EP2714288A1

EP2714288A1 - System for coating, in particular for painting, articles, in particular vehicle bodies

Info

Publication number: EP2714288A1
Application number: EP12728386.9A
Authority: EP
Inventors: Thomas Albrecht; Frank Tietze
Original assignee: Eisenmann SE
Current assignee: Eisenmann SE
Priority date: 2011-06-01
Filing date: 2012-05-23
Publication date: 2014-04-09
Anticipated expiration: 2032-05-23
Also published as: EP2714288B1; EP2714288B8; WO2012163491A8; DE102011103117A1; CN103619492B; RU2013154682A; CN103619492A; US20140245953A1; US9956567B2; RU2597399C2; WO2012163491A1; BR112013030087A8; BR112013030087A2

Abstract

The invention relates to a system for coating articles (4) which in known manner comprises a coating booth (1), a conveyor system (5), which guides the articles (4) to be coated through the coating booth (2), and at least one application unit (8, 9), which is carried and guided by a handling device (6, 7). A central supply unit (14) comprises a tank (14b) for storing CO₂ in liquid or solid form and conveying means, which are able to remove CO₂from the tank (14b) and supply it at a suitable pressure to a collecting line (13). Said collecting line (13) is connected to at least one cleaning apparatus (10, 11), which in turn comprises at least one nozzle of suitable design for delivering CO₂ for cleaning purposes. Under program control a relative movement between the nozzle and the application unit (8, 9) is induced, such that all surfaces of the application unit (8, 9) to be cleaned can be reached by CO₂. In this manner a complete automation of the cleaning of the outer surfaces of the application unit (8, 9) and optionally adjacent regions of the handling device (6, 7) is possible.

Description

Plant for coating, in particular for painting, objects, in particular vehicle bodies

The invention relates to a system for coating,

in particular painting, of objects, in particular

vehicle bodies, with a) a coating booth; b) a conveyor system, which to be coated

Leads objects through the coating booth; c) at least one application unit for the coating medium; d) at least one handling device, in particular

Robot that carries and guides the application unit

In automatic coating of objects, in particular when painting vehicle bodies, not all of the coating medium emerging from the application units reaches the object to be coated. Rather, so-called "overspray" arises, the greater part with the help of an air flow from the

Coating booth is discharged and reflected to a lesser extent on inner surfaces of the coating booth, but preferably on the outer surfaces of the application units and the adjacent areas of the handling device, reflected. These external surfaces must be freed of precipitation at regular intervals. To facilitate this, is so far common in practice

CONFIRMATION COPY the outer surface of the application unit of the atomizer area up to its mounting location on the handling device, in a painting robot so for example to the wrist, provided with a protective film of, for example Vaseline. This must then be removed manually from time to time and disposed of together with the deposited paint.

It is known in other fields of technology to clean surfaces with the aid of C0 ₂ . This has the advantage that the cleaned-up areas do not have to be additionally dried, since the CC> ₂ used for drying passes directly into the gaseous form by sublimation.

Object of the present invention is to provide a system of the type mentioned, in which the cleaning of the application unit and adjacent areas with less effort on materials and manu eller work can be done largely automated.

This object is inventively achieved in that the system comprises: e) at least one cleaning device comprising at least one nozzle from which C0 ₂ in for cleaning a suitable form, particularly as a C0 ₂ snow or in the form of pellets, exiting and the surfaces of the application unit to be cleaned and optionally adjacent areas of the handling device can be applied; f) a tank for storing C0 ₂ in liquid

or solid form; g) a central supply unit, which in turn Conveying means capable of removing C0 ₂ from the tank and providing it with a pressure suitable for onward transport; a manifold, which is connected to the supply unit and to which at least one cleaning device is connected; where i) programmatically a relative movement between the

Nozzle and the application unit can be brought about, such that all surfaces of the application unit to be cleaned can be reached by the C0 ₂ leaving the nozzle.

With the present invention, the cleaning of the

External surfaces of the application unit are fully automated in a similar manner, as previously possible for the cleaning of the inner flow paths of the application device with solvent. Thus, the total cleaning of the application units in the coating booth can be carried out in a much shorter time without the use of workers; entering the coating booth is generally no longer necessary. The required movements of application unit and / or nozzle are in the interaction between the central

Plant control and, if necessary, the individual associated with the handling equipment and / or the cleaning equipment

Controls causes.

Compared with the use of protective films, the invention reduces the consumption of chemicals, which at the same time reduces disposal costs. The mission of a protective film is eliminated, which on the one hand the eliminates the production stops caused by this and, on the other hand, no longer exposes the assigned worker to the atmosphere in the coating booth. The

Cleaning with the help of C0 ₂ snow can also be carried out in sensitive places where the otherwise used cleaning agent can not be used.

The used for cleaning C0 ₂ may come from conventional sources, such as pressure bottles, which are connected to the supply system; Alternatively, the tank of the central supply unit can also be connected directly to a C0 ₂ recovery or supply system. Depending on the shape of the applied to the surfaces to be cleaned C0 ₂ , the tank for storage of liquid or solid C0 _{2 may be} formed. Solid C0 ₂ can already be present in the tank in the form of pellets, which can be conveyed by means of a corresponding air flow through the manifold.

Alternatively, it is also possible that the fixed C0 ₂

is in the form of a block and that a crusher is provided which is able to grate off small parts of the block. In this embodiment, the loss of CO _{2 is} due to sublimation

smaller than when storing pellets.

When liquid C0 _{2 is} used, the manifold preferably comprises a liquid C0 _{2 line} and a nebulizing compressed air line and is connected to at least one two-component nozzle for generating O ₂ snow. The C0 ₂ ~ snow thus arises only when exiting the corresponding nozzle. The nozzle of the cleaning device can be pivotably mounted on a holder, for which purpose a corresponding drive, motor or pneumatic, will generally be provided. In this way, a part of the required relative movement between the nozzle and the

Application integrity by movement of the nozzle take place.

The cleaning device preferably comprises a plurality of nozzles, from which the application unit can be acted upon from different angles. The use of multiple nozzles reduces the amount of relative movement between nozzle and application unit required to clean all surface areas. It is also expedient if the collecting line is connected to at least one removal point, to which a manual cleaning device can be connected. This manual cleaning device is exceptionally used when automatic cleaning of the application unit by the cleaning device is not sufficient or for cleaning other surfaces within the coating booth where precipitation has formed. In an advantageous embodiment of the invention, the cleaning device has an enclosure which has at least one opening through which the application unit can be inserted into the interior of the enclosure. In this way, the cleaning process is largely shielded from the other areas of the coating booth.

Finally, it is expedient if the cleaning device has a closed space in which the

Delivery end of the application unit for flushing the internal ren flow paths can be introduced with solvent through an opening. In this way, the cleaning of the outer surface can take place substantially simultaneously with the cleaning of the inner flow paths of the application unit, so that the downtimes of the system can be further reduced.

Embodiments of the invention will be explained in more detail with reference to the drawing; show it

Figure 1 shows schematically a section of the layout

a paint booth;

FIGS. 2 to 5

schematically in vertical or horizontal

Cut cleaning stations, as they can be found in the paint booth of Figure 1 use. First, reference is made to FIG. This can be as a schematic layout of a part of a paint booth or as a horizontal section through the

Paint booth can be read below the ceiling. The paint booth provided overall with the reference numeral 1 comprises two parallel side walls 2, which are closed in the region no longer represented by end faces, which in turn are in a known manner

Gates or locks for the objects to be painted 4 have. The bottom of the spray booth 1 is essentially formed by a grate 3, while it is closed at the top, likewise in a conventional manner, by an air plenum, from which conditioned air can be conducted into the interior of the spray booth 1. The objects to be painted 4, which are shown schematically in the drawing as rectangles and which may be in particular vehicle bodies or parts thereof, are guided by means of a conveyor system 5 in a continuous or intermittent movement through the interior of the painting booth 1, for example in Figure 1 from left to right. The nature of the

Conveyor system 5 is without reference in the present context

Concern.

On both sides of the path of movement of the objects 4 on the conveyor system 5 painting robots 6, 7 are arranged.

Again, different designs can be used. For example only, a total of four articulated robot 6 are provided, of which two are arranged on one side of the path of movement of the objects 4, as well as two industrial robots 7, one of which is arranged on one side of the path of movement. Both types of robot have in common that they have a movable robot arm 6a and 7a, at the end of each an application unit 8 and 9 is worn. Each of these application units 8, 9 comprises the actual applicator, which may in particular be spray guns and / or high-rotation atomizers.

Along the side walls 2 of the painting booth 1 a plurality of cleaning stations 10, 11 is provided,

which are shown schematically as rectangles. The cleaning stations 10, 11 have in common that they at least

contain a nozzle, from which C0 ₂ in the form of solid

Pellets or snow can escape. Details of possible constructions of such cleaning stations 10,

11 will be described below ^¬ Ben with reference to the figures 2 to 5. At the upper side wall 2 of the paint booth 1 in Figure 1 except the cleaning stations 10, 11 sampling points 12 provided for connecting manual cleaning equipment, ie cleaning equipment, the nozzle differently than that of the cleaning stations 10, 11 not robots for certain programs automatically but by hand be guided.

All removal stations 10, 11, 12 are connected via branch lines, which are not provided with the reference numerals for clarity, with a manifold 13.

This leads to a central supply unit 14,.

which is added in the embodiment of Figure 1 to the lower side wall 2 there from the outside. The

Central supply unit 14 has an area

14a, in which all for conveying CO ,, in pellets

or in liquid form required units, pumps and valves and associated controls are housed. The provision of auxiliary media, such as compressed air and conveying air, as they are used to transport

CC> 2 especially in pellet form or for the production of

C0 ₂ snow is required, takes place in the area 14a of the central supply unit 14. The latter also comprises a tank 14b, in which the used for cleaning C0 ₂ in the form of pellets or in liquid form is kept in stock. Instead of pellets, it is also possible to use a large, solid C0 ₂ block, from which smaller solid particles are then shredded as required for transport through lines of appropriate size.

The tank 14b is connected via a line 15 to an external C0 ₂ source in connection. This may be a conventional pressure bottle or any other source of CO ". If gaseous C0 _{2 is} supplied, of course, the necessary for liquefaction or solidification units and facilities must be present in the central supply unit 14.

The cleaning stations 10, 11 have an enclosure 16 which has such an opening that the application units 8, 9 can be introduced by the associated robots 6, 7 into the interior of the corresponding cleaning device 10, 11. This generally means an opening upwards and optionally also towards at least one side. Examples of this are described below. The painting booth 1 described above operates as follows:

The normal painting process is carried out in the usual way: The objects to be painted and prepared accordingly 4 are supplied from the left with the aid of the conveyor system 5 in Figure 1 and get into the

Area of the guided by the robots 6, 7 application devices 8 and 9. According to predetermined movement programs under the command of the system control and the individual robot controls the objects 4 from the application units 8, 9 are sprayed with paint. When they leave the painting booth 1 to the right in FIG. 1, they are completely painted or at least one painting phase is completed. The overspray produced during the painting process is essentially taken along by the air flow which causes the

Paint booth 1 from top to bottom, starting from the above-mentioned Luftplenum, and flows through the bottom of the spray booth 1 forming grate 3. However, part of the overspray is reflected on the outside Chen the robot arms 6a, 7a and the application units 8, 9 down. From there they must be removed at certain intervals, depending on the degree of soiling. This happens now in the following way:

It is assumed that the tank 14b of the central supply unit 14 is filled via line 15 with liquid C0 ₂ . The area 14a of the central supply unit 14 has filled the manifold 13 with the required liquid CC> ₂ and atomizing compressed air. In this case, the manifold 13 comprises separate

Single lines that lead to the respective sampling point 10, 11, 12. Liquid C0 ₂ or atomizing compressed air is now at these removal stations 10, 11, 12 at. For cleaning, the application units 8, 9 and the regions of the robot arms 6a, 7a adjacent to them are now again introduced into the housings of the cleaning stations 10, 11 through the openings already mentioned above.

Now, the local valves are opened so that liquid C0 ₂ and atomizing compressed air flow into the corresponding two-component nozzles and there can form CC ^ - snow. With this snow, the surface areas of the application units 8, 9 and the adjacent areas of the robot arms 6a, 7a, as far as they are dirty, acted upon. The nozzles, as will be explained in more detail below, can be pivoted again by a program-controlled motor to clean them all

Reach surfaces. The contaminants dissolve, as is known in and of itself by C0 ₂ -reinigungsverfahren.

The application units 8, 9 are then removed again with the aid of the associated robot arms 6a, 7a from the housings. sungen the cleaning stations 10, 11 moved out; remaining, not completely cleaned surfaces

can with the help of manual cleaning devices IIa,

12 be cleaned if necessary.

Then, the painting operation can be resumed immediately without the need for drying or other aftertreatment of the surface areas of application units 8, 9 or adjacent areas of the robot arms 6a, 7a which have been cleaned of paint.

FIG. 2 schematically shows a cleaning station 10 in vertical section. Shown is a portion of the cabin wall 2, a portion of the opposite wall of the. Housing 16, one attached to the cabin wall 2 by means of a holder 17 two-component nozzle 18 and one by means of a holder 19 on the

Housing wall 16 fastened two-component nozzle 20.

The two-component nozzles 18, 20 are supplied via supply hoses 21, 22, which are connected to the manifold 13, with liquid C0 ₂ and atomizing compressed air. The two-component nozzles 18, 20 can be

about a horizontal axis 23 and 24 motor or

pneumatically under the influence of plant control

pivot.

From above, the application unit 8 of an articulated robot 6 is introduced in FIG. 2 between the housing wall 16 and the cabin wall 2. When cleaning the inserted region of the application unit 8 and, if appropriate, the adjacent region of the associated robot arm 6a, the two-component nozzles 18, 20 generate CO.sub.2 snow and thus act on the surfaces to be cleaned. In order to reach all surfaces, the two-component nozzles 18, 20 thereby about the above-mentioned axes 23, 24 pivots. Optionally, in addition

the application unit 8 are rotated about a vertical axis. After completion of these cleaning operations, the application unit 8 by means of the associated robot arm

6a again pulled up from the cleaning station 10. Figure 3 shows, also in vertical section, a

Variant of the cleaning station 10 of Figure 2. Corresponding parts are here designated by the same reference numerals as in Figure 2, but in addition 100. The cabin wall 102 and the housing wall 116 can be seen. In this exemplary embodiment, a bottom wall 125 of the cleaning station 110, in which there is a discharge opening 126, is additionally shown. Above the discharge opening 126, a cleaning box 127 surrounding a substantially closed space is provided, which has an opening 128 which points obliquely upwards and inwards into the cleaning appliance 110 and is surrounded by a seal 129.

In the case of the cleaning device 110 shown in FIG. 3, a two-component nozzle 120 is provided only on the housing wall 116, which is supplied via the hose 122 with liquid CO ₂ and atomizing air.

For cleaning, the application unit 108 with its foremost, the actual sputtering area 108 a end having in advance through the opening 128 in the

Box 127 introduced. While the outside surfaces of the

Application unit 108 are cleaned by means of the two-component nozzle 120 in the manner already described above, the inner flow paths of the application unit 108 is cleaned by solvent which is sprayed via the sputtering area 128a into the interior of the box 127 and finally removed via the drain opening 126. In this way, the outer surfaces are cleaned simultaneously with the inner flow paths of the application unit 108.

Another embodiment of a cleaning device 210 is shown in horizontal section in FIG. Parts that correspond to those of the cleaning device of Figure 2 are provided with the same reference numerals plus 200. To the cabin wall 202, the housing 216 of the cleaning device 210 is attached. This is open at the top and additionally has an opening 230 in one of the side walls. A two-component nozzle 218, 220, 231 is fastened to the cabin wall 202 as well as to those side walls of the housing 216 which have no opening. The nozzles 218, 220, 231 in each case enclose an angle of 120 °.

The applicator 208 of an articulated robot is from above and / or through the opening 230 of the housing 216 in its interior to the position shown in Figure 4 in the middle between the Zerstäubungsbereichen the

Two-component nozzles 218, 220, 231 introduced. There, the application unit 208 can be acted upon from three sides with C0 ₂ ~ snow. Under favorable circumstances, in this way all surface areas of the

Application unit 208 can be achieved without this would have to be additionally rotated.

In Figure 4, attached to the cleaning station 211, a removal point 211a for a manual cleaning device, not shown itself, is shown. Figure 5 finally shows, also in the horizontal

Section, a cleaning station 311, which largely corresponds to that of Figure 4 and whose parts are provided with reference numerals, which are increased again by 100. The cabin wall 302, the housing 316 and its opening 230 are similar to the corresponding components in the embodiment of Figure 4 and therefore need not be described again. The main difference between the embodiments of Figures 5 and 4 is that in the embodiment of Figure 5, all three two-component nozzles 318, 320 and 331 are fixed to the cabin wall 302. In this construction, it will generally be necessary to turn the application unit 308 to be cleaned during the cleaning process so that all surface areas of C0 ₂ ~ snow are reached.

In the above description of the various embodiments of cleaning devices 10, 11; 110; 211; 311 a cleaning with C0 ₂ snow was assumed. Of the

However, cleaning process occurs in much the same way when C0 ₂ pellets are used instead of C0 ₂ snow. These are guided by means of transport air through the supply line 13 to the various removal points 10, 11, 12. Their cleaning effect is due to the mechanical impact of the pellets on the surfaces to be cleaned slightly larger in a known manner; the cleaning with C0 ₂ foam, on the other hand, is gentler.

Claims

claims

Plant for coating, in particular painting, articles, in particular vehicle bodies, with a) a coating b) b) a conveyor system, which to be coated

Leads objects through the coating booth; c) at least one application unit for the Beschich processing medium; d) at least one handling device, in particular

Robot that carries and guides the application unit; characterized in that it comprises: e) at least one cleaning device (10, 11) having at least one nozzle (18, 20; 120; 218, 220, 231; 318, 320, 331) from which C0 ₂ in for cleaning purposes suitable form, in particular as C0 ₂ snow or in the form of pellets, and on the surfaces to be cleaned of the application unit (8, 9, 108;

208; 308) and optionally adjacent areas of the handling device (6, 7) can be applied; f) a tank (14b) for storing CO ^ in liquid or solid form; g) a central supply unit (14), in turn Having conveying means capable of removing C0 ₂ from the tank (14b) and providing it with a pressure suitable for onward transport; h) a manifold (13) which communicates with the central

Supply unit (14) is connected and to which at least one cleaning device (10, 11) is connected; where i) programmatically a relative movement between

the nozzle (18, 20, 120, 218, 220, 231, 318, 320,

331) and the application unit (8, 9, 108, 208, 308) can be brought about in such a way that all surfaces of the application unit (8, 9,

9; 108; 208; 308) from the C0 ₂ leaving the nozzle (18, 20; 120; 218, 220, 231; 318, 320, 331)

can be achieved.

2. Plant according to claim 1, characterized

that the tank (14b) of the central supply unit

(14) via a supply line (15) is filled, which is connected to pressure cylinders or a CO ^ recovery or supply system.

3. Plant according to claim 1 or 2, characterized in that the tank (14b) for the storage of liquid

Is formed C0. ₂

4. Plant according to claim 1 or 2, characterized in that the tank (14b) for the storage of solid

CO "is formed.

5. Plant according to claim 4, characterized in that that the solid CO_ is in the form of pellets.

6. Plant according to claim 4, characterized

that the solid C0 _{2 is} in the form of a block and that a crusher is provided which is capable of rasping small parts off the block.

7. Plant according to one of claims 1 to 3, characterized

in that the collecting line (13) has a

Liquid CC </ RTI> conduit and atomizing compressed air conduit and connected to at least one two-component nozzle (18, 20, 120, 118, 220, 231, 318, 320, 331) for producing CC 2 snow.

8. Installation according to one of the preceding claims,

characterized in that the nozzle (18, 20, 120;

218, 220, 231; 318, 320 331) on a holder (17, 19;

119; 217, 219, 232; 317, 319, 332) is pivotally mounted.

9. Plant according to one of the preceding claims,

characterized in that the cleaning device

(211; 311) has a plurality of nozzles (218, 220, 231; 318, 320, 331) from which the application unit (208;

308) can be acted upon from different angles.

10. Installation according to one of the preceding claims,

characterized in that the collecting line (13) is connected to at least one removal point, to which a manual cleaning device (IIa, 12, 211a;

311a) can be connected.

11. Plant according to one of the preceding claims, characterized in that the cleaning device (10; 110; 211; 311) has an enclosure (16; 116; 216; 316) which has at least one opening (230; 330) through which the application unit (8,9; 208;

308) can be inserted inside the enclosure (116; 216; 316).

12. Plant according to one of the preceding claims,

characterized in that the cleaning device (110) has a closed space (127), in which the discharge end (128a) of the application unit (108) for flushing the inner flow paths with solvent through an opening (128) can be introduced.