EP2244846A1 - Method and apparatus for the at least partial removal of a coating and surface treatment installation - Google Patents

Abstract

The invention relates to a method and an apparatus for the at least partial removal of a coating from a functional area (34, 50, 51) of a vehicle wheel (18) formed by a recess, a cap seat or a hub ring and relates to a surface treatment installation with an application device for applying a coating to a vehicle wheel (18) and a dryer for hardening the coating applied.  According to the invention, it is provided that the functional area (34, 50, 51) is exposed to a beam produced by a source of radiation (12, 212) until the coating is at least partially transformed into a gas mixture in the region of the functional area (34, 50, 51) as a result of the heating by the beam.  The apparatus according to the invention for the at least partial removal of a coating from a functional area (34, 50, 51) formed by a recess, a cap seat or a hub ring may be integrated in a surface treatment installation.

Description

 Method and device for at least partial removal of a coating and surface treatment plant

The invention relates to a method and a device for at least partially removing a coating from a functional surface of a vehicle wheel formed by a countersink, a cap seat or a hub ring, and to a surface treatment installation for applying and processing coatings on vehicle wheels.

From the prior art it is known vehicle wheels, as they are intended in particular for use on motor vehicles, made of metallic materials such as steel or aluminum

To produce magnesium. Such vehicle wheels are provided with a coating which comprises one or more layers. The coating serves as corrosion protection for the metallic material and possibly to improve the aesthetic effect of the vehicle wheels. Wet coating methods and powder coating methods are usually used as coating methods for the vehicle wheels; these can also be combined with one another.

Recently, coating methods such as CVD

(Vapor Deposition Chemical) or PVD (Physical Vapor Deposition) used for the coating of vehicle wheels before a clear coat.

The vehicle wheel has, for attachment to a hub, in particular a motor vehicle axle, serving functional surfaces. A first group of functional surfaces is formed by subsidence. The countersinks can be conical or dome-shaped in shape and serve for the areal contact of wheel fasteners or parts thereof, eg heads of Wheel bolts or wheel nuts. As a further functional surface, a hub ring may be provided in which, when the vehicle wheel is attached to the hub, a circumferential centering collar provided on the hub side engages in a form-fitting manner to ensure exact centering of the vehicle wheel with respect to the hub. Another functional surface is referred to as a cap seat and serves to receive a cap for covering a central bore on the vehicle wheel. The functional surfaces should, in contrast to the other surface regions of the vehicle wheel, be at least substantially free of coating after the coating of the vehicle wheel has been carried out. As a result, it is achieved, for example, that the mating geometry between the wheel bolt or nut and the vehicle wheel in the region of the countersink can ensure the necessary frictional engagement during operation. In the case of a coating remaining in the region of the reduction, the surface pressure between the wheel bolt and the vehicle wheel changes, in particular as a result of setting processes, so that functional reliability could be impaired.

It is known from the prior art to cover the functional surfaces during the implementation of the coating process or processes provided for coating the entire vehicle wheel, in order to prevent the coating material from hitting and adhering to it. For this purpose, before the implementation of the coating suitable covering means such as balls or plugs are applied to the functional surfaces and removed after performing the coating. This entails a considerable additional outlay, which includes the attachment and removal and, if appropriate, a preparation of the corresponding stoppers. In addition, in the boundary regions between the plugs and the coating adhering to the vehicle wheel, unwanted buildup and breakage of coating materials, which may need to be removed in a finishing step, arise. By means of the covering means, the closer environment of the depression, in particular a recess for receiving When the coating process is carried out, at least some of the wheel attachment means, at the bottom of which the reduction is arranged, are shaded so that, where appropriate, no satisfactory coating is achieved there and quality criteria with regard to optics and corrosion protection are not met.

This shading problem is compounded by the fact that the recess at the bottom of which the counterbore is located and which receives the wheel bolt head or nut often has an insignificantly larger diameter than these wheel fasteners, so that there is just enough space to fit a tool , Depending on the design of the vehicle wheels, the recesses may even be designed as a cylindrical screw hole, which may have a substantially elongated shape and protrude deeply into the vehicle wheel.

From DE 102 49 999 B3 a method for the extraction of functional surfaces on vehicle wheels is known, which are provided with a powder coating. In this method, the paint powder serving for coating is first applied over the entire surface of the vehicle wheels. In a subsequent process step, the functional surfaces are again freed from the loosely adhering powder with the aid of a suitable suction device, before the powder is burnt in an oven. The mode of action of this process is limited to powder coatings. In the case of wet coatings or other coating processes, the coating material adheres significantly more strongly to the vehicle wheels and can not be removed by suction.

The object of the invention is to provide a method, a device and a surface treatment plant which makes it possible to largely treat depressions. layers and a cost-effective and independent from the coating process exemption of functional surfaces on vehicle wheels guaranteed.

To solve the problem relating to the method, a method with the features of claim 1 is provided. In carrying out the method, the functional surface is exposed to a radiation beam generated by a radiation source until the coating in the region of the functional surface at least partially as a result of heating by the

Beam is transferred into a gas mixture. As the radiation source is in particular a laser source in question, which emits high-energy electromagnetic waves, which in turn leads to local heating of the coating when hitting the coating in the region of the functional surface of the vehicle wheel, in particular by radiation absorption. The radiation beam emitted by the radiation source has such a high energy density that the coating can locally be heated so strongly that it evaporates. Surrounding coating areas, which are not exposed to the beam undergo no significant heating, the coating applied there remains unimpaired. In the evaporation process, molecules of the coating are released into the environment and form a gas mixture with the ambient atmosphere, in particular ambient air.

It is advantageous if the functional surface is exposed to the beam of radiation until a metal surface of the vehicle wheel covered by the coating is at least partially exposed in the area of the functional surface. For proper operation of the vehicle wheel, it is not mandatory that the functional surfaces are metallic bright. Rather, it is sufficient if the thickness of the remaining coating is only a few 1/1000 mm, since such thin coatings do not adversely affect the function of the radio impact areas.

In an embodiment of the method, it is provided that the gas mixture formed by the heating is sucked off. On the one hand, an undesired escape of optionally harmful constituents of the detached coating into the environment is avoided by suction, which takes place in particular directly in the area of the functional surface to be processed. On the other hand, precipitation of such coating components in other areas of the vehicle wheel can be effectively prevented, which could otherwise affect the surface quality of the remaining coating.

In one embodiment of the invention, it is provided that the beam has a non-zero divergence, and that the dimensions of a beam spot arising when the beam strikes the vehicle wheel are determined by changing the relative arrangement of the vehicle wheel and the beam. Usual radiation sources like

Laser light sources emit bundles of rays whose marginal rays are at an acute angle to each other and thus have a non-zero divergence. Thus, when the beam impinges on the vehicle wheel, a beam spot with a preferably circular extent results, which, for a given divergence, depends in particular on the distance between the light source and the vehicle wheel. In an advantageous development of the method, it is ensured that only the surface areas of the vehicle wheel to be stripped are exposed to the beam while adjacent ones

Areas, in particular the coated recess for receiving the Radbefestigungsmittel remain irradiation-free.

It is advantageous if the functional surface is exposed to the radiation beam after all the coatings have been applied to the driving surface. were applied. The coatings in question are coatings that remain permanently on the surface when the vehicle wheel is used. For reasons of production, storage or presentation, anti-corrosion or high-gloss layers are not included, since these usually do not have any layer thickness relevant for the use of the vehicle wheel. Thus, according to the invention, it is ensured that the functional surface is ready for use and that no additional preparatory actions are necessary when attaching the vehicle wheel to a vehicle, in particular a motor vehicle. Possibly after removal of the coating of the functional surfaces applied to the vehicle wheel protective wax layers are also not intended to remain on the vehicle in use and are also not included.

In an advantageous development of the method, it is provided that the functional surface is exposed to the beam after all coatings have been applied to all surfaces of the vehicle wheel. This can ensure that when applying the coatings no consideration must be taken of the coating freedom of functional surfaces. Rather, a cost-effective coating application can be carried out on all surfaces without costly cover measures. Subsequently, the functional surfaces are selectively stripped.

In a further embodiment of the invention it is provided that the coating comprises a primer and a clearcoat applied to the primer. The primer can be applied both as a spray paint, in particular as a water-soluble paint, as a powder coating or as a CVD coating or PVD coating. The same applies to any further layers which may be provided, in particular one which is responsible for the visual appearance of the vehicle. rads important decorative layer and a layer applied to protect the decorative layer can act. The vehicle wheel is usually provided with a powder-based primer onto which a decorative layer based on water-based paint is applied after the powder coating has been baked. This is then covered with a protective layer of transparent powder coating.

It is advantageous if the vehicle wheel is moved along a predeterminable path, while a part of the functional surface is exposed to the radiation beam. In order to maintain the desired radiation intensity for the beam spot on the surface of the vehicle wheel, it may be necessary to approach the beam to the surface of the vehicle wheel in such a way that the beam spot has a smaller extent than the functional surface to be machined. In this case, the coating is removed by moving the functional surface with the beam spot along a predetermined path. The metallurgy of the vehicle wheel is not changed due to the gentle, partial heating. The energy is absorbed almost completely by the coating to be removed.

In one embodiment of the invention it is provided that the web is predetermined as a function of a contour of the functional surface and the size of the beam spot. Preferably, the web is predetermined such that each surface portion of the functional surface only once has to be swept by the beam to ensure rapid and efficient processing of the vehicle wheel. Since the beam spot can have an inhomogeneous distribution of the radiation intensity, it is provided according to the invention to arrange adjacent tracks in such a way that there is an overlap of the surface areas respectively processed with the beam spot. Thus, also in the possibly processed with less removal capacity edge regions of the web a sufficient exemption of the functional surface achieved.

In one embodiment of the invention can be provided that the vehicle wheel is moved and / or pivoted relative to the spatially stationary beam. Thereby, the supply of the beam from the light source to the surface of the vehicle wheel can be kept simple. Preferably, the radiation beam emitted by the radiation source is directed onto the functional surfaces in the free jet, where appropriate using deflecting means such as deflecting mirrors. Additionally or alternatively, the beam may be at least partially guided in a light guide, in particular in a glass fiber bundle or a fluid light guide. The movement of the beam spot on the surface of the vehicle wheel necessary for processing larger surface areas is effected exclusively by movements of the vehicle wheel in this embodiment of the invention.

In a further embodiment of the method, it is provided that the direction and / or position of the beam is changed relative to the stationary vehicle wheel. This is done before ^¬ preferably by moving a deflection device for Strah ^¬ lenbündel. Additionally or alternatively, the beam may be at least partially guided in a flexible light guide, for example a glass fiber bundle or a fluid light guide, which is deflected and / or displaced according to the trajectory to be traveled on the surface of the vehicle wheel. As a result, highly dynamic relative movements between the beam and the vehicle wheel can be achieved with high precision. This is due to the fact that the mass of the deflection device and / or the flexible light guide is low and can also be caused with low forces necessary for carrying out the required movements accelerations. It is advantageous if a positioning of the radiation source relative to the functional surface to be processed is determined by an image processing device. With an image processing device which comprises at least one camera and a processing unit connected thereto

Body edges of the vehicle are determined to determine the spatial position of the vehicle wheel relative to the radiation source. From the determined position, the travel path necessary for machining the functional surfaces can then be determined in order to move the vehicle wheel into the working range of the

To bring radiation source. The image processing device can preferably determine the position of the vehicle wheel with respect to a rotational symmetry axis, so that no rotational alignment of the vehicle wheel about the axis of rotational symmetry must be carried out before the machining process is carried out. Particularly preferably, the image processing device is set up in such a way that it can differentiate between differently dimensioned vehicle wheels and can retrieve the paths necessary for processing the corresponding functional surfaces from a memory.

In an advantageous embodiment of the invention it is provided that the beam emerges from a sleeve which is retracted into a recess of the vehicle wheel, at the bottom of which is designed as a lowering functional surface is arranged. The sleeve serves to protect the coating of the recess adjoining the layer to be stripped, which is provided for receiving the wheel fastening means. Furthermore, the use of such a sleeve for compliance with safety guidelines is advantageous because of radiation protection reasons

As far as possible, bundles of rays should only bridge short distances as a free jet and the retraction of the sleeve into the recess prevents high-energy radiation from escaping uncontrollably and leading to damage or injury. Basically, the sleeve for this purpose can be arbitrary, for example, as an elliptical tube, a square tube or a polygon tube with a polygonal cross-section, formed. In an advantageous embodiment of the invention, however, hen hen provided that the sleeve has an elongated, hollow cylindrical shape. This allows the sleeve to be inserted deeply into the recesses. The outer diameter of the hollow cylindrical sleeve is adapted to the dimension of the recesses, so that the sleeve can be inserted into the recess, without this touches the wall of the recess.

To solve the object relating to the device, a device is provided for at least partially removing a coating from a functional surface of a vehicle wheel formed by a countersink, a cap seat or a hub ring. According to the invention, the device has a radiation source, with which a radiation beam which can be directed onto the functional surface can be generated, so that the coating in the region of the functional surface can be converted into a gas mixture at least partially as a result of the heating by the radiation beam. In addition, with the aid of an adjusting device, the relative arrangement between the vehicle and the beam can be changed. With such a device, the method according to the invention can preferably be carried out. The radiation source is preferably a laser source which comprises a continuous or pulsed, in particular monochromatic, laser beam having a wavelength or wavelength distribution in the region of the middle infrared, preferably in a range between 350 nm and 2500 nm, particularly preferably between 900 nm and 1500 nm.

In a further embodiment of the invention, a sleeve is provided, in which the beam is guided and which has an outlet opening for the beam. As already mentioned above, the sleeve serves the protection of the side and above the coating to be coated adjacent to the functional surfaces to be coated, in particular on the wall of the recess for receiving the wheel fastening means. It also complies with safety guidelines and prevents high-energy radiation from escaping uncontrollably and resulting in damage or injury. The sleeve is preferably adapted to the divergence of beam, such that the cross-section not limited ^¬ of the beam in order to avoid undesirable attenuation of the radiation intensity. Preferably, a path length for the at least partially guided in the sleeve beam depending on the divergence of the beam is selected such that the end present at the outlet opening of the sleeve beam spot at least almost corresponds to the minimum beam spot to be used for processing the vehicle wheel.

It is advantageous if the sleeve can be moved and / or pivoted by the adjusting device. Since the sleeve only has to have a low weight in order to fulfill its protective function for the beam, it can be moved with low forces and high accelerations, so that a rapid sweeping of the working surfaces to be machined with the beam to the vehicle wheel and thus short cycle time for processing can be achieved.

In a further embodiment of the invention, the vehicle wheel can be moved and / or pivoted by the adjusting device. This is of particular interest if the functional surfaces to be machined on the vehicle wheel have a large extent or are widely spaced apart and an adjustment possibility for the beam is exceeded. In particular, the adjusting device serves in a dual function both the supply and removal of the vehicle wheel as well as the movement of the vehicle wheel during the processing operation. Also combinations of the adjustment of the Beam with the adjustment of the vehicle wheel are possible.

The adjusting device preferably comprises a robot arm which is equipped with at least two arm sections which can be adjusted relative to one another by pivoting drives and which can bring about a movement of the vehicle wheel in at least one travel plane and / or at least one pivot plane.

In a further embodiment of the invention, the

Setting device a traversing table. The traversing table can be set up for translatory and possibly also for rotational movements and picks up the vehicle wheel during processing. Preferably, the traversing table is designed at least as an XY table, which allows movements in a, preferably horizontally oriented, traversing plane. Particularly preferably, the traversing in addition a positioning device for a ^¬ Z-axis that is orthogonal to the position determined by the X and Y-axis traverse plane permits an adjustment. A rotary adjustment of the movement. tables can be provided by a rotary drive, wherein a rotation axis is preferably aligned orthogonal to the XY traverse plane.

In a development of the invention, a suction device is provided for sucking off the gas mixture released during the irradiation. Preferably, the suction device comprises a suction fan, on the suction side of a suction hose is attached. This is led to shortly before the functional surface to be machined and thus allows extraction of the

Gas mixture in the immediate vicinity of the processed functional area. Pressure side, the exhaust fan can device with a filter "be provided to restrain the extracted flue gas Parti ^¬ angle and only filtered particle-free surrounding air express to the outside. Or will the entire corresponds supplied gas mixture of an oxidative, thermal gas cleaning, which is provided in a device comprising the device for removing coatings coating system anyway for exhaust air purification.

In a further embodiment of the invention, an image processing device for determining a positioning of a radiation source with respect to the Funktionsflä ^{¬ surface} to be processed is provided. With the aid of the image processing device can be determined, in which way a movement and / or pivoting movement of the vehicle wheel and / or the radiation source must be made to the exit opening of the sleeve in which the beam is guided, in the correct distance and the correct position to bring to the functional surface to be processed.

According to a further aspect of the invention, a surface treatment system is provided with an application device for applying a coating to a vehicle wheel, a dryer for curing the applied coating and a device for at least partially removing a coating from a functional surface of a vehicle wheel. The application device may comprise one or more coating devices, in which a coating of the vehicle wheel with powder coating and / or wet paint is carried out. At least one of the coating devices is followed by a dryer which enables curing and / or crosslinking of the applied coating by temperature or by radiation, in particular by infrared radiation or ultraviolet radiation. Those areas of the vehicle wheel which are to be coating-free as functional surfaces are processed by means of the device arranged in a machining flow downstream of the application device and the dryer for the at least partial removal of the coating. Hereinafter, embodiments of the invention will be described with reference to the drawings. In this show:

FIG. 1 is a perspective view of a first embodiment of a stripping station;

FIG. 2 shows the stripping station according to FIG. 1 in a side view,

FIG. 3 shows a detailed view from the view according to FIG. 2,

FIG. 4 is a perspective view of a second embodiment of a stripping station with a travel table for handling the vehicle wheel during the stripping process;

Figure 5 is a perspective view of another embodiment of a Entlackungsstation, and

6 shows a side view of the Entlackungsstation according to Figure 5.

The illustrated in Figures 1 to 3 first embodiment of Entlackungsstation 10 includes a Laserstrahlungsguelle 12 which is fixedly mounted on a support frame 14. On the support frame 14 also two cameras 16 of an image processing device are arranged. An industrial robot 20 is used to handle the designed as aluminum wheels 18 and the entire surface provided with a coating vehicle wheels. Furthermore, the Entlackungsstation 10 comprises a suction device 22 for exhaust air extraction, a rail transport system 24 for supplying aluminum wheels 18 and a conveyor belt 26 for the removal of aluminum wheels 18th The laser radiation source 12 provides a non-illustrated radiation beam, which is guided for safety reasons in an angled square tube 28. In the interior of the square tube 28, an unillustrated deflecting mirror is arranged at a kink between a substantially horizontally extending square tube section 28a and a substantially vertically extending square tube section 28b. This deflects the slightly divergent beam from the horizontal in the vertical direction down to the surface of the aluminum wheel 18. To stabilize the square tube 28, an L-shaped holder 30 is mounted on the support frame 14, which supports the end portion of the square tube section 28b.

End side, the square tube 28 is provided with a hollow cylindrical protective sleeve 32, as shown in more detail in Figures 2 and 3. The protective sleeve 32 has an outer diameter which is adapted to the introduced in the aluminum wheels 18 cylindrical screw holes or screw holes, which serve as recesses for receiving screw heads not shown wheel bolts. An inner diameter of the protective sleeve 32 is selected such that it at least substantially corresponds to a largest diameter of the provided in the aluminum wheels 18 dome-shaped screw depressions 34 (also called screw calotte), but is smaller than the cylindrical bore.

The length of the square tube sections 28a, 28b and the protective sleeve 32 and the free inner cross section of the square tube 28 and the inner diameter of the protective sleeve 32 are matched to the divergence of the beam provided by the laser radiation source 12 such that the cross section of the beam at the end of the protective sleeve 32nd in a cross-sectional plane orthogonal to the beam direction substantially corresponds to the inner diameter of the protective sleeve 32. Thereby If the coating of the coating in the respective counterbore 34 can be removed without moving the aluminum wheel 18, the beam spot of the beam covers the entire surface of the counterbore 34.

The protective sleeve 32 is coated on its outer surface with a plastic layer, which offers high strength and good sliding properties, so that 32 damage to the coating in the screw holes can be avoided in a random, undesirable contact between aluminum wheel 18 and sleeve.

The image processing device, which is mounted on the support frame 14 and has two cameras 16 and an unillustrated control unit, makes it possible to detect the spatial position of the aluminum wheel 18, which is movable relative to the laser radiation source 12 by the industrial robot 20, in order to retract or extend the protective sleeve 32 To allow screw holes of the A-luminal wheel 18. The image processing device thus permits a freely selectable angular orientation of the aluminum wheel 18 with respect to the laser radiation source 12 with respect to the rotational symmetry axis 19 of the aluminum wheel 18.

The industrial robot 20 is designed as a four-axis robot and carries on the fourth axis a U-shaped holder 36 to which two downwardly open U-profiles 38 are mounted. These are provided with plastic-coated, movable by a drive not shown holding pins 40 which engage the rim flange of the aluminum wheel 18 and cause its exact positioning tion on the holder 36.

The suction device 22 comprises a suction fan 42, on whose suction side an at least partially flexible suction hose 44 is mounted, which opens into a suction mouthpiece 46. The suction mouthpiece 46 and the attached suction hose 44th are adjustably mounted in the vertical direction at the foot of the support frame 14 by means of an adjusting cylinder 47 to allow easy feeding and removal of the aluminum wheel 18 and still be able to take the smallest possible distance to the site of action of the beam during the Abtragvorgangs.

The suction mouthpiece 46 has a conical section-shaped inlet region 48, which is arranged centrally below the aluminum wheel 18 to be machined. The suction nozzle 46 is provided on its inner surfaces with a high-temperature resistant absorption coating, which serves to absorb not incident on the aluminum wheel 18 radiation of the beam and thus uncontrolled reflections of this radiation, in particular on rear surfaces of the aluminum wheel 18 to prevent. On the pressure side of the suction fan 42, a filter device 50 is mounted, which filters the particles released during the machining process by the beam of the laser radiation source 12 from the suctioned by means of the suction nozzle 46 and the suction hose 44 ambient air and thus prevents uncontrolled escape of these particles into the environment. In one embodiment of the invention, not shown, the exhaust air sucked in by the suction fan 42 is subjected to a thermal after-treatment of the exhaust gas, in particular an afterburning, so that the filter device 50 can be dispensed with if necessary.

In the following description of preferred exemplary embodiments, the same reference numerals are used for functionally identical components, functionally similar components are provided with reference numerals increased by 100 or 200.

The stripping station 110 according to FIG. 4 differs from the stripping station 10 according to FIGS. 1 to 3 by another form of feeding the aluminum wheels 18 to the laser radiation source 12. The industrial robot 120 shown in FIG 4 is equipped with a support plate 152, on the two pivotable by actuators 154 in a pivoting gripper 156 gripping and reliable lifting of the aluminum wheel 18 of a Enable roller conveyor 158. The aluminum wheels 18 are stored and fixed by the industrial robot 120 on a holder 136 formed by U-profiles 138 and adjustable holding pins 140 and attached to a three-axis table 160.

The three-axis table 160 has actuators for moving the rim holder 136 in the three mutually perpendicular spatial directions X, Y and Z. The aluminum wheel 18 can thus be arranged with its screw counterbores 34 in such a way in relation to the laser radiation source 12 that the coating can be removed in the area of the screw counterbores 34. Another difference between the stripping station 110 and the stripping station 10 shown in FIGS. 1 to 3 is that the suction device 122 has a suction mouthpiece 146 fixedly attached to the holder 136.

In the third embodiment of a Entlackungsstation 210 shown in Figures 5 and 6, the laser radiation source 212 is equipped with variable length square tube sections 228a and 228b and thus can be length-adjusted in and against the X and Z directions. The variable-length square tube section 228a is assigned a linear divider 264 fastened to the carrier frame 214 by means of a U-profile 262. The variable-length square tube section 228b has a linear divider 265 attached to the linear adjuster 265. Thus, the beam can be adjusted in the X and Z directions with respect to the aluminum wheel 18, while the adjustment of the aluminum wheel 18 in the Y direction takes place through the conveyor belt 226, as will be described below. The provision of the aluminum wheels 18 for processing by the laser radiation source 212 is ensured in the embodiment according to FIGS. 5 and 6 by a conveyor belt 226 which has three conveyor belt sections 22βa, 226b and 226c operable independently of one another.

The conveyor belt section 226a serves to lift the aluminum wheels 18 of centering spindles 266 brought about by a rail transport system 224, this being an S-shaped one

Course of the conveyor belt section 226a is ensured. As soon as the aluminum wheels 18 are lifted off the continuously operated rail transport system 224 by means of the conveyor belt section 226a, they are brought to a waiting position immediately in front of the conveyor belt section 22 βb.

The conveyor belt section 226b respectively includes laterally taken on guide rails and provided with centering rollers 270 linear actuators 272, the axes of movement are aligned in pairs in parallel. The linear drives 272 are each attached to angle plates 274, which in turn are connected by coupling means with circulating conveyor belts 276 of the conveyor belt section 226b. Thus, the linear drives 272 can be brought into a pick-up position across the conveyor belt section 226a and into a delivery position spanning the conveyor belt section 226c to permit transfer of the aluminum wheel 18 between the respective conveyor belt sections 226a, 226b and 226c.

During machining of the aluminum wheel 18, adjustment of the square tube sections 228a, 228b by the linear actuators 264, 265 takes place to secure the protective sleeve 232 at the end of the square tube section 228b in the desired position to the desired depth in the screw holes of the Retract aluminum wheels 18. As can be seen from the illustration in FIG. 6, the suction device 226 is equipped with a suction mouthpiece 246 arranged in the shape of a pyramid section, whose longitudinal extension visible in FIG. 6 substantially corresponds to the outer diameter of the aluminum wheels 18 to be machined and whose in FIG recognizable transverse extent corresponds to the distance between the guide rails of the conveyor belts 276.

In a non-illustrated embodiment of the invention, it is also provided, the visible in the figure 3, kegelabschnittsförmigen hub ring 50 and / or the cylindrical peripheral cap seat 51, which were also provided with the Beschichtungs.With the Laserstrahlungsguelle.-12 decoat. The cap seat 51 may be stripped in the same orientation of the aluminum wheels 18 as the counterbores 34. For the stripping of the hub ring 50, the retaining pins 40 of the holder 36 may be modified so that they can carry the aluminum wheel 18 even with reversal of the support plate 52 and thus hanging arrangement of the aluminum wheel 18. Thus, the hub ring 50 can face the beam emitted from the laser radiation source 12 and accordingly be stripped.

In an embodiment of the invention, also not shown, the square tube is replaced by a tube with a circular, elliptical or polygonal cross-section.

Claims

claims

1. A method for at least partially removing a

Coating of a functional surface (34, 50, 51) of a vehicle wheel (18) formed by a countersink, a cap seat or a hub ring, characterized in that the functional surface (34, 50, 51) corresponds to one of a radiation source (12, 212 ) is exposed until the coating is transferred in the region of the functional surface (34, 50, 51) at least partially due to the heating by the beam in a gas mixture. '^'

2. The method according to claim 1, characterized in that the functional surface (34, 50, 51) as long as the

Is exposed to radiation beam until in the area of the functional surface (34, 50, 51) a covered by the coating metal surface of the vehicle wheel (18) is at least partially exposed.

3. The method according to claim 1 or 2, characterized in that the gas mixture formed by the heating is sucked off.

4. The method according to any one of the preceding claims, characterized in that the beam has a non-zero divergence, and that the dimensions of a beam spot when the beam hits the vehicle wheel (18) resulting by changing the relative arrangement of the vehicle wheel (18 ) and the beam.

5. The method according to any one of the preceding claims, characterized in that the functional surface (34, 50, 51) is exposed to the beam after all coatings have been applied to the vehicle wheel (18).

6. The method according to any one of the preceding claims, characterized in that the functional surface (34, 50, 51) is exposed to the beam after all coatings have been applied to all surfaces of the vehicle wheel (18).

7. The method according to any one of the preceding claims, characterized in that the coating a

Primer and applied to the primer clearcoat comprises.

8. The method according to any one of the preceding claims, characterized in that the vehicle wheel (18) is moved along a predeterminable path, while a part of the functional surface (34, 50, 51) is exposed to the radiation beam.

9. The method according to claim 8, characterized in that the web in response to a contour of

Function surface (34, 50, 51) and the size of the beam spot is specified.

10. The method according to any one of the preceding claims, characterized in that the vehicle wheel (18) is moved and / or pivoted relative to the spatially stationary beam.

11. The method according to any one of claims 1 to 9, characterized in that the direction and / or location of the

Beam is changed relative to the fixed vehicle wheel (18).

12. The method according to any one of the preceding claims, characterized in that a positioning of the

Beam is compared to the functional surface to be processed (34, 50, 51) by an image processing device (16) is determined.

13. The method according to any one of the preceding claims, characterized in that the beam emerges from a sleeve which is retracted into a recess of the vehicle wheel, at the bottom of which is designed as a lowering functional surface is arranged.

14. The method according to claim 13, characterized in that the sleeve has an elongated, hollow cylindrical shape.

15. An apparatus for at least partially removing a coating from a functional surface (34, 50, 51) of a vehicle wheel (18) formed by a countersink, a cap seat or a hub ring, characterized by a radiation source (12, 212) with which one on the Functional surface (34, 50, 51) can be generated directable radiation beam, so that the coating in the region of the functional surface (34, 50, 51) at least partially as a result of heating by the beam in a gas mixture can be transferred, and by an adjusting device (20, 120 , 160, 264, 265), with which the relative arrangement between the vehicle wheel (18) and the beam is changeable.

16. The apparatus according to claim 15, characterized by a

Sleeve (32, 232), in which the beam is guided and which has an outlet opening for the beam.

17. The apparatus according to claim 16, characterized in that by the adjusting device (264, 265), the sleeve (32, 232) can be moved and / or pivoted.

18. Device according to one of claims 15 to 17, characterized in that by the adjusting device (20, 120, 160) the vehicle wheel (18) process and / or can be pivoted.

19. The device according to claim 18, characterized in that the adjusting device comprises a robot arm (20, 120).

20. The device according to claim 18, characterized in that the adjusting device comprises a travel table (160).

21. Device according to one of claims 15 to 20, characterized by a suction device (22, 122, 222) for sucking the released during the irradiation gas mixture.

22. Device according to one of claims 15 to 21, characterized by an image processing device (16) for determining a positioning of the beam relative to the functional surface to be processed (34, 50, 51).

23. Surface treatment plant with an applicator for applying a coating on a

Vehicle wheel (18), a dryer for curing the applied coating and a device according to any one of claims 15 to 22.