DE19519725C2 - Device for welding and / or treating workpieces using laser light in water - Google Patents

Description

The invention relates to a device for welding and / or treatment of workpieces by means of laser light in the Water, including one for the welding process before Laser location to be welded in the water step device (laser head) and one with this connectable nozzle device which has several openings for Leakage of gas in the space between the nozzle device and has workpiece.

For certain applications, welding is by means of Laser light is a most welcome method to certain Disadvantages of conventional electrical or autogenous Eliminate gas welding processes. So far it has not been possible in wet surroundings, d. H. in the water, the sweat practice using laser light. In general, that the medium water that from a laser beam laser light emerging very strongly  dampens so that high laser energies are provided would have to, if one directly by means of the laser light in Would want to weld water. Such difficulty associated with a decrease in sweat quality lity, would increase the higher the ambient pressure of water, d. H. with increasing depth in the water. A major cause of the poor sweat quality Liability by means of laser light in the water lies in the leg flow of evaporating water and dissociation components of the water on the weld. Such disadvantages are, for example, for users laser welding in underwater area of offshore plants as well as in reactor construction or other highly security-relevant underwater completely unacceptable, so far so far Advantages of using laser light welding in gaseous environment such as air for which Application in the water area had to be dispensed with.

A device of a similar type, as mentioned at the beginning, is known (JP 7-1171 A). The known device has an interior that is closed by a double ring-shaped and each formed in one piece Body is limited, in whose annulus from a Set up a liquid above the water level Medium that is pressurized and obvious Water is, through another nozzle device in the annular space that the main interior there ring-shaped, is introduced. The two one-piece, closed rings end in pointed ends aligned with each other encircling rings and thus form an annular umlau fende outlet nozzle from which the device coming water in a circular shape in the form of a "water curtain "is ejected, i.e. it finds one  Emptying the actual cavity through which the Laser light falls on the welded part to be processed, by supplying a gaseous medium from the Set up instead and in addition a ring-shaped circulating curtain from a liquid medium such as obviously water that is fed from the facility is formed around the gaseous space.

The tapered legs of the double annular body have no attachment to that Workpiece itself. The known device works thus "contactless" with the welded part to be machined.

In view of the fact that the manageability of the known Device will be extremely difficult to offer it for many cases of laser welding light under water no relief or none worth emulating solution.

It is therefore an object of the present invention to To create device of the type mentioned with the welding and / or treatment of workpieces by means of Laser light in water is possible and all so far advantages compared to laser light welding other conventional welding processes be, so that the device also for the highly safety-relevant underwater structure area can be used, the Manageability of the device compared to welding only insignificantly by means of laser light in a gaseous environment Lich should be difficult and the device simple and should be inexpensive to provide.

The object is achieved according to the invention in that the laser beam exit device from the essentially  disc-shaped nozzle device is limited, wherein the nozzle device has a circumferential elastic seal for pressing against the workpiece and the seal made of several frustoconically structured Ring elements exist.

The advantage of the solution according to the invention is essential in that thereby also in the water unimpeded guidance of the laser beam to the actual welding spot or a treatment site on the Workpiece is possible because the water comes out of the room that is under higher pressure than the surrounding water is displaced and thus the laser light from the water undamped to the predetermined position on the workpiece can reach. Due to the higher pressure of the in the room introduced gas versus the pressure of the in the room initially located water, the ambient pressure in the Equivalent to water, the water can be between elastic Gasket and the workpiece are removed from the room whereby by suitably chosen pressure of the seal the workpiece is connected to the nozzle device which laser exit device can be reached that the surrounding water does not flow back into the room can.

To a maximum of elasticity or flexibility of the To achieve seal and also to look good too To be able to adapt non-flat workpieces Seal also from a plurality of truncated cone surfaces Chen-shaped structured ring elements, which are essentially They lie tightly together, but they are, each for yourself, unhindered by the adjacent ring element can deform, but still each other tend to be close together, which is also very beneficial is.  

But it is also advantageously possible, in addition continuously continue to lead gas into the room the water flows back into the room from the outside avoid.

The gas can advantageously be an inert gas or generally a protective gas that is at least one after partial chemical reaction with the metal material not received during the execution of the welding process.

As the working depth in the water increases with the device according to the invention comes the continuous Tightness of space increasingly important to others on the other hand, it must also be in this great water depth be made sure that the gas removes the water from the Can displace cavity and thus a drain or The possibility of an outflow must be created without the Pressure range of the elastic seal on the workpiece is affected by it or only partially is interrupted. For this purpose, it is advantageous that the ring elements with a plurality essentially notches running at right angles to the base of the cone are provided, the individual layers of ring elements twisted with respect to the incisions are arranged so that from the room to the water in Cross section of the ring elements seen ring-like drain or discharge channel is created.

The outermost ring element advantageously has a lower one compared to the other ring elements Elasticity so that the outer ring element quasi a support ring that also has no incisions in advance needs to show, form and  which may also be a smaller width than the rest Ring elements need to have, for example  Half the width. With this outer ring element can thus advantageously an excessive bending of the four ring elements when pressing the entire seal to the workpiece can be prevented.

The openings are advantageously via a gas supply guide channel and are connected via the disk-shaped surface of the nozzle device ver divides, so that preferably as uniform as possible Displacing the water from the room in the course of the on rate of the device can be achieved.

In principle, it is possible in the main disk-shaped nozzle device the hole for the passage of the laser beam at any suitable place and with any shape, for example rectangular, square or round, each depending on the laser beam or the majority separate laser beam passing through the hole to step through.

Advantageously, the nozzle device is an essential central hole for the passage of the laser have light, then through this hole Beams of laser light or several in parallel pass through each other arranged beams can, for example, also with the workpiece to be able to treat the laser light, for example for targeted thermal post-treatment or post-processing seal thermally applied wear protection or the like.

The nozzle device advantageously consists of Metal or a metal alloy and points over it advantageously also fastening devices or  Elements on to about this using the actual laser exit device (laser head) are detachably connected to be able to.

The ring elements themselves preferably consist of any suitable elastomeric materials, at for example rubber.

The invention will now be described with reference to the following schematic drawings using an off management example described in detail. In this demonstrate:

Fig. 1 in section, a laser emitting means and associated nozzle means in a pressed against an in-water workpiece via an elastic sealing position,

Fig. 2 in perspective and in section, the nozzle device with a plurality of frustoconical surface-shaped ring elements and arranged in the edge region of the nozzle device

Fig. 3 in perspective with partial omission of certain sections of ring elements, the elastic seal in the form of a plurality of frustoconically structured ring elements.

The device 10 consists essentially of a laser beam exit device (laser head) 12 , see FIG. 1, and a substantially disk-shaped nozzle device 13 connected therewith via screw connections not shown here. The laser beam exit device 12 is of a conventional, generally known type and is therefore not described in further detail here, which also applies to the laser generating device, which is not shown here at all.

The nozzle device 13 has a substantially frustoconically structured shape, see also FIG. 3, which forms the actual elastic seal 15 . The elastic seal 15 formed from the individual frustoconically structured ring elements 20 is fastened via a substantially annular peripheral edge 14 of the nozzle device 13 by means of suitable fastening means, for example by screw means or by adhesive. The individual ring elements 20 , compare in particular also Fig. 2, are provided with a plurality of substantially at right angles to the cone base 21 and from the cone base 21 extending cuts 22 which have approximately half the width of the ring elements as a cutting depth. The outermost ring element 20 , see FIG. 3, is only half as wide as the other inner ring elements 20 and has no incisions. The outer ring member 20 has a lower elasticity than the inner ring member 20 and thus acts as an outer support layer. Thus, the outer ring member 20 can prevent excessive bending of the other ring members 20 , here in the example four incised ring members 20 . The individual ring elements 20 provided with incisions 22 are rotated with respect to their incisions 22 , so that a quasi-labyrinthine structure is created through which a gas 18 can pass through openings 17 into the space 19 between the nozzle device 13 and the workpiece 16 , The water 11 in the space surrounding the device 10 and the workpiece, which in this example is filled with water 11 , can displace. This will be discussed in more detail below.

As mentioned, the disk-shaped nozzle device 13 has a plurality of openings 17 which are distributed over the surface 24 of the nozzle device 13 . All the openings 17 are connected to each other with a substantially inside the nozzle device 13 duri fenden gas supply duct 23, wherein the gas supply duct not geson 23 via here changed terminal center shown from the outside with a gas 18 supplied can be, that then via the gas supply channel 23 through the individual Openings 17 can get into the space 19 in order to convey the water 11 located there via the labyrinthine incisions 22 into the water surrounding the device 10 and the workpiece 16 as a whole.

If the space 19 is then completely free of water 11 , the laser beam (not shown here) or the plurality of laser beams which are not shown here can be guided out of the hole 25 on the workpiece 16 without attenuation and the laser welding process or the thermal process can be performed Aftertreatment or densification thermally brought up wear protection layers are carried out on the surface of the workpiece 16 , and that completely unaffected by water 11 , but still in an external water environment, which was previously not possible for laser welding or surface treatment by means of laser light.

To focus the laser light or the laser beam bundle, the distance between the nozzle device 13 and the surface of the workpiece 16 by a device, not shown here, which is designed in the manner of a planetary gear and cooperates with the Düsenein device 13 accordingly, controlled and controlled from the outside , if necessary remote controlled.

In this context, the gas 18 which also acts as a protective gas should be a non-reactive gas, for example inert gas. The pressure of the gas 19 is of course controlled as a function of the water depth in which the device 10 according to the invention is operated, by means not shown here, so that a constant slight overpressure in the space 19 compared to that of the water 11 surrounding the device 10 is continuously achieved.

It should be noted that under the context of This application also uses the term welding Surface treatment and / or thermal treatment of Workpieces should be understood and vice versa.

Reference list

10 device
11 water
12 laser beam exit device (laser head)
13 nozzle device
14 edge
15 seal
16 workpiece
17 opening
18 gas
19 room
20 ring element
21 cone base
22 incision
23 gas supply duct
24 surface (nozzle device)
25 holes

Claims (8)

1.Device for welding and / or treating workpieces by means of laser light in water, comprising a laser beam outlet device (laser head) to be positioned for the welding process in front of the welding site and a nozzle device which can be connected to this and which has several openings for the escape of gas into the having space between nozzle means and the workpiece, characterized in that the Laserstrahlaustrittseinrich processing is limited (12) from the substantially disc-like nozzle means (13), wherein the nozzle means (13) has a peripheral elastic seal (15) for pressing against the workpiece (16 ) and the seal ( 15 ) consists of several ring elements ( 20 ) structured in the shape of a truncated cone surface. 2. Device according to claim 1, characterized in that the ring elements ( 20 ) with a plurality of substantially perpendicular to the cone base ( 21 ) extending cuts ( 22 ) are provided, the individual layers of ring elements ( 20 ) with respect to the incisions ( 22 ) are arranged offset from one another. 3. Device according to claim 2, characterized in that the outermost ring element (20) against the other ring members (20) having a lower elasticity. 4. Device according to one of claims 1 to 3, characterized in that the openings ( 17 ) via a gas supply channel ( 23 ) are interconnected and on the disk-shaped surface ( 24 ) of the nozzle device ( 13 ) are distributed. 5. Device according to one of claims 1 to 4, characterized in that the nozzle device ( 13 ) has a substantially central hole ( 25 ) for passage of the laser light. 6. Device according to one of claims 1 to 5, characterized in that the nozzle device ( 13 ) consists of metal or a metal alloy. 7. Device according to one of claims 1 to 6, characterized in that the ring elements ( 20 ) consist of an elastomeric material. 8. The device according to claim 7, characterized in that that the elastomeric material is rubber.