EP1671706A2 - Process and device for cleaning spraying devices - Google Patents

Abstract

The method involves cleaning a spraying head of a sprayer (1) in a cleaning device (10) by a cleaning medium that is conveyed through their nozzle arrangement and/or to an outer side of the head. The medium is sprayed in a discharging device (30) in the cleaning device. The device (30) prevents the sprayed medium to reach an area of an internal space of the cleaning device and/or an outer side of the sprayer. An independent claim is also included for a coating plant having a device for cleaning a spraying device that serves for machine-series coating of work pieces.

Description

The invention relates to a method and a cleaning device for cleaning a spraying device used for automatic series coating of workpieces according to the preamble of the independent claims. The spraying device can typically be the atomizer of the painting robots customary for coating workpieces such as vehicle bodies or their parts, ie in particular air atomizers or rotary atomisers including electrostatic atomizers for the internal charging of the sprayed coating material and / or with external charging electrodes.

For the required automatically during the coating operation at regular intervals cleaning of such atomizers different cleaning devices are known, each consisting of a closed up to the insertion for the atomizer housing in the interior of the inserted part of the air or rotary atomizer of a rotatable or fixed Nozzle arrangement of the cleaning device is sprayed with cleaning liquid and then dried with compressed air. For example, from EP 1 367 302 or DE 101 10 098 known cleaning devices of this type have the disadvantage that they are unsuitable for the usually referred to as short rinsing interior cleaning process, the detergent from a short rinsing channel of the atomizer coming through the ink nozzle and in the case of Rotationszerstäubern in particular in the manner known from EP 0 715 896 also directed to the outside of the rotating bell cup and sprayed by the atomizer. This can, for example, during a color change or after painting a certain number Of bodies or other workpieces with the same color be appropriate to remove any color deposits on the paint nozzle or on the bell cup. When this internal cleaning or short-purging operation is carried out in the known cleaning devices, the resulting during the atomization of the paint and detergent mixture and strongly swirling spray spreads in the interior of the cleaner and pollutes both the interior including the cleaning nozzle assembly disposed therein and the outside of the inserted atomizer. Although one could first perform the short rinse and only then spray the outside of the atomizer and clean the interior, but the associated loss of time in the series coating of workpieces is highly undesirable because of the corresponding production losses. This problem essentially occurs even if, according to EP 0 869 848 or DE 101 29 667, without introducing cleaning of the outside of the atomizer housing, only the spray head or only the air cap of air atomizers is introduced into the cleaning appliance.

Another time problem arises from the fact that forms in the interior of cleaning equipment, especially with organic solvents containing coating and rinsing agents ignitable spray and therefore no leading to sparks electrical voltage flashovers may be possible. This danger consists in the cleaning of electrostatic atomizers, which are known to be connected for contact charging of the sprayed coating material, for example by the bell cup or for external charging by external electrodes to high voltage in the order of 100 kV. Since the known cleaning devices are usually at ground potential, had before the onset of the atomizer first turned off its high voltage and degraded become what a loss of time typically in the order of a minute had to be accepted.

The invention has for its object to provide a method or a device that allows the coating operation periodically necessary cleaning of the spray devices with less loss of time than before.

This object is solved by the features of the claims.

According to a first aspect of the invention, when the internal cleaning or short-rinsing process in the cleaning device is carried out, the media sprayed from the spray head of the atomizer and consisting of paint or other coating material and / or the flushing medium are sprayed into a discharge device provided inside the cleaning device, which media prevents it from reaching outside of the discharge means lying areas of the interior of the cleaning device and / or the outside of the atomizer. According to an expedient embodiment, this discharge device contains a tubular body which, with its inlet opening in the vicinity of the spray head or surrounding it, is simply arranged in the interior of the cleaning device and directs the sprayed colorant and detergent mixture into the drainage device of the interior or out of the cleaning device can lead out. However, other suitable for the purpose considered discharge devices are conceivable, for example, blowing or suction for the spray generated by the atomizer. In any case, the invention has the advantage that there is no contamination caused by turbulence of the spray of the interior of the cleaning device and the previous additional and / or renewed contamination of the in the cleaning device used part of the atomizer to be cleaned is avoided. Since, according to the invention, a mutual influence of the short flushing process and an external cleaning of the atomizer carried out in the same device is prevented, these two processes can be carried out parallel to one another, ie simultaneously, so that a corresponding time saving results for the overall cleaning process. The reduced contamination of the cleaning device also reduces the maintenance costs.

In addition, according to the invention, the above-mentioned danger of explosion in cleaning devices can be avoided if, prior to the start of cleaning and preferably before the introduction of the atomizer into the cleaning device, the charging device of the spray device to the electrical potential of the cleaning device or the cleaning device to the electrical potential of the charging device is placed. The cleaning device may be put under high voltage at least when approaching the atomizer when it is mounted or arranged with appropriate electrical insulation and at a sufficient distance from all grounded parts of the coating system. In other instances, if the associated footprint and concomitant increase in total system electrical capacity are to be avoided, it may be more convenient to ground the atomizer when and / or before it is inserted into the cleaner. In this aspect, the invention is based on the recognition that for the potential equalization a rapid degradation of the high voltage potential of the charging device of the atomizer typically in the order of milliseconds is sufficient, so that the time loss associated with the shutdown of the high voltage generator and the complete voltage reduction avoided and after a coating process practically With the cleaning without delay and then immediately with the coating can be started again.

There are several ways to quickly ground the atomizer. For example, the charging device of the atomizer can be grounded by an automatically controlled switch connected to the charging device. Instead or in addition to this, the atomizer may be grounded by the cleaner itself. In particular, the nebulizer may be removed from the coating machine such as e.g. a painting robot or from a provided for introducing the atomizer in the cleaning device handling machine are brought to a grounded contact arrangement of the cleaning device with which the charging device of the atomizer is brought into contact.

According to another feature of the invention, an alarm signal is generated and / or the handling machine is brought to a standstill when the atomizer approaches the cleaning device from a direction other than that predetermined by the motion control program of the machine. In particular, by a special control program for the nebulizer to bring the cleaning device handling machine in the vicinity of the cleaning device in a conventional manner, a limited space for the movement of the nebulizer, which is blocked by the control program for the movement of the nebulizer when he approaching from a direction other than the given direction. These measures initially ensure that the atomizer is always introduced into the device in the correct manner without the risk of collisions with the cleaning device. In addition, there is the advantage that the atomizer when monitoring its approach to the cleaning device to initiate the timely potential equalization with certainty has to pass for this purpose provided on the given trajectory proximity sensor, so that the explosion protection safety is increased.

Fig. 1

eine mögliche Ausführungsform eines Reinigungsgeräts für einen Rotationszerstäuber;

Fig. 2

eine schematisch vereinfachte Schaltungsanordnung zum Erden eines Zerstäubers bei Annäherung an ein Reinigungsgerät;

Fig. 3

eine gegenüber Fig. 2 abgewandelte Schaltungsanordnung; und

Fig. 4

eine weitere mögliche Schaltung zur Erdung des Zerstäubers.

On a simplified in the drawing illustrated embodiment, the invention is explained in detail. Show it

Fig. 1

a possible embodiment of a cleaning device for a rotary atomizer;

Fig. 2

a schematically simplified circuit arrangement for grounding a nebulizer when approaching a cleaning device;

Fig. 3

a comparison with Figure 2 modified circuitry. and

Fig. 4

another possible circuit for grounding the atomizer.

1 is a rotary atomizer 1 of conventional design with the cylindrical and conical outer casing 2, the bell cup 3 and the distributed around the outer casing, axially projecting from the retaining ring 4 outer electrodes 5 in the cleaning device 10 described here. The cleaning device 10 may be arranged, for example, in a paint booth and consists essentially of a housing body 11, the interior 12 of which may extend from the circular insertion opening 13, for example initially conical and then cylindrical up to a funnel-shaped bottom part 14 with a cylindrical outlet 15. The rotary atomizer 1 is shown in the coaxial with the central axis of the housing body 11 inserted into the cleaning device 10, that the insertion opening 13, the cylindrical part of his Enclosed outer housing 2 and the bell plate facing away from the end with the retaining ring 4 and the outer electrodes 5 outside of the cleaning device or at least the housing body 11 is located. By its conically widening from the insertion opening 13 part, the shape of the housing body 11 is adapted to the direction in which the outer electrodes 5 protrude from the retaining ring 4. Instead of the illustrated example, it is also possible to use the rotary atomizer 1 completely or at least with its outer electrodes 5 in the interior of the housing of the cleaning device or the outer electrodes 5 in separate interiors of the cleaning device. The interior 12 of the illustrated cleaning device 10 should be tightly sealed with the atomizer inserted to the outside and is therefore provided at the insertion opening 13 with a circumferentially extending around the outer housing 2 seal assembly 16, for example with a non-contact pneumatic seal, by one of the in EP 1 367 302 mentioned or described annular air nozzle assembly may be formed. The cylindrical outlet 15 can lead to a disposal device, not shown, and be closed. With flange 17, the housing body 11 of the cleaning device may be attached to an external holder.

For cleaning the outside of the inserted into the inner space 12 of the outer part 2 of the atomizer, the cleaning device 10 has a concentric with the axes of the rotary atomizer and the housing body 11 arranged annular body 20 which forms or contains a feed line for a paint solvent suitable as cleaning liquid, and at arranged around the central axis of the cleaning device, connected to said feed line and directed to the outside of the outer housing 2 cleaning nozzles 21 are arranged. Parallel and concentric with the ring body 20 is similar as this fixed in the interior 12, a second annular body 22 which forms or contains a compressed or compressed gas line, and are arranged on the likewise directed to the outer housing 2 nozzles 23 from which air or gas is blown to dry on the outer housing 2. It could also satisfy a single ring body, which is provided with both nozzles for the solvent and with nozzles and associated lines, while on the other hand, two or more each provided with solvent and / or nozzles ring body may be present. For cleaning and / or drying of the atomizer housing serving nozzle arrangements could also be arranged directly on the wall of the interior 12 of the cleaning device 10. In the example shown, the lowermost ring body 22, which is axially farthest from the insertion opening 13, is located axially close to the bell-shaped front end of the outer housing 2. The nozzle arrangements can be fed by solvent or compressed air lines leading from the cabin into the cleaning device ,

Although a cleaning or blast nozzle arrangement fixed in the cleaning device, such as the nozzles 21 and 23, is generally to be preferred, in other cases also rotatable or pivotable nozzle arrangements may be provided around the atomiser.

To improve the cleaning or drying action, it may be expedient to heat the solvent supplied to the nozzles or other cleaning medium and / or the compressed gas. The heating can be done by an electrical or by a heat exchanger formed or other heating device outside or inside the cleaning device or possibly also within the nozzle assembly. By heating the compressed gas can also be a leading to condensation Avoid cooling by the gas relaxing at the nozzle.

According to a particular embodiment, the blowing nozzles 23 can be designed in a manner known per se in principle ("dry jet "® from SATA) in such a way that the flow from the outside, e.g. Compressed air supplied from a compressed air connection of the cabin generates a negative pressure in or at the tuyere, which draws in additional air from the vicinity of the tuyere. The sucked ambient air can be passed through a filter of the tuyere and thereby cleaned before being mixed with the main flow is passed to the atomizer.

As was explained at the outset, media sprayed off from the bell cup 3 of the rotary atomizer 1 used in the cleaning device 10, such as paint residues, rinsing liquid and their mixture, are to be prevented from the outer housing 2 of the atomizer or the walls of the interior 12 or parts of the cleaning device located therein in particular, to reach and contaminate the annular bodies 20 and 22 and their nozzles. For this reason, a cylindrical inner tube body 30 is mounted coaxially to the central axis of the housing body 11 in the inner space 12, in which the atomizer 1 facing the open input end 31, the media are sprayed from the bell cup 3. The inner diameter of the inner tube body 30 is expediently larger than the outer diameter of the bell cup 3 at least at the input end 31, while its own outer diameter may be smaller than the inner diameter of the inner space 12 of the housing body 11, on the inner wall of which the inner tube body 30 is fastened, for example with radial cross members 33 can. The input end 31 of the inner tube body 30 may be axially positioned so that the spray edge at the front end of the bell cup third is within the inner tube body 30 and the axially rear bell cup part is outside. Suitably, the illustrated inner tube body 30 at its input end 31 have a conically tapering end 34 to the outside up to the entrance plate enclosing the bell cup. In the direction away from the input end 31, the inner tube body 30 extends into or through the outlet 15 of the cleaning device 10. It can open in the cleaning device itself or in an external disposal device.

The cleaning device described here is also suitable for the cleaning of other types of atomizers, such as rotary atomizers without external electrodes or air atomizers, the spray head is not formed as in the illustrated example by a rotating bell cup, but by the usual fixed nozzle and air cap assembly. The housing and inner tube body of the cleaning device can be modified in this case according to the respective Zerstäubertyp.

In operation, the spray device to be cleaned, here the rotary atomizer 1 coming from a to the central axis of the housing and tubular body 11, 30 parallel direction and coaxially hereby introduced into the cleaning device 10, for example, vertically from above, although with a corresponding arrangement of the cleaning device 10th in itself any direction is possible. For introducing the atomizer into the cleaning device, it is possible to use the painting robot with which a workpiece was immediately painted beforehand, or in other cases, for example, a handling robot or other handling device provided for this purpose, which automatically takes over the atomizer from the coating machine. Once the atomizer is in the position shown in Fig. 1, can with the Kurzspül- or interior cleaning process in which the rotating bell cup of residual color and flushing medium sprayed into the inner tube body 30, and at the same time without delay even with the external cleaning of the atomizer by spraying his Au ßengehäuses be started by the nozzle 21. At the same time, if appropriate, the air nozzles of the sealing arrangement 16 can be switched on. After spraying, the outer casing 2 is dried by the compressed air nozzles 23. While the cleaning liquid of the nozzles 21 collecting in the interior 12 is disposed of in a manner known per se through the funnel-shaped bottom part 14 and the outlet 15, the media sprayed from the bell cup can be led out of the cleaning device through the pipe body 30. Upon completion of these cleaning operations, the nebulizer can be immediately withdrawn from the cleaner and used for the next coating operation.

The outer electrodes 5 of the rotary atomizer to be cleaned according to FIG. 1 or in other cases electrostatic air or other atomizers are known to be connected to high voltage in the order of magnitude of 100 kV in the case of workpiece coating. Since in the approximation of such electrostatic sprayer to the cleaning device 10 for explosion protection and other safety reasons, electrical flashovers may not be possible according to a particular feature of the invention before the start of cleaning and preferably before the introduction of the atomizer during its approach to the cleaning device Atomizer placed on the electrical potential of the cleaning device, such as ground potential, or the cleaning device to the electrical potential of the atomizer.

In order to avoid flashovers, it would be possible to first switch off the high voltage after a coating process. However, it would be impractical in some cases, before the startup of the cleaning device after a coating operation, completely shut off the high voltage generator of the atomizer, including its own power supply, because in this case the degradation of the high voltage and the required after cleaning reclosure undesirably take long and corresponding production delays May have consequences. In such cases, there are different possibilities for the potential equalization according to the invention.

A first option is to electrically isolate the purifier and charge it to the high voltage potential of the electrical nebulizer, e.g. by being connected in parallel to the atomizer at its high voltage generator, wherein a switching means may be provided, with which this parallel circuit can be alternately set to high voltage potential and grounded.

On the other hand, if the cleaning device is to be grounded all the time, according to the invention the atomiser is also earthed, for which in turn there are various possibilities which result in no or only minimal losses of time. A simple possibility is the circuit shown schematically in Figure 2, in which between the high voltage generator HS and the charging device (electrodes) of the atomizer Z a programmable earth switch ES is connected to the atomizer before reaching the grounded cleaning device RG disconnected from the high voltage generator and at ground potential. The ground switch ES may be outside or inside the handling machine or atomizer. Although the grounding circuit may conveniently contain one of the known per se resistance or other damping devices, the atomizer can be connected to the ground switch ES unloaded in an extremely short time. This depending on the circumstances more or less damped discharge can take place without loss of time during the time in which the atomizer is moved to the cleaning device.

To avoid a safety risk, the timing of grounding the nebulizer (or potential equalization by charging the purifier) is preferably controlled in response to the nebulizer approaching the purifier. Since the approach speed is known, as dictated by the control program of the robot, one can define in the path of the atomizer a sufficient safety distance from the cleaning device, below which the grounding or potential equalization is initiated. The achievement of the safety limit can be achieved by a proximity sensor e.g. in the form of a light barrier, a laser scanner od. Like. Be monitored and reported. The safety margin at which grounding or potential equalization must be initiated can be calculated from the known air isolation distance between the high voltage potential and ground plus the distance that the nebulizer travels in the time required to respond to the proximity sensor and transhipment , in Erdungsfall example, for the response of an earth switch and for the subsequent rapid discharge of the atomizer.

According to an alternative option shown in FIG. 3 for grounding the atomizer Z with an earth switch ES ', the atomizer can remain connected to the switched-on high voltage generator HS during grounding, to which the earth switch ES' is connected in parallel. By appropriate control measures can be avoided in this case that the high voltage generator HS is switched off due to this short circuit.

The two options according to FIG. 2 and FIG. 3 can also be modified or supplemented so that instead of or in addition to the earth switch ES or ES ', the grounded cleaning device RG itself contacts the electrode and charging device of the atomizer Z during its approach and thereby grounds. For example, the high-voltage potential at the atomizer can be broken down in a very short time that the atomizer touches a grounded contact arrangement of the cleaning device on reaching its final position in the cleaning device or during its insertion movement, which is also a plurality of contact elements such as one of the atomizer in the Insertion motion traversed grounded flexible curtain can act of single conductors.

As shown schematically in Fig. 4, the atomizer could be grounded without ground switch and without direct Erdkontaktierung. Before the atomiser reaches the cleaning device RG, in this variant, the output voltage of the high voltage generator HS by automatically controlled reduction of its set or e.g. the voltage setpoint predetermined by the control program of the system is at least approximately down-regulated to zero, without the high-voltage generator being switched off. The high voltage potential at the atomizer is then degraded very quickly and preferably even during the feed movement of the atomizer by a resistor R connected in parallel with the high voltage generator HS to earth.

Even with the other grounding options described above, such as when grounding by the cleaning device itself, it may be appropriate to previously regulate the output voltage of the high voltage generator in the manner explained.

So that the spray device such as the rotary atomizer 1 in Fig. 1 can be easily and reliably used by the machine provided in the cleaning device 10, he must approach the cleaning device from the right direction, so for example in a vertical arrangement of the cleaning device vertically from above. In addition, the correct direction is also important if the atomizer is to pass through the above-mentioned proximity sensor as it moves to the cleaning device, so that the required potential equalization can be carried out in good time. Although the correct path is given by the movement program of the machine moving the atomizer to the cleaning device, errors may result in deviations from the prescribed trajectory and thus errors in the proximity sensor or collisions of the atomizer with the cleaning device. In order to prevent collisions and / or the risk of explosion by flashovers associated safety risks, is ensured according to the above-described further feature of the invention that the atomizer can approach the cleaning device only from the prescribed direction, so for example in Fig. 1 only vertically from above. As can be defined for this purpose, a limited virtual lock space in the vicinity of the cleaning device into which the atomizer, e.g. can only be moved vertically from above, is known per se in the field of robot control. Possibilities are described for example in EP 1 332 841, EP 1 035 953 and DE 102004019888.

Claims (34)

A method of cleaning a machine spray coating device (1) for automatic series coating of workpieces, in which the spray device contaminated by the coating material is introduced by the coating machine or another automatically controlled handling machine with its part to be cleaned into the interior of a cleaning device (10),
characterized in that the spray head (3) of the spray device (1) in the cleaning device (10) is cleaned by a cleaning medium coming from the interior of the spray device (1) through the nozzle assembly and / or on the outside of the spray head (3) is directed
and that the medium sprayed from the spray head (3) in the cleaning device (10) is sprayed into a discharge device (30) provided inside the cleaning device, which prevents the sprayed medium from leaving areas of the interior (12) lying outside the discharge device (30). of the cleaning device (10) and / or the outside of the spray device (1). A method according to claim 1, characterized in that the cleaning medium from the rotating bell cup (3) of a rotary atomizer (1) or from the nozzle of an air atomizer in a discharge pipe (30) of the cleaning device (10) is sprayed. A method according to claim 2, characterized in that the cleaning medium from the discharge pipe (30) in the interior (12) of the cleaning device (10) or out of the cleaning device out. Method according to one of claims 1 to 3, characterized in that in the interior (12) of the cleaning device (10) located areas of the outside of the spray device (1) are sprayed from a nozzle assembly (21) of the cleaning device with a cleaning medium. A method according to claim 4, characterized in that the outside of the spray device (1) from the nozzle assembly (21) of the cleaning device (10) is sprayed, while at the same time sprayed from the interior of the spray device (1) coming medium from the spray head (3) becomes. Method according to one of claims 1 to 5, characterized in that the spray device (1) is dried in the cleaning device (10) by spraying with compressed air or another compressed gas. Method according to one of claims 4 to 6, characterized in that the cleaning medium and / or the compressed gas are heated. A method according to claim 6 or 7, characterized in that the compressed gas is sprayed from a nozzle assembly (23) with or in which by the gas flow a negative pressure is generated sucked by the air from the vicinity of the nozzle assembly and with the pressurized gas to the drying spray device is passed. A method according to claim 8, characterized in that the ambient air is sucked through a filter. Method according to one of claims 1 to 9 or according to the preamble of claim 1 for cleaning a spray device (1) with a charging device (5) for the coating material, which is connected to a high-voltage generator for electrostatic coating, characterized in that the charging device (5) of the spray device (1) is adapted to the electrical potential of the cleaning device (10) before the start of the cleaning. or the cleaning device (10) is set to the electrical potential of the charging device (5). A method according to claim 10, characterized in that the potential equalization during the approach of the spray device (1) to the cleaning device (10) or at least before the introduction of the spray device in the cleaning device (10). A method according to claim 10 or 11, characterized in that the charging device (5) is grounded while the spray device (1) is moved to or into the cleaning device (10) or is in the cleaning device (10), and that the high voltage generator (HS) remains switched on during grounding. A method according to claim 12, characterized in that before or during grounding when the high voltage generator (HS) whose output voltage is controlled by reducing a voltage setpoint to zero or a low voltage value. Method according to one of claims 10 to 13, characterized in that the approach of the spray device (1) to the cleaning device (10) is monitored and reported by a sensor. A method according to claim 14, characterized in that the proximity sensor generates a signal as soon as the spray device (1) on its way to the cleaning device (10) falls below a safety distance from the cleaning device, depending on the electrical insulation between the high voltage potential of the Spacing device (1) and ground potential in air is determined by the distance traveled by the spray device (1) during the time required for the signal of the proximity sensor and for the grounding or potential equalization. Method according to one of claims 10 to 15, characterized in that the charging device (5) of the spray device (Z) is grounded before the start of cleaning by a connected automatically controlled switch (ES). Method according to one of claims 10 to 16, characterized in that the spray device is grounded by the cleaning device (10). Method according to one of claims 10 to 17, characterized in that the spraying device (1) is brought from the coating machine or the handling machine to a grounded contact arrangement of the cleaning device with which the charging device (5) of the spraying device is electrically connected. Method according to one of claims 1 to 18 or according to the preamble of claim 1, wherein the spraying device is to be supplied to the cleaning device (10) from the coating or handling machine along a direction predetermined by a motion control program of the machine is characterized in that an alarm signal is generated and / or the machine is brought to a standstill when the spray device (1) the cleaning device (10) from a direction different from the predetermined direction approaching. A method according to claim 19, characterized in that by a control program for the machine in the vicinity of the cleaning device (10) a limited space is defined, which is blocked by this control program for the movement of the spray device (1), if they are from another as the given direction approaches. Cleaning device for cleaning a spraying device used for automatic series coating of workpieces with an interior space (12) into which the spraying device (1) with its part to be cleaned can be inserted,
characterized in that in the cleaning device (10) a discharge device (30) for collecting and discharging a sprayed from the spray head (3) of the cleaning device (10) introduced spray device (1) medium is arranged. Cleaning device according to claim 21, characterized in that the discharge device in the interior (12) of the cleaning device (10) arranged inner tube body (30), in the open input end (31), the medium of the spray device (1) is sprayed. Cleaning device according to claim 22, characterized in that the inner tube body (30) concentric with an insertion opening (13) of the cleaning device (10), in which the spray device (1) is inserted, is arranged such that the spray head (3) on or in the input end (31) of the inner tube body (30). Cleaning device according to claim 22 or 23, characterized in that the inner tube body (30) opens at an end opposite to the input end (31) in the interior of the cleaning device (10). Cleaning device according to claim 22 or 23, characterized in that the inner tube body (30) outside the cleaning device (10) opens. Cleaning device according to one of claims 21 to 25, characterized in that in the interior (21) of the cleaning device (10) nozzles (21, 23) are arranged, which to a feed line arrangement (20, 22) for a cleaning medium and / or compressed gas connected and directed to the outside of the spray device used (1). Cleaning device according to claim 26, characterized in that the nozzles (21, 23) are arranged on a ring arrangement (20, 22) which is arranged at least approximately concentrically with the longitudinal or rotational axis of the spray device (1) and which contains part of the feed line arrangement. Cleaning device according to claim 26 or 27, characterized in that the nozzles (21, 23) in the inner space (12) are arranged fixed. Cleaning device according to one of claims 26 to 28, characterized in that a heating device for heating the cleaning medium and / or the compressed gas is provided. Cleaning device according to one of claims 26 to 29, characterized in that compressed gas nozzles are provided, which are connected to a leading into the cleaning device compressed gas line are and suck by the compressed gas flow air from the vicinity of the nozzle. Cleaning device according to one of claims 21 to 30, characterized in that at the insertion opening (13) of the interior (12) of the cleaning device (10) into which the spraying device (1) is inserted with its part to be cleaned, a ring around the Injection opening (13) extending nozzle assembly (16) is provided, which forms a pneumatic seal between the peripheral edge of the insertion opening (13) and the circumference of the inserted part (2) of the spray device (1). Cleaning device according to one of claims 21 to 31, characterized in that it is connected to an electrical grounding line or can be connected and is provided with a contact arrangement for grounding the spray device used. Cleaning device according to one of claims 21 to 31, characterized in that it is connected or connectable to a high voltage electrical line, with which it is placed on the high voltage potential of an electrostatic spray device. Coating installation with a device for cleaning a machine device for automatic series coating of workpieces (1), wherein the spray device contaminated by the coating material is introduced by the coating machine or another automatically controlled handling machine with its part to be cleaned in the interior of the cleaning device (10),
characterized in that the spray head (3) of the spray device (1) in the cleaning device (10) by a cleaning medium is cleaned, which is coming from the inside of the spray device (1) coming through the nozzle assembly and / or on the outside of the spray head (3),
and that the medium sprayed from the spray head (3) in the cleaning device (10) is sprayed into a discharge device (30) provided inside the cleaning device, which prevents the sprayed medium from leaving areas of the interior (12) lying outside the discharge device (30). of the cleaning device (10) and / or the outside of the spray device (1).

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