-coupled discharge) device, the discharge occurs as a single loop forming the secondary of a transformer, the primary being formed by a coil having a high permeability core. It has been found that low pressure metal halide discharges operated in this manner cause widespread instability and are therefore impractical as light sources.

In E-discharge devices, the discharge tube is located between capacitor plates that are excited by a high frequency source. However, the current that sustains the discharge must flow as the displacement current through the glass wall or silica wall of the discharge tube, and it is difficult to generate a discharge with sufficient power. The excitation frequency increases the current, and thus also the dielectric loss due to the glass or silica walls, resulting in significant power losses due to the walls of the discharge vessel.

Another type of electrodeless discharge is known as "ultra high frequency" discharge. In such a discharge,
The wavelength of the excitation source is shorter than or comparable to the discharge dimension. Such discharges have been investigated for many years, but due to power generation and shape issues,
The possibility as a commercially practical light source was not obtained.

It has been found that a discharge operating in the above three prior art aspects using a low pressure metal halide encapsulation, under poor conditions, tends to form bristles that adhere to the walls of the discharge vessel. This results in strong local hot spots,
Therefore, the light source is useless. Moreover, the generated discharge is unstable and gives a fluctuating load to the generator, which causes difficulty in matching. In addition, the structure that excites and sustains the discharge during use of the discharge device itself darkens the discharge, thus reducing the amount of light for the observer.

[Problems to be Solved by the Invention] An object of the present invention is to provide a discharge tube that can be used as a light source that can avoid at least the above various problems.

Means for Solving the Problems A first feature of the present invention is a method for generating visible light from a discharge tube having a wall made of a transparent dielectric material, wherein the discharge tube comprises:
An enclosure comprising at least one compound selected from the group consisting of a metal halide and a metal oxyhalide is encapsulated, and the method comprises the step of providing a wall of the discharge vessel with sufficient power to excite surface waves of the enclosure. Applying a radio frequency (rf) electric field over a portion of the
The fill is excited to emit visible light.

The inventor has discovered that in a discharge tube without electrodes, a stable and well-acting low-pressure metal halide discharge can be achieved by exciting the discharge using surface waves. Metal halides are at least partially dissociated, and light is emitted in the visible region from both separated atoms and molecules. Metal oxyhalides are believed to behave similarly to metal halides.

A second feature of the present invention is a discharge tube device that emits visible light, the device comprising a discharge tube having a wall made of a transparent dielectric material, wherein the discharge tube comprises a metal halide and a metal oxyde. Enclosing an enclosure comprising at least one compound selected from the group consisting of halides, the apparatus further comprising a portion of the wall of the discharge vessel with sufficient power to excite surface waves of the enclosure. Means for applying a radio-frequency (rf) electric field across which causes the fill to be excited in use to emit visible light.

A discharge tube device according to this aspect of the invention can be used to emit visible light in a method according to the first aspect of the invention.

Preferably, the means for applying a radio frequency electric field comprises a radio frequency power generator and a launcher. Thus, the printing means can be arranged so as not to substantially darken the discharge, and the discharge itself can be of length from centimeters to meters and from millimeters to centimeters, depending on the power used. It has a diameter up to the meter.

Embodiment An embodiment of the present invention will be described by way of example only with reference to the accompanying drawings.

As shown in FIG. 1, the discharge tube device comprises a discharge tube 20 mounted on a launcher 22. The discharge tube 20 is formed of a translucent dielectric material such as glass, and encloses an enclosure 24.

The launcher 22 is made of an electrically conductive material such as
It is formed as a coaxial structure consisting of 26 and an outer tube 28.
The first plate 30 at one end of the outer tube is the first plate 30 of the launcher structure.
Of the end wall. A second plate 31 at the other end of the outer tube 28 and integral with the outer tube forms a second end wall. Inner tube 26 is shorter than outer tube 28 and is positioned within outer tube 28 to form a first annular gap 32 and a second annular gap 33. First plate 30
And each of the second plates 31 has an opening for receiving the discharge tube 20. The outer tube 28, the first plate 30, and the second plate 31 form a continuous conductive corridor path, but do not make electrical contact with the inner tube 26, which creates a radio frequency shielding structure therearound.

Suitable dimensions for the launcher of FIG. 1 are as follows.

Launcher length 7 ~ 20mm Diameter of launcher 25 ~ 35mm, (diameter of outer diameter 28) However, it depends on the size of discharge tube 20.

Length of inner tube 26 3 to 18 mm Diameter of inner tube 26 13 mm, depending on size of discharge tube 20.

The length of the launcher gap (first gap 32) is 0.5 to 3 mm. The length of the second gap 33 is 1 to 10 mm. The thickness of the conductive material is on the order of millimeters or less depending on the construction method used.

A radio frequency power generator 34 (shown schematically) is connected to the inner tube 26 of the launcher 22 by a coaxial cable 35 and an impedance matching network 36 (consisting of a capacitor 37 and an inductor 38 as shown schematically). Connected. The radio frequency power generator 34, the impedance matching network 36, the coaxial cable 35, and the launcher 22 constitute a radio frequency power exciter, and supplies power to the enclosure to generate discharge.

The body 40 of the dielectric material inside the launcher 22
It is provided as a structural element that maintains the size of the 2,33 and holds the inner tube 26 in place. The body 40 also helps shape the electric field in the gaps 32, 33 to facilitate launcher activation or other purposes. Suitable dielectric materials that provide low loss at radio frequencies are glass, quartz and polytetrafluoroethylene (PTFE). Alternatively, the launcher may be partially or completely air-filled, provided that means for supporting the inner tube are provided.

When the radio frequency power generator 34 is turned on, typically 1 MHz
An oscillating electric field having a frequency in the range of 1 GHz to 1 GHz is set inside the launcher 22. This electric field is parallel to the longitudinal axis of the discharge tube 20 at the first and second annular gaps 32,33. When sufficient power is applied, the resulting electric field in the enclosure 24 is sufficient to cause a discharge, which in turn causes the application of EP 0 257 533.
Electromagnetic surface waves are propagated in a similar manner to the A2 device. Thus, the launcher 22 powered by the radio frequency power generator 34 generates and maintains a discharge in the fill, the length and brightness of the discharge depends, inter alia, on the size of the discharge tube 20 and the radio frequency power generator. Depends on the power applied at 34. Therefore, such a discharge tube device can be used as a light source.

To obtain a discharge tube that emits visible light,
It shall consist of a compound selected from the group consisting of metal halides and metal oxyhalides, and a noble gas such as argon. Mercury is also added.

The inventor has tried an enclosure containing aluminum chloride (AlCl ₃ ) and a noble gas, ie, argon (Ar). This enclosure was found to produce a stable discharge emitting visible light when excited by a surface wave.

The use of metal halides from the transition series of the periodic table, such as titanium, iron and niobium, is advantageous. These halides are sufficiently volatile to produce a vapor pressure that can cause a discharge at the operating temperature of the discharge vessel wall.
These are dissociated by electron impact. As a result, excited atoms, ions, and molecules emit radiation, and metal atoms have many relatively low energy levels that cause radiation throughout the visible region.

Neodymium (Nd) and other rare earth metal halides also emit radiation throughout the visible region when excited. These are relatively non-volatile, but can form complexes with other metal halides (known as complexing agents). The vapor pressure of the complex formed is a factor of 10 ⁵ and greater than that of rare earth metal halides.
The complex should have, for example, a total vapor pressure in excess of about 10 ^-3 Torr at lamp operating temperatures up to 250 ° C. Examples of complexing agents include the following halides (ie, chloride, bromide, or iodide, where X is Cl, Br or I).

That is, aluminum (AlX ₃ ), indium (InX ₃ ),
There are gallium (GaX ₃ ), tin (SnX ₄ ), titanium (TiX ₄ ) and ferric chloride (III) (Fe ₂ Cl ₆ ) compounds. As the complex, NaAlCl ₆ (complex of NaCl ₃ and AlCl ₃ ) and NaAlCl ₄ (Na
Cl and AlCl ₃ complex).

The inventor has considered that a stable discharge is generated by surface waves from an enclosure containing the following mixture.

Tin (II) iodide (SnI ₂ ) + sodium iodide (NaI) + AlCl ₃
+ Ar; AlBr ₃ + SnCl ₂ + niobium chloride (V) (NbCl ₅ ) + Ar; indium (I) bromide (InBr) + AlCl ₃ + Ar; thallium iodide (TlI) + AlCl ₃ + Ar; SnCl ₂ + AlBr ₃ + Ar; iron iodide (II) (FeI ₂ ) + AlBr ₃ + Ar; TlI + NaI + FeI ₂ + AlCl ₃ + Al; NaI + AlBr ₃ + Ar; TlI + NaI + FeI ₂ + AlBr ₃ + Ar; InI + AlBr ₃ .

Argon is used to increase the overall vapor pressure, which can be replaced by neon, helium or another noble gas such as krypton.

Further, oxidized halides of certain metals (ie, oxychloride, oxybromide or oxyiodide, where X is Cl, Br or I) are contemplated as described below. That is, chromium oxide halide (CrO ₂ X ₂ ) and vanadium oxide halide (VOX ₂ and VOX ₃ ), molybdenum oxide halide (M ₀ O ₂ X ₂ and M ₀ OX ₄ ), and tungsten oxide halide (WO ₂ in X ₂ and WOX _4), which may be used to fill that emits visible light to be excited.

[Brief description of the drawings]

FIG. 1 is a cross-sectional side view of a discharge tube device as an embodiment according to the present invention. 20 discharge tube, 22 launcher 24 enclosure, 26 inner tube, 28 outer tube 30 first plate, 31 second plate 32 first annular gap 33: second annular gap 35: coaxial cable 36: impedance matching network 37: capacitor 38: inductor, 40: body

Continuation of the front page (72) Inventor David Osbourne Whamby Beecon Road, Roxburgh, LEE 11 2BEE Leicestershire, UK 65 (56) References JP-A-62-140355 (JP, A) (58) Survey Field (Int.Cl. ⁶ , DB name) H01J 65/04

Claims (4)

(57) [Claims] 1. A low-voltage discharge tube having a wall made of a transparent dielectric material, said discharge tube being made of aluminum trichloride or aluminum.
A tribromide and an inert gas and an enclosure consisting of at least one compound selected from the group consisting of metal halides and metal oxyhalides, with sufficient power to excite surface waves of said enclosure, A discharge tube device, comprising: means for applying a radio frequency electric field over a part of the wall of the discharge tube, wherein the applying means excites the enclosure and emits visible light. 2. A low voltage discharge tube having a wall made of a transparent dielectric material, said discharge tube being made of aluminum trichloride or aluminum.
A tribromide and an inert gas and an enclosure consisting of at least one compound selected from the group consisting of metal halides and metal oxyhalides, with sufficient power to excite surface waves of the enclosure, Means for applying a radio-frequency electric field formed by a radio-frequency power generator and a launcher over a part of the wall of the discharge tube, wherein the applying means excites the enclosure and emits visible light. Discharge tube device characterized by emitting. 3. A low-voltage discharge tube having a wall made of a transparent dielectric material, said discharge tube being made of aluminum trichloride or aluminum.
Applying a radio-frequency electric field over a part of the wall of the discharge vessel with sufficient power to excite surface waves of the enclosure, containing tribromide and inert gas and transition metal halide as enclosure A discharge tube device, comprising: means for exciting the enclosure by the application means to emit visible light. 4. A low-voltage discharge tube having a wall made of a transparent dielectric material, said discharge tube being made of aluminum trichloride or aluminum.
A radio frequency power generator containing tribromide and an inert gas and a transition metal halide as an enclosure and having a power sufficient to excite surface waves of the enclosure and over a portion of the wall of the discharge vessel; A discharge tube device, comprising: means for applying a radio frequency electric field formed by the device and the launcher, wherein the application means excites the enclosure and emits visible light.