DE4208388A1 - Excimer laser with supply of gas mixt. for tube filling - is safeguarded against halogen leakage by separate stopping of supplies from high-pressure halogen and inert gas cylinders - Google Patents

Abstract

The laser tube (10) in its housing (11) is filled via a stopcock (V5) from a supply (12) in which a number of pressurised gas cylinders contain inert gases (1-3) and F2 or HCl (4). The cylinders are connected (L1-L4) via separate stopcocks (V1-V4) to a common outlet pipe (L5) feeding the laser housing. This arrangement precludes any high-pressure halogen connection to the laser, esp. if the pipe carries a continuous high-pressure supply of harmless inert gas which provides a leak detection facility. USE/ADVANTAGE - Esp. in clinical and industrial surroundings where leakage from halogen pipework cannot be tolerated. Safe supply is guaranteed without recourse to costly additional measures.

Description

The invention relates to an excimer laser with a gas supplier supply device for filling the laser tube and a process for filling the laser tube.

As is known, excimer lasers use a laser-active medium generated by that in the plasma of a gas discharge with participi generation of noble gas atoms and halogens (as well as other reactions highly excited excimers are formed.

The excimer laser gas mixtures typically consist of 3 - 6% of the active noble gas (e.g. Kr), 0.1 to 0.5% of a halogen donor (e.g. F ₂ or HCl) and a light buffer gas such as He or Ne at a total pressure of 1.5 to 4 bar. The gases are usually available in pressure cylinders. The halogen gas itself is very aggressive and toxic and is also supplied diluted in pressure containers as standard. 5% halogen with 95% helium are typical.

The excimer laser gas mixture is usually made up of at least two, but often three, pressure vessels filled with noble gases and a pressure vessel filled with the halogen gas first mixed in the excimer laser tube. For this one of the Use the appropriate number of filling lines for the number of pressure vessels det.

A suitable arrangement for this is shown in FIG. 1. In the gas bottle cabinet 12 there are a total of four gas bottles. Noble gases are transported via lines L1 to L3, and the halogen gas is conveyed to laser 11 via line L4. The gas flow is regulated via four valves within the laser housing 11 , which are arranged in the respective lines. The lines open in the housing 11 of the laser in a line leading to the laser tube 10 .

The fill lines are all under pressure during operation. The line pressure in such a conventional arrangement is usually 5 bar. In the event of a leak, the halo provides gene filling line is a source of danger because gaseous chlorine highly corrosive and other gaseous halogens and are toxic.

The risk of a leak in the halogen line can vary in many ways turns are not tolerated. Especially in medicine the proximity of a larger number of people as well as the property of a patient who may not be transportable during problematic of laser operation and also in industrial use safety at work must be taken into account.

There have therefore already been considerations of how to take this risk could be encountered.

The following measures have already been taken in the past led:

• a) The halogen line was provided with a double wall.
• b) The halogen bottle was in the bottle cabinet directly on the Bottle equipped with a second valve to the Druckbe to be able to shut off the container separately.

The invention has for its object a secure Versor to ensure the supply of the laser tube with halogen gas without expensive additional measures would have to be taken.

To solve this problem, an excimer laser with a gas Supply device for filling the laser tube suggested gene, which is characterized in that at least the line a halogen gas source and at least one line one not Halogen gas supplying gas source in the gas supply device device, which is arranged remotely from the housing of the laser Valves open into a common line leading to the laser tube leads.

Preferred configurations of the excimer laser according to the invention are described in the dependent claims. In particular be Claim 7 contains a method for particularly safe Transfer of halogen gas into the laser tube.

Exemplary embodiments of the invention are described below the drawing explained in more detail. It shows:

Fig. 2 shows an embodiment of an excimer laser to a gas supply device;

Fig. 3 shows a detail of the gas supply device according to Fig. 2 and

Fig. 4 shows a gas supply apparatus according to FIG. 2, in addition to a control unit for controlling the gas partial pressures.

According to Fig. 2 a laser tube 10 is disposed in a housing 11 of the laser. The laser tube 10 and the housing 11 thus form the actual laser, the various supply devices, in particular the electrical circuits of the laser, being arranged in the housing 11 . This is the general state of the art.

Another housing is arranged separately and distant from the housing 11 of the laser, namely that of a gas supply device 12 in which a number of gas sources 1 , 2 , 3 and 4 are accommodated in the form of pressurized gas bottles. The gas bottles are under a pressure that is significantly higher than the atmospheric pressure. The gas sources 1 , 2 and 3 each contain noble gases, while the gas source 4 contains a halogen gas, for example F ₂ or HCl. The halogen gas source can also have lower pressure.

Lines L1, L2, L3 and L4 each lead from the assigned Gas bottles gone and are off via valves V1, V2, V3 and V4 lockable. Between the individual gas sources Valves V1 to V4 are each arranged pressure reducing valves net. The valves V1 to V4 can be controlled.

Within the housing of the gas supply device 12 open all of the gas sources 1 , 2 , 3 and 4 leading lines L1, L2, L3 and L4 into a common line L5, which stood between the housing 11 of the laser and the gas supply device 12 bridges. The common line L5 leads to the laser tube 10 via a valve V5.

Instead of the arrangement shown in the embodiment according to FIG. 2 of a halogen gas source and three noble gas sources 1 , 2 and 3 , other compositions of gas sources can also be seen before, but at least one gas source for halogen gas or another dangerous gas is always present. The source of halogen gas does not have to supply pure F ₂ or HCl, but, as is customary in the prior art, noble gas is already added to reduce the dangers associated with the halogen gas, ie the halogen gas source 4 supplies a mixture of halogen gas and a noble gas , e.g. B. He.

As described above, only a single common line L5 leads from gas sources 1 , 2 , 3 and 4 to laser tube 10 . This significantly reduces the installation effort compared to the solution according to the prior art ( FIG. 1). The mobility of the laser is also considerably improved due to the only common supply line to the laser tube.

The arrangement shown in FIG. 2 makes it possible to remove the halogen gas source completely from the supply system in a simple manner. This is particularly advantageous for certain applications in the field of medicine, where the laser is often initially filled only once, for safety reasons.

With the arrangement shown, it is possible to ensure that, following a filling of the laser tube with fresh gas, there is no supply line to the laser under high halogen gas pressure. Rather, the line L5 can be permanently under higher pressure of a non-hazardous noble gas, and at the same time a reliable and safe leak test of the particularly critical area between the gas supply device 12 and the laser housing 11 can be carried out. For this purpose, the common supply line L5 is placed under increased inert gas pressure and the drop in pressure over time is determined by means of a pressure measuring device. The result can be entered into a computer which compares the pressure drop with a maximum allowable drop setpoint and emits a corresponding alarm signal in line L5 if the pressure drop is too great.

Even if there is a leak in the common supply line L5, this is relatively harmless because care is taken can only leak noble gases.

During the filling of the laser tube 10 with the various gases, the only common feed line L5 is only flowed through by halogen gas during the halogen gas filling phase. The filling of the laser takes place with negative pressure in the laser tube, ie first the laser tube 10 is evacuated and then halogen gas by opening valve V4 with valves V1 to V3 closed, transferred via line L5 and valve V5 into laser tube 10 . Since there is negative pressure, even in the event of a leak in line L5, no halogen gas can escape. Then the line L5 is automatically flushed with halogen gases when filling the laser tube 10 with the other noble gases from the noble gas sources 1 , 2 , 3 and after filling the laser tube 10 with the noble gases, the line L5 remains under noble gas pressure.

Fig. 3 shows part of the system of FIG. 2. Mutually speaking components are provided with the same reference numerals. In Fig. 3 only the halogen gas source 4 is shown, while the other gas sources (noble gases) are omitted. In the line L4, which leads away from the halogen gas source 4 , an orifice B is arranged, that is to say a narrowing in the flow cross section in the line L4. Cover B can further increase the security of the gas supply system. For this purpose, the flow cross section Q _{B of} the orifice B is selected so that it is very small in comparison to the effective flow cross section Q _{V5 of} the valve V5 and the line L5. Due to the flow cross-sections of the orifice B on the one hand and the valve V5 on the other hand, when the laser tube 10, which is under negative pressure, is filled with halogen gas, it is ensured that even if the line L5 is defective, no halogen escapes into the external atmosphere. The orifice B inevitably limits the amount of halogen gas flowing in so far that the line L5 is under negative pressure even when the laser tube 10 is loaded with laser gas.

Fig. 4 shows an embodiment of the gas supply system according to FIGS. 2 and 3, again only the parts of particular interest are shown, here the gas source 4 for halogen gas, while the other gas sources are not shown in detail Darge. FIG. 4 is to think supplemented as FIG. 3.

According to FIG. 4, a control unit 13 in the vicinity of the Gasquel len 1, 3 and 4 are arranged in the housing of the gas supply device 12 2. The control unit 13 controls the valves V1, V2, V3 and V4. The valve control unit can be integrated into the overall control unit of the excimer laser, in particular a data ring control (LAN) of the excimer laser known in the prior art.

By means of the control unit 13 , which either has its own computer or is connected to a central computer which also controls the other functions of the laser, all of the processes described above can be automated, in particular the opening of the valves in particular, each up to a certain point specified partial pressures of the individual gases. Pressure is measured using a pressure sensor (not shown) in the laser gas reservoir. The control unit 13 can thus open the individual valves V1 to V4 one after the other and the partial pressure of the gas in question is set to a desired value (by controlled opening of the respective control valve V1 to V4).

With the pressure sensor 14 , it is also possible to monitor the entire system largely for leaks. For this purpose, the entire system by means of a single valve of an inert gas source, for. B. the valve V1, placed under high pressure, then the valve closed and the pressure drop measured by the pressure sensor 14 and evaluated in the computer. If there is a leak, the pressure drops relatively quickly.

In this way, the tightness, in particular of the critical line area to the halogen gas source 4, can also be monitored. To do this, the main valve of the halogen gas bottle is closed manually. The valve V4 is then opened and then the entire system is pressurized with inert gas and the pressure drop is then observed.

Claims (7)

1. Excimer laser with a gas supply device ( 12 ) for filling a laser tube ( 10 ) arranged in a housing ( 11 ) of the laser with halogen gas and other gases from pressurized gas sources ( 1 , 2 , 3 , 4 ) via lines (L1, L2 , L3, L4) which can be connected to the laser tube ( 10 ), characterized in that at least the line (L4) of a halogen gas source ( 4 ) and at least one line (L1, L2, L3) of a non-halogen gas source ( 1 , 2 , 3 ) in the gas supply device ( 12 ), which is arranged remote from the housing ( 11 ) of the laser, via Ven tile (V1, V2, V3, V4) open into a common line (L5) leading to the laser tube ( 10 ) leads. 2. Excimer laser according to claim 1, characterized in that the common line leading to the laser tube ( 10 ) (L5) has a shut-off valve (V5), which is arranged in particular in the housing ( 11 ) of the laser. 3. Excimer laser according to one of claims 1 or 2, characterized in that the common, to the laser tube ( 10 ) leading line (L5) is a single line, in which all of the gas sources ( 1 , 2 , 3 , 4 ) outgoing lines (L1, L2, L3, L4) open outside the housing ( 11 ) of the laser. 4. Excimer laser according to one of claims 2 or 3, characterized in that in the halogen gas source ( 4 ) outgoing halogen gas line (L4) an aperture (B) is arranged, the cross section (Q _B ) is small compared to the effective cross section (Q _V5 ) of the valve (V5) in the common line leading to the laser tubes ( 10 ). 5. Excimer laser according to one of the preceding claims, characterized in that the common line leading to the laser tube ( 10 ) (L5) is equipped with a pressure sensor ( 14 ). 6. Excimer laser according to one of the preceding claims, characterized in that a valve control unit ( 13 ) for adjusting the partial pressures of the gases is provided on or in the gas supply device ( 12 ). 7. A method for filling the laser tube of an excimer laser according to one of the preceding claims, characterized in that first the laser tubes ( 10 ) via the common line (L5) with halogen gas at a pressure lower than atmospheric pressure and then filled with noble gas.