DE3318043C2 - - Google Patents

Description

The invention relates to a spray booth for coating Objects with a powder coating spray material with the in the preamble of claim 1 led characteristics.

It is known (DOS 31 35 898) in the spray room of one Spray booth to provide a constant vacuum by by a suction pump (blower, fan or the like) via a filter provided in the upper area of the cabin Air is extracted. This well-known spray booth is like this met that a large part of the to be coated Object of unsuspended spray material drops to the floor and can be recovered there. For this purpose, at the known spray booth in front of the filter a baffle arranged, which prevents the spray material directly  can be sprayed onto the filter. However, with that Exhaust airflow a rest of the spray material to the filter is pulled and this filter can clog, becomes perio A short pulse of air in counter from the suction chamber Direction to normal suction air flow on the filter blow and the filter cleaned. With this be Known establishment, it is still relatively difficult Convert furnishings to other colors. With one color As is well known, even slight traces of color are sufficient for the changes replaced color to incorrectly change the new color do.

The invention has for its object a device to create that is easy and quick to clean and at which is therefore almost no undesirable when changing colors Color residues remain.

This task is carried out by the in the patent claim 1 described invention solved.

In contrast to the known known Solution of the suction air flow designed so that it in the spray room no noticeable air flow causing a distortion spray material could cause. In addition, the Clean the filter continuously, so not pulse-shaped. Finally, the filter forms one vertical wall of the spray room, which is easily replaceable is designed and no additional constriction of the spray room represents. The floor of the spray room is so out forms that it is easily accessible for cleaning purposes.

Further developments of the invention are in the subclaims described.

To explain the invention in more detail below several embodiments with reference to the drawings wrote. These show in

Fig. 1 is a schematic representation of the device according to the invention,

Fig. 2 shows a detail of the opening for replacement of the filter,

Fig. 3 shows the construction of the nozzle holder,

Fig. 4 is a diagram of the exchangeable Auffangbe hälters,

Fig. 5 two cabins assembled into a unit according to the figure.

Fig. 1 shows a device for the electrostatic loading of objects G in a cabin 1 with a spray gun 2 , which sprays a powder coating spray material from a built-in and / or a separate reservoir 3 under pressure in the direction of the object G. So that the coating spray material cannot escape from the cabin 1 due to the required spray pressure, a vacuum is generated in the cabin 1 by means of a suction pump 4 (blower, fan or the like). As a result of the electrostatic field between spray gun 2 and object G , the electrically charged powdery spray material is deposited on objects G and coats them. The non-deposited material partly sinks to the ground due to its own weight and is collected there, as well as unloaded through the ground's potential. Another part of the spray material is sucked in by the suction pump 4 . In order to avoid that this part of the spray material is distributed by the suction pump 4 in the room outside the cabin 1 , the rear wall of the spray chamber 7 of the cabin 1 is closed by a filter 5 , which essentially forms the whole wall and between its edges and the cabin wall has such a seal 6 that no spray material can bypass the filter 5 to the suction pump 4 . The cabin is thus divided into a spray room 7 and a suction room 8 . On the side of the filter 5 facing away from the spray chamber 7 , that is to say in the suction chamber 8 , a blowing device 9 is arranged with at least one nozzle 10 which constantly blows during operation, which blows a fraction of the filter 5 from the rear side and which continuously extends over the surface of the Filters 5 is guided to reach and blow on each part of the filter surface. The pressure of the filter 5 blowing air flow is dimensioned so that the spray material caught and held by the filter 5 dissolves again and sinks down by its own weight. The air flow must not be so great that the spray material affects the uniformity of the spray order on the object G. The spray material collected on the floor of the cabin 1 is reprocessed and used again. A collecting container 13 is arranged under the floor of the cabin 1 . This collecting container is preferably provided with means for processing the collected spray material and enables constant supply of the collected spray material to the spray gun 2 , so that the supply of spray material required for the coating can be kept relatively low.

In devices in which the nozzle jet has to be dimensioned so strongly that the coating of the object is impaired by the constant effectiveness of the nozzle jet, a catch plate 12 which is moved synchronously with the nozzle holder 11 is provided on the spray chamber side of the filter 5 and extends over the whole vertical dimension of the filter 5 he stretches and is so wide that no swirl is caused by the jet.

The filter 5 is designed in such a way that it can bring about a vacuum in the spray chamber 7 from the suction chamber 8 without impairing the spraying process itself. For this purpose, the filter is large and practically designed as a vertical back wall. Therefore, if there is any air flow at all, it is approximately horizontally, ie perpendicular to the filter, directed and evenly distributed over the entire area of the surface 5 . In addition to the large area of the filter, a nonwoven material has proven itself to solve this task. In order to make this material more resistant to loads, the nonwoven material is deposited on the side of the suction space 8 with a grid, the surface of which facing the nonwoven is kept very small. In one embodiment, the grid is incorporated into the nonwoven material. To increase the stability, the filter 5 is made from a frame 18 with a fleece attached to it. This creates an interchangeable unit that is easy to handle, can be replaced quickly and easily and, in addition to being permanently cleaned inside the spray room, can also be easily prepared for a color change by additionally cleaning it outside the cabin 1 with a vacuum cleaner. Such extreme cleaning can be dispensed with if the device is assigned a set of filters in which a replaceable filter is provided for each color.

Fig. 2 shows the outer wall of the cabin 1 with an opening 19 through which the frame 18 with the filter 5 can be inserted or removed. In the example shown, the frame is inserted so that the vertical edge of the frame 18 facing the opening is visible, together with the seals 6 at the upper and lower ends of the frame edge. The opening 19 can be closed by a flap 21 , which is shown open in FIG. 2, a fold-out support 25 being provided at the open end of the flap and holding the flap 21 in an approximately horizontal position. The frame 18 can thus be pulled from the seal 6 directly into the horizontal guide 26 in the flap 21 and removed there. In the closed state of the flap 21 , this guide also presses on the seal for the vertical frame part 18 and thereby makes this device effective. Before commissioning the entire device, the flap 21 is attached, for example by a quick-release lever. Also in the interior of the spray chamber 7 and / or from the suction chamber 8 , fasteners, for example quick release levers, are provided. To attach the frame parts inside the device, eccentric levers can be used, which are operated by rotating a corresponding shaft from the side of the opening 19 , for example rotated. Furthermore, these levers can be operated electrically, pneumatically or hydraulically. In addition to the seal 6 , the opening can also be provided with a brush seal, not shown, which brings about an additional cleaning of the filter when the filter 5 is pulled out.

Fig. 3 shows the construction of the nozzle holder 11 and the associated movement device. At the upper end of the filter 5 , a threaded rod 14 is arranged on both sides, which is rotated by a motor 15 directly or via a gear. On the threaded rod 14 , a bushing 27 with the nozzle holder 11 attached is arranged so that it moves from one end to the other end when the threaded rod 14 rotates. The speed depends on the speed of the motor, the direction of rotation of the direction of rotation of the threaded rod 14 . The direction of rotation can be effected either by electrical switching of the direction of rotation of the motor 15 or by mechanical switching of the transmission, which in turn is triggered by limit switches. The motor 15 is preferably a type with a large variation range of the rotational speed in order to be able to adapt the speed of the nozzle holder 11 to the spraying speed of the spray gun or to the respective spray quantity.

In the nozzle holder 11 , a pneumatic or hydraulic device 17 is attached with a lifting rod 16 or a chain, rope or other drive device. On the lifting rod 16 one or more nozzles 10 are attached, which are moved up and down with the lifting rod 16 by the pneumatic or hydraulic cylinder 17 . Pneumatic or hydraulic cylinders 17 and nozzles 10 are supplied with compressed air by a common compressor, the individual supply lines 28 , 29 , 30 being able to be set as required. It is also possible to derive the supply lines 28 , 29 , 30 and, if appropriate, further supply lines from a distributor (not shown) in which the quantity of air metered to each supply line automatically varies by a process computer depending on the spray speed, spray quantity, number of nozzles, number of spray guns, suction power and filter material becomes. The opening of the nozzles 10 can be dimensioned very small and the required area coverage can be achieved by high speed of movement of the nozzle holder 11 and the nozzles 10 . But it is also possible to dimension the nozzle cross-section somewhat larger, for example in the form of a flat jet nozzle, and to reduce the speed accordingly.

In Fig. 4 the basic construction of the collecting container 13 and the associated collecting devices of the spray chamber 7 is shown. The bottom of the spray chamber 7 is formed over most of its area by an inclined metal plate which ends at its lowest point above an opening of the mobile collecting container 13 . Similarly, the plane of the filter 5 lies above the opening of the collecting container 13 or the lower end of the filter 5 is connected to the collecting container 13 via a slideway. In FIG. 4, to simplify the illustration, the collecting container 13 is so long that it extends over the entire width of the spray chamber 7 or over the entire length of the filter 5 . The effectiveness of the spray material - to improve recovery plant, shorter containers are desirable. The bottom surface of the spray chamber 7 can therefore have a surface shaped in such a way that the entire spray material that comes to the bottom moves to a relatively small bottom opening, which is located above a small, but optimized for the spray material circuit, container. The opening and thus the container 13 are arranged on the part of the cabin 1 which is accessible from the outside. The containers 3 and 13 can be formed by a single container.

The filter 5 essentially retains all spray material particles that want to move towards the suction space. In order to meet the regulations regarding the purity of the air emitted by the suction pump to the outside, 8 additional cartridge filters with an effective filter area of approximately 10 m ² are arranged in the suction space, through which the suction air reaches the pump. In a further development of the system shown in FIG. 1, another filter 31 of the structure of the filter 5 was inserted with great success into the suction space behind the nozzle holder 11 . With such an arrangement, both optimal material recovery and optimal air purity could be achieved in a simple manner. A replacement opening can also be provided in the cabin 1 for the second filter. Since relatively little material is obtained with this second filter, neither a blowing device nor a frequent replacement is required.

The suction chamber 8 is a sealed door 32 is suitably assigned to wait for the suction chamber 8 and the parts therein.

The horizontal movement of the nozzles 10 can also be carried out by pneumatic means. If a catch plate 12 is used, the associated drive means, for example a threaded rod similar to the rod 14 , are arranged above the cabin roof and the catch plate holder is connected to it by a preferably flexibly sealed slot in the cab roof.

In a practical embodiment, a fan of approximately 6000 m ³ / h was used, which caused a suction pressure of approximately 0.5 m / s at the openings of the spray chamber 7 . The pressure of the nozzles 10 was measured at 2 to 3 bar. The effect of the nozzles 10 is increased if they are surrounded by a box which covers the suction pressure of the fan in the area of the filter 5 points just blown by the nozzles 10 .

In special cases, for example test coatings or with smaller objects G , it may be sufficient if the filter 5 forms only part of the rear wall of the spray chamber 7 . For large areas, several nozzles 10 can be arranged horizontally offset.

Fig. 5 shows a spraying system for the coating on opposite sides of objects G running through a cabin 1 . For this purpose, the total cabin 1 consists of two assembled part cabins 1 a and 1 b are formed, which are mutually offset by 180 °. The objects G thus first reach the first cabin 1 a and are sprayed by the spray gun 2 a . The filter 5 a for collecting the particles not adhering to the object is arranged as in FIG. 1 and can be removed on the side of the cabin. The objects G then enter a spray chamber 7 b , the spray gun 2 b of which is arranged on the opposite side and thus sprays the back of the object. Here too, the filter 5 b is arranged similarly to FIG. 1 and can be removed from the side. The two cabins 1 a and 1 b can be combined into one cabin. But they can also be placed side by side so that they perform the function of a unit without being mechanically connected. In a similar way, a single suction fan can also be provided for both cabins 1 a and 1 b , which ensures negative pressure in the separate suction spaces 8 a and 8 b and thus in the two spray spaces 7 a and 7 b .

The coating of two opposite surfaces of an object can also be achieved with a turning bracket in a single cabin 1 . Such Wendehal tion can also be designed so that it carries out a continuous or stepwise rotation. When program control by means of a process computer, the spray gun 2 and the turning bracket can be controlled so that their spray quantity and spray type as well as the turning movement are coordinated.

Since the filter 5 acts like a rear wall of the spray chamber 7 , it can be used advantageously in existing systems by removing the rear wall there and replacing it with the filter 5 . It is then only necessary to add the suction chamber 8 with the associated movable nozzles 10 .

Claims (24)

1. spray booth for coating objects ( G ) with a powder coating spray material by means of a fixed or movable, to the object ( G ) to be coated or directed spray gun ( 2 ) and with a flat filter ( 5 ) for air purification, which at the same time can be used to recover the spray material not adhering to the object, with a suction pump ( 4 ) behind the filter ( 5 ) for generating a negative pressure in the cabin ( 1 ), the filter ( 5 ) being sealed against the cabin wall (6) that it separates the spray chamber ( 7 ) from the suction chamber ( 8 ) and the filter ( 5 ) for detaching the spray material collected by the filter ( 5 ) can be blown from the suction chamber ( 8 ) by means of a blowing device ( 9 ), and with a collecting container ( 13 ) for the spray material which has sunk downward due to its own weight, characterized in that the filter ( 5 ) forms the rear wall of the spray space ( 7 ) of the cabin ( 1 ), and that the blowing device ( 9 ) contains at least one nozzle ( 10 ) which can be moved continuously over the surface of the filter ( 5 ) on the side of the filter ( 5 ) facing away from the spray gun ( 2 ) and thus essentially every point of the filter ( 5 ) can blow. 2. Spray booth according to claim 1, characterized in that the strength of the air flow with which the filter ( 5 ) is blown is dimensioned such that the spray material collected by the filter ( 5 ) against the holding effect of the continuously working suction pump of the The filter surface loosens and sinks down due to its own weight. 3. Spray booth according to claim 2, characterized in that the nozzle ( 10 ) is part of a nozzle holder ( 11 ), that the nozzle holder ( 11 ) is continuously moved in a horizontal direction over the surface of the filter ( 5 ) back and forth, and that the nozzle ( 10 ) in the nozzle holder ( 11 ) is movable up and down. 4. Spray booth according to claim 1, 2 or 3, characterized in that a catch plate ( 12 ) is provided on the spray chamber side of the filter ( 5 ), which extends in the vertical direction over the filter ( 5 ) and somewhat wider in the horizontal direction is dimensioned as the effective range of the nozzles, the movement of the nozzles ( 10 ) and the catch plate ( 12 ) being coordinated by suitable control so that the catch plate ( 12 ) covers the nozzles ( 10 ) at every point of the filter ( 5 ). 5. Spray booth according to claim 4, characterized in that the catch plate ( 12 ) is so large that the nozzles ( 10 ) can no longer cause swirling in the spray chamber ( 7 ). 6. Spray booth according to one of claims 1 to 5, characterized in that for the horizontal movement of the nozzle holder ( 11 ) a threaded rod ( 14 ) is provided which is parallel to the upper edge of the filter ( 5 ) over the entire length of the filter ( 5th ) extends and on which the nozzle holder ( 11 ) is held by means of a corresponding threaded bushing, the longitudinal movement of the nozzle holder ( 11 ) being brought about by rotation of the threaded rod by means of a motor ( 15 ). 7. Spray booth according to one of claims 1 to 6, characterized in that for the vertical movement of the nozzles ( 10 ), the nozzle or nozzles ( 10 ) on the lifting rod ( 16 ) of a pressure-controlled pneumatic or hydraulic device ( 17 ) is or are attached , whose stroke range is dimensioned so that each nozzle is moved over the height or a partial height of the filter ( 5 ). 8. Spray booth according to claim 7, characterized in that the lifting rod ( 16 ) is part of a linear cylinder system. 9. Spray booth according to one of claims 1 to 8, characterized in that for the vertical movement of the nozzles ( 10 ), the nozzle holder ( 11 ) is movable by chain, spindle or cable. 10. Spray booth according to one of claims 1 to 9, characterized in that the filter ( 5 ) is fixed to a frame ( 18 ). 11. Spray booth according to claim 9 or 10, characterized in that a stabilizing grid with a small surface is provided on the frame ( 18 ) or in the filter material. 12. Spray booth according to one of claims 10 or 11, characterized in that the frame ( 18 ) with the filter ( 5 ) through an externally accessible bare opening ( 19 ) of the cabin ( 1 ) is interchangeable that the opening ( 19 ) can be closed by a flap ( 21 ) which can be pivoted about a horizontal axis at the lower end of the opening ( 19 ) into a substantially horizontal position and that in this position the flap ( 21 ) is a guide and support for filters ( 5th ) and / or frame ( 18 ). 13. Spray booth according to one of claims 10, 11 or 12, characterized in that the opening ( 19 ) has on its inside brush-like constrictions that strip any remaining material residues when the filter ( 5 ) is pulled out. 14. Spray booth according to one of claims 1 to 13, characterized in that the bottom of the booth 1 is formed so that the spray material collected is continuously fed to a collecting container ( 13 ). 15. Spray booth according to claim 14, characterized in that the collecting container is mobile and replaceable from the outside of the cabin ( 1 ) can be removed. 16. Spray booth according to one of claims 1 to 15, characterized in that the suction pump ( 4 ) with the suction chamber ( 8 ) is connected via an air cleaning filter ( 22 ). 17. Spray booth according to claim 16, characterized in that the air cleaning filter ( 22 ) consists of one or more cartridge filters. 18. Spray booth according to claim 16, characterized in that the air cleaning filter ( 22 ) has the same design as the filter ( 5 ) and how this is replaceable bar. 19. Spray booth according to claim 4, characterized in that the catch plate ( 12 ) is moved by a threaded rod, lifting rod or cable and that the catch plate ( 12 ) communicates with the movement device via a gap in the roof of the suction chamber ( 8 ), wherein the gap is sealed against the passage of spray material, in particular by a brush seal device. 20. Spray booth according to one of claims 1 to 19, characterized in that the bottom of the spray chamber ( 7 ) and / or the filter ( 5 ) is associated with a vibrator, the spray material to the collecting container ( 13 ) tet. 21. Spray booth according to one of claims 10, 11 or 12, characterized in that the filter ( 5 ) is composed of several individual filters, each of which is interchangeable. 22. Spray booth according to one of claims 1 to 21, characterized in that the object ( G ) is rotatably supported. 23. Spray booth according to claim 22, characterized in that that the rotary movement is controllable. 24. Spray booth according to one of claims 1 to 23, characterized characterized that two cabins 180 ° against each other are combined to form a unit.