The invention relates to a gas discharge lamp in accordance with the preamble of claim 1, as well as to a light source having such a gas discharge lamp which preferably serves as a mercury spectral lamp.
From U.S. Pat. No. 5,013,966 a type of gas discharge lamp having external electrodes is known. In this the electrodes are formed as ring electrodes and respectively surround a cylindrical section of the gas discharge tube. In this respect the ring electrodes have a relatively large surface area and are formed as a type of clamp. The limited life time is common for all known gas discharge lamps which results, in particular due to a blacking of the inner side of the discharge tube. This is particularly true for mercury lamps, presumably because the mercury ions are impinged into the quartz glass surface of the discharge tube and react there to become mercury oxide. This procedure is ever more effective the higher the speed is with which the ions impinge in the surface. The speed depends on the electric field perpendicular to the surface.
Starting from this prior art it is the object of the invention to provide an improved gas discharge lamp having external electrodes which has a higher life time.
This object is satisfied by a gas discharge lamp having the features of claim 1.
The gas discharge lamp in accordance with the invention includes a gas discharge tube having a cylindrical discharge region and two electrodes which are arranged at an outer side of the gas discharge tube, wherein each electrode has a planar disc-shaped holding section which each have respective openings and wherein the cylindrical discharge region is received in the openings in a shape matched manner, wherein the cylinder axis of the cylindrical discharge region lies perpendicular to the planar holding sections.
It has been shown that considerably less blacking is present on the inner side of the gas discharge tube when the electrodes are designed in a manner in accordance with the invention and only a small region of electrode, namely the inner sides of the boundary of the openings are in contact with the gas discharge tube. Through this the life time is also considerably increased. Experiments with mercury spectral lamps in which comparison measurements were made between identical gas discharge tubes but with different electrode formations namely, on the one hand, those known from the prior art in which the electrodes surround a cylindrical gas discharge tube in a clamping manner and, on the other hand, those having the design in accordance with the invention which have shown that the life time can be increased by more than a factor of 6. A possible part of the explanation for this long life time is presumably that the electro-magnetic field which is formed between the planar holding section with this specific geometry, i.e. flat discs, which discs are arranged parallel to one another and the arrangement of the gas discharge tube perpendicular thereto contribute thereto so that a reduced blacking occurs.
In a different embodiment material thicknesses of the holding sections of approximately 0.15 mm and a separation distance of the holding sections of approximately 3 mm have been found to be particularly advantageous.
In particular, in the use of a gas discharge lamp as a mercury spectral lamp the Zeeman components of the spectral lines are frequently required, so that the invention also includes a light source surrounding the gas discharge lamp in accordance with the invention, wherein magnets are provided between which a generally homogenous magnetic field can be generated.
So that the generated magnetic field is particularly homogenous in one embodiment of the light source in accordance with the invention it is provided that a north pole of a magnet is arranged at a side of the gas discharge tube and a south pole of a second magnet is arranged at the opposite side and in that both the north pole and also the south pole are formed from two partial magnets, whose like poles are arranged opposite one another and form the north pole and the south pole respectively, wherein a gap is formed between the opposing two north poles and between the opposing two south poles which gaps widen towards the gas discharge tube. A further increase of homogeneity can be achieved when the gaps are each filled with an iron core, wherein the shape of the end of the iron core facing the gas discharge tube is preferably formed in a concave shape.
In a different embodiment of the light source the magnets are arranged on opposite sides of the gas discharge tube and are formed as ring magnets whose one pole is arranged at the inner boundary and the other pole is arranged at the outer boundary. Such ring magnets are available on the market and can be supported in the light source in a constructively simple manner, so that the light source can be designed in a relatively simple manner in comparison to the previously mentioned embodiment.
On use of the gas discharge lamp in accordance with the invention as a mercury spectral lamp, the gas discharge tube is preferably composed from a quartz glass. Such a mercury spectral lamp is preferably used for the measurement of the mercury concentration of a gas.
In the following the invention will be described in detail by means of the drawing with reference to an embodiment. In the drawing there is shown:
As is illustrated schematically in
The light source 12 in accordance with the invention, which is shown in
As can be recognized, in particular from
Each electrode 12-2 and 12-3 in accordance with the invention has a planar disc-shaped holding section 12-6 and 12-7 which have respective openings 12-8 and 12-9. The cylindrical discharge region 12-4 of the gas discharge tube 12-1 is held in a shape matched manner in the openings 12-8 and 12-9. The holding sections 12-6 and 12-7 are arranged in parallel to one another and with its cylinder axis the cylindrical discharge region 12-4 lies perpendicular to the holding section 12-6 and 12-7.
In the embodiment the holding sections 12-6 and 12-7 have a material thickness of approximately 0.15 mm and are separated by distances of approximately 3 mm. They are preferably made of copper as a good electrical conductor.
The gas discharge tube 12-1 of the light source 12 is located in as homogeneous a magnetic field as possible which is generated by magnets 15 and which is aligned perpendicular to the optical axis at the position of light generation. Due to the Zeeman effect the σ+ Zeeman components, the σ− Zeeman components and the Π polarized Zeeman components of the spectral lines are generated in this way.
So that the splitting of the spectral lines is large enough and the spectral lines remain clear enough, i.e. are spectrally displaced at each position in the lamp by the same amount a sufficiently strong and homogeneous magnetic field has to be generated. For this reason the magnet 15 is formed in a particular manner, as is shown in
From the outside the magnets 15-1 to 15-4 are held by supports 15-8 and 15-9 which are preferably made of iron, to guide the magnetic field between the partial magnets 15-1 and 15-4 and/or 15-2 and 15-3 in a suitable manner. The support 15-9 has an opening 15-10 through which the light generated in the gas discharge tube 12-1 can exit out and arrive at the apparatus 10 along the optical axis 14.
As will be explained in more detail in the following the sufficient separation is important because the Π component ultimately delivers the measurement quantity, since the non-displaced Π component is absorbed and the displaced a components form a reference value as the displaced spectral components cannot be absorbed as was principally already known from the prior art (U.S. Pat. No. 3,914,054).
Finally,
In the following the use of the gas discharge lamp in accordance with the invention in the apparatus 10 for the determination of the mercury content of a gas is individually explained for a complete understanding.
The light generated in the light source 12 includes the Zeeman components of the mercury spectral lines in accordance with
The light then runs through an optical separator device 22 which is formed as a photo-elastic modulator 24 here, in which the birefringent properties of the modulator 24 influence the linear polarized Π components differently compared to the polarized σ+ components and to the σ− components perpendicular thereto. This difference in influence is achieved in synchronism to the rhythm of an alternating voltage which is applied to the piezo 26 which is supplied by a voltage source 28. In combination with the photo-elastic modular 24 having a polarizer which is not illustrated in detail, on the one hand, the polarization of the signal components is turned and at certain times only the σ+ components and the σ− components are let through and at other times only the Π components are let through. Thus, with the aid of the photo-elastic modulator 24 a timely separation of the Π component, on the one hand, and of the σ+ component and of the σ− component on the other hand is achieved.
Following this the light passes through a measurement cell 30 containing the mercury contaminants to be measured therein. The measurement cell could also, have a heating 32. The non-displaced spectral lines of the Π component experience an absorption at the mercury atoms in the measurement cell 30, in contrast to which the displaced σ+ components and the displaced σ− components do not experience an absorption due to the energy displacement so that the light of these lines serves as a reference light.
Finally, the light is received at the light receiver 34 and guided to a lock-in amplifier 38 which is triggered by the alternating voltage conveyed to the photo-elastic modulator 24. As a result a signal is then generated via the lock-in amplifier as is qualitatively shown with the reference numeral 40 in
Number | Date | Country | Kind |
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10 2009 059 705.0 | Dec 2009 | DE | national |