DE102005052431B4 - Machining robot for laser machining of workpieces - Google Patents

Abstract

processing robot (1) for laser machining workpieces, wherein a laser beam a stationary laser outside of the robot is arranged over Mirror means substantially along a longitudinal axis (2) of a hinged, essentially elongated and rigid coupling means (3) in an inlet (4) in a middle Robot axis (5) is to be guided, wherein a central coupling piece (14) of the coupling means (3) variable in length, in particular telescopically formed and the processing laser (16) is a CO2 laser and has a laser power between about 300 W and about 600 W or a power between about 600 W. and has about 8 kW.

Description

The The invention relates to a processing robot for laser processing of workpieces.

EP 0 237 987 B1 shows a laser robot, wherein a stationary laser source emits a laser beam, which is introduced into the likewise rigid base of the robot.

DE 690 12 307 T2 shows an apparatus for welding motor vehicle bodies with a laser beam, but a costly conduction of the laser beam on the entire outside of the robot via mirrors to the robot hand takes place.

Known are robots with beam guidance via fiber optic cable, For example, with a disc laser or NDYAG laser whose Laser radiation is guided by means of the optical fiber cable to the robot head. Here, however, there are strong restrictions on the Workpiece accessibility as well as the load of the optical fiber. In addition, only low movement speeds can be realized become.

task Therefore, it is the object of the present invention to provide a processing robot provide, with the movement of the robot almost unhindered can take place through the introduction of the laser and also a processing of workpieces is possible, which requires a high laser cable.

The Task is solved by a machining robot for laser machining of workpieces Claim 1.

Of the Laser beam is over the mirror means passed along a coupling means, whereby the one the geometric relation of the mirror means for guiding the Laser beam can be determined in advance safely and a simple and stable transmission even of high power laser beams possible is, because due to the conductor freedom no optical fiber cable provided become. The coupling agent is here designed to be substantially rigid and thus forms a mechanical coupling of the movement of the robot with the output of the laser. Furthermore the coupling means is preferably formed as a hollow conduit. In this way, the laser beam is guided within the coupling means and is thus in an all - round protection, so that the Laser beam can not escape. The coupling agent thus has a Dopplfunktion as mechanical coupling and as protection. Preferably the coupling means has an articulated flange, wherein balancing joint means are used, so that more complex fast rotational movements and / or, for example, a tilting be performed can. The entrance of the laser beam through the coupling means is located at the central processing robot axis, whereby only a very small movement of the robot to the Coupling agent is passed.

The Length of the Coupling agent can easily connect to the spatial Conditions are adapted, for example, if the laser because of its size or its weight, especially in high power lasers, outside a cab is placed around the robot.

With the guided by the processing robot laser beams can for example, welding and cutting components, but also a surface treatment for compensation or cleaning. It is advantageous in particular that transfer high power can be with which also very thick components or hard materials processed can be. At the same time keeps the machining robot its agility and gets one very good component accessibility.

A slight movement of the coupling agent in the entrance area is achieved when the central robot axis is a third or fourth robot axis. In this area leads The robot only makes very small movements, as the main movement in the essential to the front robot axes, which focuses on hand axes.

Advantageous it is when the central robot axis is a forearm axis of a Articulated robot is.

ever according to geometric conditions, in particular the location of the laser and / or the workpiece assembly is advantageously provided that the entrance of the coupling means on the top, on a flank side or on the back the central processing robot axis is arranged so that the Coupling means by the movement of the robot arm only a small Movement experiences. A particularly advantageous embodiment occurs when the entrance to the back of the central robot axis because there is almost no movement compared to the hand movements of the robot takes place.

Advantageous it is when the entrance of the coupling agent is close to the beginning the robot axis is arranged, in particular in the third axis, in the elbow area of an articulated robot.

Lasers with very high powers can also be coupled by means of the processing robot and the radiation can be guided to the exit in the robot hand after entering the robot arm, if the beam feedthrough cross section in the robot Robot axis after entry is up to about 50 to about 60 mm.

A simple and well reproducible positioning in particular of the Mirror agent is possible when the axial end of the coupling means to a beam adjustment bank is mounted within the processing robot axis.

One low adjustment effort falls at, with at the same time very high accuracy if after the entrance of the Laser beam to the exit from the outlet nozzle in the robot head two mirrors are provided for redirecting the laser beam.

A simple and mechanically stable coupling of the coupling agent is also in case of tilting movements or wide rotary movements of the robot given when a central coupling piece of the coupling means is variable in length, is designed in particular telescopic.

One reliable protection against leakage of the laser beam is present if the central coupling piece is designed as a tube.

A good mobility of the coupling agent is present when the coupling agent Having at the ends for connection to the laser or the robot axis spacers.

Advantageous it is when at the laser-side end of the coupling means a Mirror / a pair of mirrors and at the axis-side end of the coupling means a mirror / mirror pair is provided. This is the mirror easily accessible and easy to adjust. A particularly advantageous embodiment due to a low number of mirrors and at the same time great adjustment accuracy occurs when a total of one coupling agent from a laser four mirrors go out, leaving it at the back in the middle robot axis enters and the laser beam then two more mirrors to the exhaust nozzle is diverted.

Advantageous it is when joints, especially hinges between the central coupling piece and the spacers are attached. As a result, the essential to the movement of the robot necessary rotational degrees of freedom allows and at the same time remains the relation of the mirrors to each other so obtained that the laser beam is almost centrally by the coupling means forward.

A Adaptation of the coupling means to the inlet and / or the laser output is flexible, if a spacer with the outer mirror is rotatable about a respective transverse axis.

A simple and sure repeatable device of the laser path is given when a mirror on the axis-side end of the coupling means means the jet stage stage is to be adjusted. At the laser-side output For example, can advantageously be an adjustment of the laser over a Adjustment bank be provided.

A Long life of the mirrors even with very high laser cables is secured if a mirror cooling by means of water and / or Air is provided.

low Cable routes are necessary if the mirror / mirror pair on laser-side end of the coupling means starting from the processing laser to cool is. In addition, this can be used by the strong cooling of the laser so that the mirror is always sufficiently cooled.

low Routing paths are also necessary if the pair of mirrors at the axis end of the coupling means is to be cooled starting from the robot axis.

A size Bandwidth of laser powers may be for use with that described Machining robot can be used. Prerequisite is essentially an adjustment of the mirror selection and mirror cooling to the selected laser power. Advantageous is a use of low to high power lasers, wherein the processing laser has a laser power between about 300 W and about 600 W or a power between about 600 W. and has about 8 kW. For a laser with a power between 300 W and 600 W can then a small robot can be used.

Quality editing options of the workpiece occur when the processing laser is a CO2 laser. preferred Weis The laser has a power of 600 W to 8 kW.

Advantageous the invention is particularly when the laser as a stationary laser, especially outside of the robot is arranged. By means of the coupling agent of the Laser beam even with very heavy and large high-power lasers easy way to the processing robot and then to his Be guided robot hand.

A safe and simple attachment of very large and heavy high-power laser is possible when the processing laser is mounted on and / or on a bodywork mounted around the processing robot, the coupling means is passed in particular through the body wall cabinets. In this case, in particular an all-round shielding of the laser beam path by a tubular coupling means made of laser-impermeable material is advantageous in order to obtain an output to prevent the laser beam from entering.

Especially if a body cabin with a laser in the upper area provided is, it is advantageous to minimize the conduction paths when the Laser is provided on the top of the bodywork cabin.

A Machining even very complex structures of the workpiece by means of especially a high power laser is possible if in the head area the machining robot, a scanner, especially high-performance scanner is used.

Further Features and advantages of the invention will be apparent from the claims and the description below, in the embodiments of the subject matter the invention in conjunction with the drawings are explained in more detail.

It demonstrate:

1a an assembly cabin with a processing robot,

1b a view of the bodywork 1a .

2 a coupling agent in perspective view,

3 a coupling means in perspective view and

4 a coupling piece of a coupling agent.

1a shows a body cabin 24 with a processing robot 1 and 1b shows a top view 25 the bodywork cabin 24 out 1a , The machining robot 1 has five robot axes, where on a central robot axis, in this case on a third robot axis 5 on a backside 8th a coupling agent 3 a connection to a processing laser 16 that is on the top 25 the bodywork cabin 24 is attached. The entry 4 However, for example, on an upper side 6 or a flank side 7 to be appropriate.

The coupling agent 3 is how in 2 shown in more detail, constructed substantially rigidly, has, as in 4 illustrated, telescopic, central coupling piece 14 along a longitudinal axis 2 , as in 2 shown on, which is tubular in this case and further at this one achsseitigen end 11 and a laser-side end 13 attached spacers 15 , Between the central coupling piece 14 and the spacers 15 are swivels 21 attached so that a very good mobility of the coupling agent 3 given is. The rotation of the spacers can by means of the hinges to the longitudinal axis 2 transversely formed transverse axes 22 respectively.

Inside the coupling agent 3 are four mirrors 17 . 18 . 19 . 20 for the beam guidance within the coupling means 3 intended. Two further, not shown mirrors are for the path of the laser beam to the exit from the robot head 10 at the outlet nozzle 12 needed. As a result, a fast movement of the robot and large reorientations can be achieved safely and easily. Furthermore, good workpiece accessibility is ensured. The cooling of the mirror is from an axle-side end 11 and from a laser-side end 13 very easy. The adjustment takes place in the case of the axle-side end 11 over the robot housing. The axis-near joint is on an interior of the robot axis 5 established radiation bank built. High laser powers are therefore no problem. The weight load of the robot is very low.

The entry 4 for the laser radiation is at the back 8th the robot axis 5 set up. The robot axis 5 subsequent axes can be made with a larger free inner cross-section, so that beam passages of laser beams with a cross section of up to about 50 and 60 mm can be realized. It is advantageous that the mirror by means of a mirror cooling 23 can also be cooled by water and air. In particular, it is very easy to use the two mirrors 17 . 18 at a laser-side end 13 near a processing laser 16 from the laser-side end 13 to cool off and the two near-axis mirror 19 . 20 from the axle end 11 at the robot axis 5 , The other mirrors in the area of the robot head 10 are cooled by the robot. In this case, in particular two mirrors in the / the axis / n 9 intended.

The coupling agent 3 is with two swivel joints 21 , which are not driven, and with a telescopic guide in the region of the central coupling piece 14 executed. In this way, the / can the entrance 4 subsequent head axes can be freely moved without restriction. The movements of the robot can be performed at high speeds. Since no laser cables or other components are used in the area of the robot head, a good workpiece accessibility is given. The entry 4 of the coupling agent 3 in the area of the robot axis 5 , at which the beam coupling takes place, moves very little, since this is located at a low-motion point at the transition from the second robot axis to the third robot axis. Even with major reorientations of the head axis or the interception of large components, this point moves relatively little relative to it. The processing laser 16 can be so on top 25 the bodywork cabin 24 be set up, is fixed and does not have to be moved.

3 shows a coupling agent 3 in perspective view. In this case, almost no central coupling means is shown, but it outweigh the spacers 15 with the mirrors. This embodiment is advantageous when the laser is mounted very close to the robot, so that no long distances must be bridged.

4 shows a central coupling piece 14 a coupling agent 3 , wherein the telescoping is represented by telescoping pipe sections.

1

processing robot

2

longitudinal axis

3

coupling agent

4

entry

5

robot axis

6

top

7

flank side

8th

back

9

axis

10

robot head

11

axle-side The End

12

exhaust nozzle

13

laser-sided The End

14

central coupling piece

15

spacers

16

laser processing

17

mirror

18

mirror

19

mirror

20

mirror

21

swivel

22

transverse axis

23

mirror cooling

24

construction cabin

25

top

Claims (22)

Machining robot ( 1 ) for laser machining of workpieces, wherein a laser beam of a stationary laser, which is arranged outside the robot, via mirror means substantially along a longitudinal axis ( 2 ) of a hinged, substantially elongated and rigid coupling means ( 3 ) into an entrance ( 4 ) into a central robot axis ( 5 ), wherein a central coupling piece ( 14 ) of the coupling agent ( 3 ) variable in length, in particular telescopic and the processing laser ( 16 ) is a CO2 laser and has a laser power between about 300 W and about 600 W, or has a power between about 600 W and about 8 kW. Machining robot according to claim 1, characterized in that the central robot axis ( 5 ) is a third or fourth robot axis. Machining robot according to claim 1 or 2, characterized in that the central robot axis ( 5 ) is a forearm axis of an articulated robot. Machining robot according to one of claims 1 to 3, characterized in that the entry ( 4 ) of the coupling agent ( 3 ) on the top ( 6 ), on one flank side ( 7 ) or on the back ( 8th ) of the central robot axis ( 5 ) is arranged so that the coupling agent ( 3 ) experiences only a slight movement by the movement of the robot arm. Machining robot according to one of claims 1 to 4, characterized in that the entry ( 4 ) of the coupling agent ( 3 ) near the beginning of the robot axis ( 5 ) is arranged, in particular in the elbow region of a articulated robot. Machining robot according to one of claims 1 to 5, characterized in that the laser beam after the entrance ( 4 ) into the robot axis ( 5 ) by mirroring through subsequent axes ( 9 ) to a robot head ( 10 ). Machining robot according to one of claims 1 to 6, characterized in that the beam feedthrough cross section in the robot axis ( 5 ) after entry ( 4 ) is up to about 50 to about 60 mm. Machining robot according to one of claims 1 to 7, characterized in that the axial end ( 11 ) of the coupling agent ( 3 ) to a beam adjustment bench within the processing robot axis ( 5 ) is attached. Machining robot according to one of claims 6 to 8, characterized in that after entry ( 4 ) of the laser beam until it leaves the outlet nozzle ( 12 ) are provided in the robot head two mirrors for redirecting the laser beam. Processing robot according to one of claims 1 to 9, characterized in that the central coupling piece ( 14 ) is designed as a tube. Machining robot according to one of claims 1 to 10, characterized in that the coupling means ( 3 ) on both sides at an axle-side end ( 11 ) at the entrance ( 4 ) and a laser-side end ( 13 ) is articulated. Machining robot according to one of claims 1 to 11, characterized in that coupling means ( 3 ) at the ends for connection to the laser or the robot axis spacers ( 15 ) having. Machining robot according to one of claims 1 to 12, characterized in that at the laser-side end ( 13 ) of the coupling agent ( 3 ) a mirror / mirror pair ( 17 . 18 ) and at the axle-side end ( 11 ) of the coupling agent ( 3 ) a mirror / mirror pair ( 19 . 20 ) is provided. Machining robot according to one of claims 12 to 13, characterized in that joints, in particular swivel joints ( 21 ) between the central coupling piece ( 13 ) and the spacers ( 15 ) are attached, Machining robot according to one of claims 12 to 14, characterized in that a spacer ( 15 ) with the outer mirror about a respective transverse axis ( 22 ) is rotatable. Machining robot according to one of claims 8 to 15, characterized in that a mirror at the axis end ( 11 ) of the coupling agent ( 3 ) is to be adjusted by means of the beam adjustment bank. Processing robot according to one of claims 1 to 16, characterized in that a mirror cooling ( 23 ) is provided by means of water and / or air. Machining robot according to one of claims 13 to 17, characterized in that the pair of mirrors ( 17 . 18 ) at the laser-side end ( 13 ) of the coupling agent ( 3 ) starting from the processing laser ( 16 ) is to cool. Machining robot according to one of claims 13 to 18, characterized in that the pair of mirrors ( 19 . 20 ) at the axle-side end ( 11 ) of the coupling agent ( 3 ) starting from the robot axis ( 5 ) is to cool. Machining robot according to one of claims 1 to 19, characterized in that the processing laser ( 16 ) and / or on a bodywork ( 24 ) attached to the processing robot ( 1 ), the coupling agent ( 3 ) is passed in particular through the body wall cabinets. Machining robot according to claim 20, characterized in that the processing laser ( 16 ) on the top ( 25 ) of the body ( 24 ) is provided. Processing robot according to one of claims 1 to 21, characterized in that in the head region of the processing robot ( 16 ) a scanner, in particular high performance scanner is used.