JPH04315761A - Deuterium electric discharge lamp - Google Patents

Abstract

PURPOSE:To reduce oscillation of ultraviolet output, extend the life, enhance the reliability, and achieve high efficiency of a deuterium discharge lamp by providing a hollow cathode within a discharge container having an ultraviolet- ray transmitting window. CONSTITUTION:A hollow cathode 1, an anode 2 and an electrode case 4 are provided within a discharge container 6 having an ultraviolet-ray transmitting window 5 and deuterium gas is sealed therein. The case 4 is of such a structure as to surround the cathode 1 and the anode 2 and a small hole 3 for constricting discharge is provided through a partition wall located between the anode 2 and the transmitting window 5. As to power supply to each electrode, the power supply is connected to the anode 2 through a lead wire 10 and to the cathode 1 through lead wires 11, 12 and that portion of each lead wire connected to the anode 2 which is located inside the lamp is covered with an insulating sleeve 8 in order to prevent abnormal discharge. A deuterium electric discharge lamp in which oscillation of ultraviolet output is reduced and which has long life, high reliability and high efficiency is thus provided. A spectrometer of high sensitivity and high reliability may be formed using the lamp.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a deuterium discharge lamp used as an ultraviolet light source in scientific measuring instruments such as spectrophotometers and liquid chromatographs.

0002

[Prior Art] Conventionally, deuterium discharge lamps were
It was as described in No.-9977. That is, Figure 5
(a) is a partially cutaway view of a conventional deuterium discharge lamp seen from the front. FIG. 5(b) is a sectional view taken along line AA' in FIG. 5(a). A cathode 5 is placed in a discharge vessel 6 having an ultraviolet-transmitting window 5.
1, an anode 2 and an electrode enclosure 4 are provided, and deuterium gas is sealed at several Torr. The electrode enclosure 4 has a structure that surrounds the cathode 51 and the anode 2, and has a diameter of about 1 mm in front of the anode 2 to constrict the discharge.
A small hole 3 is provided. A portion of the electrode enclosure 4 between the small hole 3 and the ultraviolet transmitting window 5 is open so that light can be extracted. A slit 7 is also provided in the partition wall surrounding the cathode 51.

[0003] The connection of the power supply to each of the above electrodes is as follows:
is connected through the lead wire 10, and the cathode 51 is connected through the lead wire 11 and the lead wire 12. In order to prevent abnormal discharge, the lead wire portion to the anode 2 inside the lamp is covered with an insulating sleeve 8. The lead wire 14 supports the electrode enclosure 4 and can also be electrically connected to apply a potential to the electrode enclosure 4 if necessary. At startup, approximately 10V is applied to the cathode 51 (between the lead wires 11 and 12) to heat it, and the anode 2 is heated (between the lead wires 1 and 1).
1 and the lead wire 10) to start the discharge by applying a high voltage necessary to start the discharge. When lighting, the voltage of the cathode 51 is approximately 4V.
The discharge current is approximately 300 mA. At this time, discharge occurs between the cathode 51, the slit 7, the small hole 3, and the anode 2. The ultraviolet rays generated by the constricted discharge caused by the small holes 3 are extracted through the ultraviolet transmitting window 5. Now, the cathode 51 has BaO and Sr on top of a coiled filament.
An electron emitting substance such as O or CaO is coated.

0004

[Problem to be Solved by the Invention] In the cathode of the conventional deuterium discharge lamp described above, a cathode bright spot is generated when the lamp is lit, and the temperature locally becomes high in this part, and thermionic emission occurs actively. ing. Therefore, most of the discharge current is concentrated in this part. At the cathode bright spot, since the temperature is high, electron-emitting substances such as BaO evaporate directly or after being reduced to Ba, etc., and because the current is concentrated, they are scattered by sputtering. For this reason, there is a phenomenon in which the electron emission characteristics near the cathode bright spot deteriorate and the cathode bright spot moves to an adjacent area. In this case, a drift occurs in the light output of the deuterium discharge lamp. This was an unavoidable drawback as long as a coiled cathode was used, as in conventional deuterium discharge lamps. In addition, the surface area coated with electron emitting material such as BaO is sufficiently large compared to the surface area of the cathode bright spot, and the cathode bright spot may move randomly, or there may be a large temperature gradient between the cathode bright spot and the adjacent area. Therefore, cracks may occur in the electron emitting material such as BaO, and the cathode bright spot may suddenly move.

When the cathode bright spot moves in this way, random or step-like fluctuations occur in the light output of the deuterium discharge lamp. When used as a light source for a measuring instrument, especially a measuring instrument that measures the absorption amount of a substance, the fluctuation of the lamp determines the detection limit of the measuring instrument, and the smaller the fluctuation, the better the detection limit. Such fluctuations in the lamp become particularly large as the lighting time increases, making it impossible to use the lamp as a light source for measuring instruments, and thus reaching the end of the lamp's lifespan. In this way, the reliability of deuterium discharge lamps was determined by the deterioration of the cathode.

Furthermore, as mentioned above, in the conventional deuterium discharge lamp, the discharge path is narrowed by the small hole 3 in the positive column between the cathode 51 and the anode 2, and the ultraviolet light emitted from this area is used. Ta. Ultraviolet light is also emitted from the negative glow generated near the cathode, but as the cathode bright spot moves, the light emitting spot also moves, so it cannot be used and is wasted. For this reason, the lamp's efficiency in utilizing ultraviolet light was poor.

It is an object of the present invention to provide a deuterium discharge lamp which is highly reliable, has a long life and is highly efficient.

[0008]

[Means for Solving the Problems] The above object is achieved by providing a hollow cathode.

[0009]

[Operation] By using the hollow cathode mentioned above,
The cathode bright spot is fixed in the hollow and does not move, eliminating fluctuations in ultraviolet output. Furthermore, since there is no movement of the cathode bright spot, light emission from the vicinity of the cathode can be used.

0010

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1(a) is a sectional view of the center of a deuterium discharge lamp according to an embodiment of the present invention, viewed from the side. A hollow cathode 1 is disposed in a discharge vessel 6 having an ultraviolet-transmitting window 5.
An anode 2 and an electrode enclosure 4 are provided, and deuterium gas is sealed therein. The electrode enclosure 4 has a structure that surrounds the cathode 1 and the anode 2, and a partition wall between the anode 2 and the ultraviolet light transmission window 5 is provided with small holes 3 for confining the discharge.
is provided. The diameter of the small hole 3 is, for example, 1 mm, and several Torr of deuterium is sealed therein. To connect the power to each of the electrodes described above, the anode 2 is connected through the lead wire 10.
The cathode 1 is connected through a lead wire 11 and a lead wire 12. In order to prevent abnormal discharge, the lead wire portion to the anode 2 inside the lamp is covered with an insulating sleeve 8.

FIG. 1(b) shows the structure of the hollow cathode 1.
This will be explained in detail using Figure 1(b) shows the hollow cathode 1.
FIG. The cathode 1 has a filament 21 wound along the inner surface of a cylindrical insulator 20 made of alumina or the like with one side open, and an oxide 22 such as BaO as an electron emitting material in the gap between the filament 21 and the insulator 20. Filled. The cylindrical insulator 20 is fixed by a lead wire 11 and a fixing band 23. filament 21
are connected to a power source through lead wires 11 and 12, and heated by electricity. At the time of starting the discharge, a voltage of, for example, 10 V is applied to sufficiently heat the oxide 22 to facilitate the emission of thermoelectrons, thereby facilitating the start of the discharge. During steady state, self-heating occurs due to discharge, so the filament voltage is lowered to about 4V. The discharge current is about 300mA. In the cathode 1 having such a hollow structure, a negative glow is formed inside the cathode 1. If this inner diameter is set to about 1 to 5 mm, for example, a negative glow is stably formed in the center of the cathode 1. A discharge occurs between the cathode 1, the small hole 3, and the anode 2. Small hole 3
The ultraviolet rays generated by the constricted discharge are extracted from the ultraviolet transmitting window 5. The cathode spot of this ultraviolet light is fixed in the hollow and does not fluctuate, so the discharge path does not fluctuate, so the ultraviolet light output is extremely stable and does not fluctuate. Therefore, a highly reliable and long-life deuterium discharge lamp can be realized. In this embodiment, the electrode enclosure 4 is supported by the lead wire 10 via the insulating sleeve 8, but if necessary, other lead wires may be provided and electrically connected to the electrode enclosure 4. It is also possible to apply an electric potential.

Another embodiment of the hollow cathode 1 of the present invention is shown in FIG. The hollow cathode 1 is a thin-walled pipe 24 made of a high melting point metal such as tungsten, molybdenum, tantalum, etc., with one end open and the other end fixed to the lead wire 11 by caulking. It is connected to the lead wire 12 at the open end side. Inside the pipe 24, the oxide 22 is connected to the coil 2.
It is applied together with 5. Coil 25 is oxide 22
It is used to prevent it from falling off. Lead wire 1
When a voltage is applied between the lead wire 12 and the lead wire 12, the pipe 24 acts as a resistor and generates heat, and the oxide 22 is heated. The lighting method and the fact that fluctuations in the ultraviolet light output are reduced are exactly the same as in the embodiment shown in FIG. The embodiment of FIG. 2 has the advantage of being easier to assemble.

As mentioned above, during steady lighting, the voltage applied to the cathode is usually lowered, but it is also possible to use only self-heating by discharge without applying any voltage. This is because the cathode spot does not move even if no potential gradient is applied to the cathode, and since the cathode is a hollow cathode, photoelectron emission occurs even when light is emitted from negative glow, and electrons are emitted efficiently. In addition, fluctuations in the ultraviolet output are reduced and this state can be maintained for a long time, resulting in a long-life deuterium discharge lamp.

Next, another embodiment of the present invention will be explained using FIG. FIG. 3 shows a deuterium discharge lamp that has a hollow cathode and uses light emission from inside and near the cathode. A hollow cathode 1 and an anode 2 are provided in a discharge vessel 6 having an ultraviolet transmitting window 5, and several Torr of deuterium gas is sealed therein. As the hollow cathode 1, for example, a cathode as shown in FIG. 2 is used. The anode 2 is placed opposite the hollow cathode 1 and has a ring shape. The hollow cathode 1 is connected to a cathode heating power source through lead wires 11 and 12. The anode 2 is connected to the main power source through a lead wire 10. The lead wire 10 is covered with an insulating sleeve 8 to prevent abnormal discharge. The cathode spot is fixed inside the hollow and a negative glow is created inside and near the hollow. In this embodiment, the light emitted from the negative glow is extracted to the outside through the ultraviolet transmitting window 5. As a result, the negative glow emission point is fixed for a long period of time, which was impossible with conventional coiled cathodes, and fluctuations in the intensity of ultraviolet rays are also greatly reduced. Furthermore, this embodiment has the feature that the lamp voltage is low because there is no constricted part unlike the conventional deuterium discharge lamp, and a deuterium discharge lamp with low power consumption and high efficiency can be realized.

FIG. 4 shows still another embodiment of the present invention. FIG. 4 shows a deuterium discharge lamp that has a hollow cathode and uses light emitted from inside and near the cathode as well as light emitted from a narrowed portion of the discharge path. Components with the same reference numerals as those in the embodiment of FIG. 3 have the same functions, and their explanation will be omitted here. A partition plate 9 having small holes 3 for narrowing the discharge path is installed immediately in front of the hollow cathode 1. In this embodiment, the cathode spot is fixed for a long period of time as in the embodiment of FIG. 3, and furthermore, fluctuations in the intensity of ultraviolet rays are extremely reduced. Furthermore, this embodiment has the excellent feature that extremely strong ultraviolet light intensity can be obtained since the light emitted from the constricted portion is utilized in addition to the light emitted from the negative glow.

[0016]

According to the present invention, a deuterium discharge lamp with less fluctuation in ultraviolet output, long life, high reliability, and high efficiency can be obtained. Furthermore, by using the deuterium discharge lamp of the present invention, a highly sensitive and highly reliable analytical device can be realized.

[Brief explanation of the drawing]

FIG. 1 shows an embodiment of a deuterium discharge lamp with a hollow cathode.

FIG. 2 is a sectional view of another embodiment of a hollow cathode.

FIG. 3 is a diagram showing an example of a deuterium discharge lamp having a hollow cathode and using light emission from inside and near the cathode.

FIG. 4 is a diagram showing another embodiment of a deuterium discharge lamp having a hollow cathode and using light emission from inside and near the cathode.

FIG. 5 is a diagram showing a conventional deuterium discharge lamp.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1...Hollow cathode, 2...Anode, 3...Small hole, 4...Electrode enclosure, 5...Ultraviolet transmission window, 21...Filament, 22...Oxide.

Claims (2)

[Claims] 1. A deuterium discharge lamp for discharging deuterium or hydrogen, characterized by having a hollow cathode and means for constricting a portion of the positive column. 2. A lamp for discharging deuterium or hydrogen, characterized by having a hollow cathode and extracting ultraviolet light from inside and near the cathode to the outside of the lamp as an ultraviolet light source. Hydrogen discharge lamp.