DE3427424A1 - GAS LASER SYSTEM - Google Patents

Description

The present invention relates to a device for generating a laser beam using a gaseous one Laser medium and in particular an improvement of the deflecting mirror arranged in this device.

In an apparatus for generating a laser beam using a gaseous active, i.e. laser beam emitting medium (hereinafter referred to as "gas laser") is in an active area (laser area), which is a Gas mixture (e.g. a helium-nitrogen-carbon dioxide mixture) contains, caused a glow discharge to excite the gas mixture and thereby generate laser light. The laser light comes into resonance with an optical cavity created by a plurality of provided in the laser area Mirroring is formed, and is then led out of the cavity through an output mirror. The emerging laser beam can be used for work such as cutting and welding an iron plate or the like be used. In cutting or welding work of this type, the aim is to maintain the cutting or welding width to make it as small as possible, since such a precise processing can take place and the laser processing with it for different Processing objects is applicable. A small processing width is possible through the use of a To achieve laser beam, which has a so-called one-mode characteristic. With the one-mode characteristic the energy density in the central area of the laser beam spot is considerably greater than the energy density in the peripheral areas. In order to achieve this one-mode characteristic, a large spacing of the mirrors is the optical Required cavity for the laser light. For this purpose, a pair of opposing deflection mirrors is provided, between which the laser area lies in order to

Serlicht pass through the excited laser area several times allow. In such a structure, however, the width of each deflecting mirror becomes large / and it is necessary to to make the laser area wide. This also results in large dimensions of the gas laser system.

The general object of the present invention is to be seen in / to specify a gas laser system with which the The disadvantages inherent in the prior art are at least partially overcome. A more specific task is To create a gas laser system, the width of which is smaller than that of the conventional systems.

According to the invention, a gas laser system is used to achieve these objects indicated, in which each deflecting mirror has a free space through which a laser beam between an output mirror and a rear mirror can pass through, whereby the optical path runs through these free spaces, thereby reducing the width of the laser.

Preferred embodiments of the invention are described in detail with reference to the accompanying drawings. In the drawings show:

2o 'Fig. 1 is a perspective schematic view of an Aus. management form of a gas laser system according to the invention

with transverse gas flow;
Fig. 2 is a schematic representation to illustrate the

embodiment shown in Fig. 1; Fig. 3 is a sectional view for explaining the structure of the optical cavity shown in Figs. 1 and 2;

Figure 4A

and FIG. 4B are cross and longitudinal sections of the structures shown in FIGS. 1, 2 and 3, respectively

deflection mirror shown; and

Figure 5A

and FIG. 5B shows transverse and longitudinal sections of the deflecting mirrors according to one

another embodiment of the gas laser system according to the invention.

In the following with reference to FIGS. 1, 2 and an embodiment of the gas laser according to the invention with transverse gas flow is shown.

As shown in Figs. 1, 2 and 3, the gas laser is with a hermetically sealed steel container 1, the interior of which is mainly of a circulation channel 2 and an optical cavity 3 is formed.

The circulation duct 2 is equipped with a fan motor 5, which is a gas mixture 4 in a direction indicated by an arrow (i.e. in a direction A), as well as with a heat exchanger 6 provided. Both ends of the channel 2 are connected to side surfaces of the cavity area 3.

In the upper and lower part of the cavity area 3, a cathode 8 and an anode 7 are arranged via a bellows 11 are holding plates 12 and 13 on the right and left, respectively Wall of the cavity area 3 attached. Also, an exit mirror 15 and a rear mirror 16 are above a bellows 14 connected to the outer surfaces of the retaining plates 12 and 13, respectively. First and second deflection mirrors 17 and 18 are via a fastening element 19 so attached to the inner surfaces of the holding plates 12 and 13 that they are next to the exit mirror 15 or the rear mirror 16 are. The first and second deflection mirrors 17 and 18 are attached to the Fasteners 19 attached so that their reflective surfaces have an incline and face each other. The structure of the deflecting mirrors 17 and 18 is shown in FIGS. 4A and 4B. As the two mirrors essentially are designed identically, only the first deflection mirror 17 is shown in FIGS. 4A and 4B, while on the description of the second deflection mirror 18 is dispensed with.

As shown in Figures 4A and 4B, the fastener 19 supports one end of a mounting plate 20. The first deflection mirror 17 is arranged between this mounting plate 20 and a clamping element 22, with between the deflection mirror 17 and the mounting plate 20, a sealing ring 21 is provided. In the clamping element 22 and the mounting plate 20, a through screw 23 is inserted and tightened so that the first deflection mirror 17 between the Bracket plate 20 and the clamping member 22 is held.

The heat generated at the first deflection mirror 17 can be dissipated by water, which in the direction of the arrow by a provided in the clamping element 22 coolant channel 24 flows. The first deflection mirror 17 has a recess on. This recess 25 is in the areas of the first deflection mirror 17, the mounting plate 20 and the clamping element 22 are provided which adjoin the beam path 30A which runs through the output mirror 15.

When a DC voltage is applied between the anode 7 and the cathode 8, a voltage occurs between these electrodes Glow discharge on, and the gas mixture 4 is excited. An excited laser region 31 is thus formed, and it becomes Laser light 30 is generated. The laser light 30 comes with one of the output mirror 15, the first deflection mirror 17, the second deflection mirror 18 and the rear mirror 16 formed optical cavity in resonance, whereby in this cavity, as shown in Fig. 3, five optical paths 30A to 3OE arise. The optical path 30A runs, as shown in FIGS. 4A and 4B, through the recess 25. Furthermore is the recess 25 in the first deflection mirror 17, the mounting plate 20 and the clamping element 22 in the immediate vicinity Proximity of the optical paths 30B and 3OC which are adjacent to the optical path 30A are provided. This allows the distance between the optical path 30A and the optical path 30B (or 30C) can be made small. The output mirror 15 can be in others

Words can be arranged immediately next to the optical paths 3OB and 3OC. Similarly, the distance between the optical path 3OE and the optical path 3OC (or 30D) can be kept small by adding another recess 25 is provided in the second deflection mirror 18 and the associated components. This allows the distance L between the optical paths 30A and 30E can be decreased by an amount equal to the displacement of the optical paths 30A and 3OE in the direction of the central optical path corresponds to 3OC. Accordingly, the optical paths can be 30A to 30E be arranged in a narrow laser area, whereby the embodiment shown in Figs. 1 to 3 without Reducing the light output can be made with small dimensions.

The one in each of the deflecting mirrors 17 and 18, the mounting plates 20 and the clamping elements 22 provided recess 25 is always on the side of the exit mirror or the rear Arranged mirror and can thus serve as a positioning mark. This will carry out the positioning facilitated, and the time required for assembling the cavity portion can be shortened.

FIGS. 5A and 5B show the first deflecting mirror as it is in another embodiment of a gas laser system according to The present invention finds application. According to FIGS. 5A and 5B is in the first deflecting mirror 17 and the mounting plate 20 a through opening 25A is provided at a position next to the optical paths 3OB and 3OC in order to to keep the distance between the optical path 30A and the optical path 30B (or 30C) small. In a similar way is a further through opening 25A in the second deflecting mirror 18 and the mounting plate connected to it provided to the distance between the optical path 3OE

and the optical path 3OC (or 30D). Thus, the distance between the optical paths 30A and 30E can be reduced in size.

In the exemplary embodiments shown above, circular Deflection mirror used. Instead of this circular Deflection mirrors, however, can also be used with square or rectangular deflection mirrors. Furthermore, the present Invention also applicable to another type of transverse gas flow gas laser in that of the three Sizes: Direction of transport of the gas mixture, direction of discharge and the direction of propagation of the laser light are two sizes parallel to each other and perpendicular to the other size. Moreover, the invention is directed to a gas laser of the axial gas flow type in which all of the above directions are parallel to each other, as well as applicable to a closed gas laser in which the gas mixture does not circulate.

As is apparent from the above description, according to the present invention, a gas laser can be made small in size getting produced.

Ah / bi

Claims (6)

STHEHL SGHLTHKL -HOPF SCHULZ 3A27424 WIDKNMAYKRSTKASSK 17, I) HOOO Ml) NCI IKN 22 HITACHI, LTD. DEA-26712 July 25, 1984 Gas laser system e: Gas laser,
marked by one hermetically sealed and containing a gas mixture (4) Container (1), a cathode (7) and an anode (8) which are each provided in the hermetically sealed container (1) and between which a glow discharge is generated in order to excite the gas mixture (4),
an output mirror (15) for leading out the laser light (30) generated by the excited gas mixture (4) and a rear mirror (16) which are provided at opposite ends of the hermetically sealed container (1), and
first and second deflecting mirrors (17, 18) which face each other and are provided in the immediate vicinity of the exit mirror (15) or the rear mirror (16), said mirror being used as a resonator for the generated Laser light (30) are used, and in the first deflecting mirror (17) in an area which corresponds to the output mirror (15), as well as in the second deflecting mirror (18) in an area which corresponds to the rear mirror (16) Free space (25, 25A) is provided for the passage of the laser light (30). 2. Gas laser according to claim 1, characterized in that the free space is a recess (25). 3. Gas laser according to claim 1, characterized in that that the free space is a continuous opening (25A). 4. Gas laser according to one of claims 1 to 3, characterized in that that it is a transverse gas flow system. 5. Gas laser according to one of claims 1 to 3, characterized in that that it is an axial gas flow system. 6. Gas laser according to one of claims 1 to 5, characterized in that that a closed gas laser system is used.