DE2457815A1 - High power discharge tube with metal halide for pumping lasers - comprising long capillary discharge tube with cooling jacket - Google Patents

Abstract

The high pressure discharge lamp with metal halide, pref. for use as pumping light source for lasers, consists of an extended capillary as discharge tube with an electrode fused into each end, which is surrounded by a vessel through which cooling fluid flows up to the electrode cavities and contains a rare gas, pref. Xe as buffer in addn. to the metal halide, which pref. is a Tl or rare earth (Dy) halide esp. iodide. The inlet and outlet for the cooling liq. pref. are at an angle to the cooling vessel, so that the liq. enters and leaves this tangentially. Used for pumping dye lasers, such as those with rhodamine 6G as medium; and also in photochemistry and reprography. Effective cooling is achieved and the lamp output is increased.

Description

Metal halide high pressure discharge lamp The invention relates to a high pressure discharge lamp with metal halide. Such lamps are in different Embodiments and known for very different uses. The present Lamp should preferably be used as a pump light source for lasers, i.e. the Radiation emitted by the lamp should as far as possible be within a certain wavelength range of the spectrum, the position of which, for example, has been chosen in such a way that it corresponds to the range of the largest absorption coefficient of a laser coincides. Under pump light source a light source is understood which is responsible for the induced emission of the laser supplies the required energy.

It is known to use high-pressure mercury vapor discharge lamps for such purposes to use. Also a high pressure mercury vapor discharge lamp with thallium halide has already become known as a pump light source for a ruby laser (DT-AS 1 241 532).

Because of the high wall load caused by the high concentration of power these types of lamps need to be cooled. The invention is particularly effective Cooling and increasing the radiant power of the lamp are aimed at.

The high pressure discharge lamp with metal halide for the preferably Use as a pump light source for lasers is characterized by H H Ol j 61/12 that the lamp consists of a long capillary as a discharge tube with one on each The ends of the fused electrode, which is up to the electrode spaces of one is surrounded with the cooling liquid flowing through the vessel and its filling in addition to metal halide Contains noble gas as a buffer gas.

Due to the capillary shape of the discharge vessel, which results from the intended use of the lamp, and due to the high electrical power consumption of the lamp the thermal load on the vessel wall is very high; the vascular material is up close heated to its melting point. The particular embodiment of the cooling device according to the invention now has the great advantage that on the one hand the high wall load generated heat is dissipated from the discharge tube without on the other hand the enlarged Electrode chambers are cooled. This is of vital importance for lamps which contain metal halides, since one encompasses the entire discharge vessel Cooling does not get enough vaporized substance in metal halide to power the lamp to be able to operate optimally.

Advantageously, feed and discharge nozzles for the cooling liquid attached to the cooling vessel at such an angle that the cooling liquid is tangential enters the cooling vessel and a coolant and thus heat build-up compared to the Entry points of the liquid can arise and accordingly no momentary Overheating of the vessel wall can destroy it.

The radiant power of the lamp in a certain spectral range can be increased by the composition of the filling. E.g. for using the lamp to pump a dye laser (medium rhodamine 6 G) thallium halide, preferably thallium iodide, as a metal halide as particularly proved suitable. The radiation power can be in the absorption range of the laser compared to lamps with mercury increase if you add the thallium halide a noble gas of higher pressure, preferably xenon, is used. The radiation from mercury lamps is not because of the unfavorable spectral position of the green Quec silver line suitable the spectral radiance of only xenon containing Lamps is not high enough in the absorption range of the laser used. According to the invention must be the partial pressure of the buffer gas used, i.e. in the visible - in contrast to mercury - noble gas not excited to radiation, high compared to that of des Thallium halide, higher than 150 torr. Because of the low partial pressure of the thallium halide several advantages are achieved at the same time. Except the There is no resonance line of thallium lying at the maximum of the laser absorption Longer-wave radiation, causing triplet absorption, i.e. a reduction in the Laser power, is avoided. There is no strong broadening of the thallium resonance line, no strong self-absorption and no white thallium halide molecular continuum on.

But you get by using an inert gas as a buffer gas (no optical emission in the visible) with a higher ionization voltage than thallium despite the low partial pressure of thallium, the advantages of a high pressure discharge. The small Ramsauer cross-sections of the light noble gases lead to the small ones Discharge channel dimensions to a rapid deionization of the plasma and thereby difficult reignition, but the large Ramsauer cross-section of mercury has the far more serious disadvantage of leading to excessive operating voltages.

The lamp according to the invention is intended for the first time to be a continuous Operation of a paraffin laser with an incoherent pump light source allows will. The achieved with the lamp according to the invention. Pump power is at least twice as high as with one of the previously known lamps, without the special one Execution of the cooling and without noble gas as buffer gas. The lamp is but also for other purposes, e.g. in photo chemistry or for reprography well suited. In principle, other metal halides can also be used in the inventive Find lamps for the respective application purposes, e.g. the halides the rare earths, such as dysprosium halide, preferably dysprosium iodide.

In the figures is an embodiment of the lamp according to the invention reproduced.

Figure 1 shows a lamp according to the invention, Figure 2 shows the approach of Inlet and outlet connections to the discharge vessel for the coolant.

The discharge vessel 1 in FIG. 1 made of quartz glass has an inside diameter of about 3.5 mm, a wall thickness of 1 to 2 mm, a volume of about 3 cm3 and an optically usable length of the capillary of 200 mm. The total length of the lamp is approx. 380 mm.

The electrodes 2 and 3 are made of tungsten with the addition of thorium oxide Connected to the external power supply lines 6 and 7 via a foil seal 4 and 5 each. The cooling vessel 8, which has the expanded electrode spaces, is arranged around the discharge path 9, 10 leaves free and is fused tightly to the discharge vessel 1 at the ends. The cooling vessel 8 has an outside diameter of approximately 11 mm. As a coolant is decalcified water with a flow rate of about 8 1 / min used, which over the Connection 11 is fed to the cooling vessel 8 and discharged via the connection 12. By With additives, the coolant can also act as a radiation filter.

The nozzles 11 and 12 are each below according to FIG such a curvature attached to the cooling vessel 8 that one to the circumference of the discharge vessel 1 tangential entry of the cooling water into the cooling vessel 8 and thus a rotation of the cooling liquid takes place around the arc axis and no stagnation point in the coolant channel opposite the attachment points occurs.

The lamp contains xenon as a filling with a cold filling pressure of 200 to 400 torr, preferably 300 torr, and 5 to 40 mg, preferably 20 mg, thallium iodide. The internal wall load of the discharge vessel 1 is 150 to 300 W / cm2. At a The supply voltage is a current of 14 to 18 A and an operating voltage of 450 V ~ about 600 V AC. The current-voltage characteristic is increasing sharply. The lamp is operated via a regulating throttle and ignited with an HF igniter. The emission reached at 535 nm, in the area important for pump light sources about 10% of the electrical power. In addition to the radiation in the green spectrum, i the lamp delivers in the long-wave ultraviolet (351.9 + 352.9 + 377.5 nm) Radiation component of a similar size.

- patent claims -

Claims (6)

Claims for high pressure discharge lamp with metal halide the preferred use as a pump light source for lasers, characterized in that that the lamp consists of an elongated capillary as a discharge tube with one each There is an electrode melted at the ends, except for the electrode spaces is surrounded by a vessel through which cooling liquid flows and its filling in addition to metal halide contains noble gas as buffer gas. 2. High pressure discharge lamp according to claim 1, characterized in that that in the filling the metal halide with low partial pressure and the buffer gas with a high partial pressure of greater than 150 Torr. 3. High pressure discharge lamp according to claim 1 and 2, characterized thereby, that the buffer gas is xenon. 4. High pressure discharge lamp according to claim 1 to 3, characterized in that that the metal halide is a halide of thallium, preferably thallium iodide. 5. High pressure discharge lamp according to claim 1 to 3, characterized in that that the metal halide is a rare earth halide, preferably dysprosium iodide. 6. High pressure discharge lamp according to claim 1 to 5, characterized in that that the inlet and outlet nozzle for the cooling liquid at an angle is attached to the cooling vessel in such a way that the cooling liquid enters the Cooling vessel in and out. L e r s e i t e