EP0455107A2 - Method and installation for coating work pieces in series with a conductive coating product - Google Patents

Abstract

In an installation for electrostatically coating workpieces with electrically conductive coating material, an earthed supply system (1) and an intermediate container (B) to which a high voltage is constantly applied and which is connected to a spray device are continuously insulated from one another by a further intermediate container (A). The insulation distances between the insulating intermediate container (A) and the earthed supply system or the intermediate container (B) to which high voltage is supplied are smaller than the flash-over width of the applied high voltage, which is possible by virtue of the fact that after the respective intermediate containers (A, B) are filled, insulating shells are rotated into the respective distances. <IMAGE>

Description

The invention relates to a method and a system according to the preamble of claims 1 and 8, respectively.

In conventional electrostatic coating systems, such as those used in particular for painting vehicle body shells, the spray head of rotary atomizers or the like is connected to high voltage in order to thereby generate the sprayed coating particles between the spray head and the grounded object to be coated. The problem arises here that when using a coating material with high electrical conductivity, such as the environmentally friendly water-soluble paints, the insulation resistance via the line connecting the spray head to the paint supply system is too low if the supply system is at ground potential. The supply system, which usually consists of ring lines for the individual colors, is to be grounded, since otherwise not only would considerable expenditure of insulation be required, but also the danger of explosive discharges would exist due to the large electrical capacity.

In a coating system for electrically conductive materials known from DE-OS 30 14 221, a separate storage container is provided for each color, which is arranged insulated from earth and from the other containers and via a color changer and a connecting line which is at high voltage potential horizontal spray device feeds. After the coating operation has ended, the connecting line is flushed with a given color and before changing to another color with solvent (water) and dried with compressed air in order to maintain the required insulation for the container which is subsequently connected to the spraying device. Especially with a large number of selectable colors and corresponding containers, this system is structurally complex and bulky. There are also color losses when emptying and flushing the insulating lines and the need to dispose of the flushing agent. The same problem occurs with a method known from DE-OS 37 17 929, in which the color changer of an earthed supply system leads to an intermediate container and from there leads to the spraying device for electrical insulation and is dried.

This problem is partially avoided in a system known from DE-PS 29 00 660, in which the coating material from an earthed ring line first passes into an insulated first intermediate container and then from this into a second intermediate container, the output of which is constantly at a high voltage lying spray device is connected. By means of a sufficiently large distance and expediently movable connecting pipes or by moving the first intermediate container up and down, the contents of the first intermediate container are electrically insulated from the second intermediate container and when the second intermediate container, which is connected to high voltage, is filled, the first intermediate container is isolated from the grounded storage system. The first intermediate container is electrically charged before emptying into the second intermediate container in order to avoid voltage flashovers. However, the known system is structurally complex and very bulky because of the distances of the first intermediate container from the supply system and from the second intermediate container that are necessary for insulation.

Based on the system known from DE-PS 29 00 660, the invention has for its object to provide a method and a system that require less space and allow in the case of a large number of selectable coating materials of different colors, the intermediate container required for this can be combined into a compact unit in the smallest of spaces.

This object is achieved by the method characterized in claim 1 or by the system characterized in the further claims.

According to the invention, the spatial distances between the intermediate containers from one another and from the supply system can be significantly reduced by the described insulating means, which in the simplest case consist of a rotatable container.

The invention not only has the advantage of taking up little space and requiring little construction, it also enables low operating currents. Even if the insulation distances between the first intermediate container and the supply system or the second container are so large that no flashover occurs, in the known case there is the possibility of a charge exchange by ionization in the insulation zone. This possibility is prevented by the insulating walls of the intermediate containers.

It is also important that the high voltage does not have to be switched off during the coating operation, since the spray device is always isolated from the supply system during operation, either between the two intermediate containers or between the first intermediate container and the outlet opening of the supply system. This is achieved according to the invention without the previous need to maintain or set a distance between the intermediate containers and the supply system which is greater than the flashover distance of the high voltage applied.

Fig. 1

eine Anlage mit zwei Zwischenbehältern gemäß einem ersten Ausführungsbeispiel;

Fig. 2

eine Anlage gemäß einem zweiten Ausführungsbeispiel;

Fig. 3

eine Anlage gemäß einem dritten Ausführungsbeispiel;

Fig. 4

eine schrägbildliche Ansicht einer Anlage für eine Vielzahl verschiedenfarbiger Beschichtungsmaterialien; und

Fig. 5

eine besondere Ausführungsform des zweiten Zwischenbehälters.

The invention is explained in more detail using various exemplary embodiments. In the drawing show schematically

Fig. 1

a system with two intermediate containers according to a first embodiment;

Fig. 2

a system according to a second embodiment;

Fig. 3

a system according to a third embodiment;

Fig. 4

an oblique view of a system for a variety of different colored coating materials; and

Fig. 5

a special embodiment of the second intermediate container.

1 shows two intermediate containers A and B connected between an earthed supply system, of which only one outlet pipe 1 is shown, and an electrostatically operating spray device (not shown). The intermediate containers A and B each consist of an elongated hollow cylinder, the circular cylindrical outer wall 2 or 3 (outer shell) of insulating material of a thickness sufficient for electrical insulation in this embodiment. These cylinders forming the intermediate containers are each divided in their longitudinal direction by transverse walls into a number of partial containers corresponding to the number of selectable coating materials of different colors (as shown in FIG. 4 for another exemplary embodiment). In the embodiment shown in FIG. 1, both intermediate containers A and B are immovably mounted. They lie with their longitudinal axes horizontally parallel to one another and to a row of outlet pipes 1 corresponding to the number of selectable colors, the two intermediate containers A and B being vertically one above the other are arranged and the vertical longitudinal axis of the exhaust pipe 1 intersects both cylinder axes.

Each sub-container of the intermediate container A has at its upper end an inlet opening 4, for example designed as a valve, which lies on the longitudinal axis of the outlet pipe 1, and at the lower end also an outlet opening 5 also designed as a valve. Each sub-container of the second intermediate container B has at its upper end an inlet opening 6, for example in the form of a valve, which lies axially below the outlet opening 5.

The entire intermediate container A is concentrically enclosed by a likewise cylindrical insulating shell 7 of sufficiently thick insulating material, which is circular in cross section and which can be rotated by at least 180 °, for example by 360 °, about the horizontal longitudinal axis relative to the intermediate container A in accordance with the arrows shown. The insulating shell 7 contains an opening 8 at the positions corresponding to the inlet openings 4 of the various partial containers in the horizontal direction. In the position of the rotatable insulating shell 7 shown, its opening 8 is located exactly between the mouth of the outlet pipe 1 and the inlet opening 4 of the intermediate container A.

The second intermediate container B is also concentrically surrounded over its entire length by an insulating shell 9 which, according to the arrows shown, can be rotated in two directions relative to the intermediate container B about its longitudinal axis, for example by 90 °. The insulating shell 9 only has to be partially cylindrical, so that it covers the opening 6 and can be pivoted away from it. The intermediate container B has permanent line connections (not shown) to the spraying device.

A distance which improves the insulation is maintained between the insulating shells 7, 9 and the associated containers A, B. The insulating shells can also be arranged so that they serve as a cover for the openings and prevent loss of solvent and drying of the paint, especially when the inlet and outlet openings of the containers do not contain any valves.

The operation of the system shown is known in principle (cf. DE-PS 29 00 660). Accordingly, the outlet pipe 1 is constantly at low or earth potential, while the content of the intermediate container B is constantly connected to the high voltage of the spraying device and the potential of the intermediate container A changes cyclically between high voltage and earth potential. When the intermediate container A is filled by the supply system, its contents are grounded and isolated from the contents of the intermediate container B. Before and during the intermediate container A is emptied into the intermediate container B, the contents of the intermediate container A, on the other hand, are set to high voltage and isolated from the grounded supply system. While the intermediate container B is then emptied to the spray device, the intermediate container A can be filled again.

In contrast to the known system, the required insulation is not achieved by a spatial distance that is greater than the respective flashover width of the high voltage, but by the insulating material of the container walls and by the insulating shells 7 and 9. This allows the distance between the mouth of the outlet pipe 1 and the liquid in the intermediate container A and the distance between the outlet opening 5 and the liquid in the intermediate container B, between which an electrical flashover distance would otherwise exist, would be smaller than the respective electrical flashover distance.

As shown, when filling the intermediate container A, the opening 8 of the insulating shell 7 is located between the outlet pipe 1 and the inlet opening 4, while the insulating shell 7 covers the outlet opening 5 against the inlet opening 6 of the intermediate container B. For additional insulation, the insulating shell 9 is simultaneously located above the inlet opening 6.

Before the intermediate container A is then emptied into the intermediate container B, it is connected to high voltage, and its inlet opening 4 is covered by the insulating shell 7 against the earthed outlet pipe 1, while the opening 8 of the insulating shell 7 now clears the way below the outlet opening 5 ( as indicated by dashed lines in the drawing). At the same time, the insulating shell 9 is turned away from the inlet opening 6 (as is also indicated by dashed lines). These processes are repeated cyclically according to the material consumption.

The cyclical switching between filling and emptying the containers is not time-critical. The containers and / or insulating shells can be rotated quickly and easily, even while the coating material is being sprayed, without having to rely on coating breaks. This also results in the possibility of a single common intermediate container arrangement (per color) for all connected atomizers, e.g. to be used for all "levels" consisting of several atomizers in one spray booth.

The exemplary embodiment according to FIG. 2 differs from that according to FIG. 1 only in that the intermediate container A is rotatable and has only one opening 14, which is designed as a valve and serves alternately as an inlet opening and outlet opening, and in that the insulating shell 17 of the intermediate container A is similarly partially cylindrical is like the insulating shell 9 of the intermediate container B. If the intermediate container A is filled through the opening 14, the insulating shell 17 is rotated here by 180 ° to the lower end of the intermediate container A, where it lies between the two containers as well as the insulating shell 9. Zum Will drain the intermediate container A is then rotated by 180 ° so that its opening 14 is aligned with the inlet opening 6 of the intermediate container B, while the insulating shells 17 and 9 are rotated into the positions shown in broken lines, in which the insulating shell 17 interrupts the rollover distance to the outlet pipe 1 and the insulating shell 9 clears the way to the inlet opening 6.

Rotatable intermediate containers have the additional advantage that they can be moved continuously or periodically during operation and also during breaks in order to prevent paint from depositing on the inside of the containers. This eliminates the need to prevent settling, for example by pumping, as was previously the case with comparable systems.

With the exception of their openings for the inlet and outlet of the coating material (and possibly of air), the intermediate containers A and B are preferably completely closed insulating cylinders. However, they do not have to be circular-cylindrical as in the previously described exemplary embodiments, but they can also have expedient other cross-sectional shapes. In the embodiment shown in Fig. 3, a rotatable Zwischenbe container A is approximately pear-shaped in cross-section, that is higher than wide, the widest part when filling the container is below and the height dimension along the axis of the outlet tube 1 and an opening 18 which is designed as a valve and, as in FIG. 2, serves alternately as inlet and outlet. The cross-sectional shape shown increases the insulation distances without taking up a lot of space.

3 differs from those according to FIGS. 1 and 2 in that there are no separately rotatable insulating shells. Instead is just an attached to the intermediate container A, the round bottom surrounding insulating shell 19 is provided. When the intermediate container A is filled, the insulating shell 19 thus covers the inlet opening 6 of the lower intermediate container B, while covering the mouth of the outlet pipe 1 when the intermediate container A is emptied.

FIG. 4 shows the shape and arrangement of intermediate containers A and B essentially in accordance with FIG. 3 in an oblique representation, the separate insulating shells 19 being omitted for simplification. In the other exemplary embodiments, too, the separate insulating shells are not always absolutely necessary. As can be seen from Fig. 4, except for the openings 18 and 6 completely closed containers A and B are elongated cylinders with a circular, pear-shaped or other cross-section, horizontally with a small distance above one another in a common frame structure below the outlet pipes 1 for the different Colors are stored. Since the intermediate container B is always at high voltage potential, the bearing structure 20 is designed to be insulating.

Instead of an intermediate container in the form of an elongated cylinder with intermediate walls, cylindrical individual containers can also be provided for the different colors, which can be arranged vertically parallel to one another and firmly connected to one another.

The second intermediate container B for the spraying device can be emptied in a manner known per se, not shown, with gear pumps, paint pressure regulators, piston pumps, etc.

5, however, there is also the possibility of emptying by acting on the intermediate container B with compressed air.

In this case the intermediate container is separated by e.g. horizontally lying partition 22 divided into two chambers B1, B2, which are connected by a valve 23. The upper chamber B1 has an inlet opening 26 in the form of a valve, while the lower chamber B2 has an outlet opening 27 in the form of a valve which is connected to the spray device 29 via a line 28. A compressed air line 30 or 31 with a valve is connected to each of the two chambers.

First, when the compressed air valves are closed, both chambers B1 and B2 can be filled through the inlet opening 26 and the valve 23. You can also fill chamber B1 first and then empty it into chamber B2 using compressed air. The chamber B2 is emptied through the compressed air line 31 when the valve 23 is closed. The supply in the chamber B2 can be continuously supplemented according to consumption.

A return line 32 leading from the line 28 back into the chamber B1 is expediently provided with a valve 33, as a result of which the settling and drying of paint can be avoided. A vent line 34 with a valve 35 is also provided.

The illustrated embodiments can be modified in various respects, and in particular individual features of the different exemplary embodiments can be combined with one another.

The arrangement described with small distances between the intermediate container A and the outlet pipe 1 of the supply system on the one hand and the intermediate container B on the other hand has the advantage of small "fall distances", so that no significant foaming of the coating material is to be feared.

However, there is also the possibility of installing suitable detachable line couplings between the various openings and / or, for example, of designing the outlet pipe 1 in such a way that it can be immersed through the inlet opening for filling the intermediate container A.

In addition, there is the possibility of pivoting separate insulating shells around the container axis, rather about its own, different axis, into the section to be insulated, or to push them linearly into this section.

If the second intermediate container can be pressurized, there is also the possibility, during breaks in operation, of the line connected to it and leading to the coating device, e.g. to apply a periodically changing container pressure to the line 28 in FIG. 5 in order to keep the coating material in the line uniformly viscous and to prevent it from settling.

Claims (16)

Process for the serial electrostatic coating of workpieces with electrically conductive coating material, in which the coating material first reaches a first intermediate container (A), which is isolated from the supply system, from a supply system which is at low potential or earth potential, then from the first intermediate container (A) to one of reaches this and the second intermediate container (B), which is insulated from the supply system, and is finally fed from the second intermediate container (B) to a spray device at high voltage potential,
the content of the second intermediate container (B) being permanently connected to the spray device in an electrically conductive manner,
the contents of the first intermediate container (A) are set to the high-voltage potential when emptied into the second intermediate container (B), but are at their potential when filled by the supply system,
and the contents of the first intermediate container (A) are electrically insulated against an inlet opening of the second intermediate container (B) when the first intermediate container (A) is filled and against an outlet opening of the supply system when the second intermediate container (B) is filled,
characterized by
that at least one of the intermediate containers (A, B) is filled through an opening (4,6,8,14,18) or recess of an insulating shell (2,7,9,17,19) forming or at least partially surrounding the container, which is moved for insulation after filling so that there is a closed piece of the insulating shell in the way through which the coating material was fed. A method according to claim 1, characterized in that the insulating shell (2,7, etc.) is rotated about an axis for insulation. Method according to claim 1 or 2, characterized in that an opening (8) of an insulating shell (7) completely surrounding the first intermediate container (A) when filling the first intermediate container between an inlet opening (4) of the first intermediate container and the outlet opening (1) of the Supply system and after the rotation of the insulating shell (7) between an outlet opening (5) of the first intermediate container (A) and an inlet opening (6) of the second intermediate container (B). Method according to one of the preceding claims, characterized in that an inlet opening (6) of the intermediate container (A, B) is covered by an insulating shell (9) of the container after it has been filled. Method according to one of the preceding claims, characterized in that at least the first intermediate container (A) is rotated for insulation. Method according to claim 5, characterized in that the intermediate container (A) is rotated through 180 °. Method according to one of the preceding claims, characterized in that the second intermediate container (B) is emptied by compressed air. System for carrying out the method for the series electrostatic coating of workpieces with electrically conductive coating material according to one of the preceding claims, with
a supply system that is at low potential or earth potential,
a first intermediate container (A) isolated from the supply system and having an opening (4, 14, 18) through which the coating material can be fed to it from an outlet opening (1) of the supply system,
a second intermediate container (B) which is isolated from the first intermediate container (A) and the supply system and has an opening (6) through which the coating material can be fed from an opening (5, 14, 18) of the first intermediate container (A),
and a high-voltage spray device (29) to which the coating material can be fed from the second intermediate container (B),
characterized by
that the spatial distance of the contents of the first intermediate container (A) from the outlet opening (1) of the supply system and / or from the contents of the second intermediate container (B) is equal to or less than the flashover distance of the high voltage applied and when filling and emptying the two intermediate containers (A, B) remains small,
and that at least one insulating shell (7, 9, 2) can be moved into the rollover path between the first intermediate container (A) and the outlet opening (1) of the supply system and / or an inlet opening (6) of the second intermediate container (B). System according to claim 8, characterized in that the insulating shell consists of the wall (2) of the intermediate container (A). System according to Claim 8 or 9, characterized in that an insulating shell (7, 9, 17) which can be moved around the intermediate container (A, B) is provided. System according to one of claims 8 to 10, characterized in that the insulating shell (7,9,17,2) is rotatable about a horizontal axis. System according to one of claims 8 to 11, characterized in that the first and / or second intermediate container (A, B) is cylindrical or similar to a cylinder and the insulating shell (7,9,17,19) is at least partially cylindrical. System according to one of Claims 8 to 12, characterized in that at least one of the intermediate containers (A) is larger than it is wide in cross section (Fig. 3). Installation according to one of Claims 8 to 13, characterized in that the second intermediate container (B) is divided into two chambers (B1, B2) by a partition (22) which contains a connecting valve (23), one of which is a chamber (B1) has an inlet opening (26) and the other chamber (B2) has an outlet opening (27) connected to the spraying device (29), and that a compressed air line (30, 31) is connected to both chambers (B1, B2). System according to one of Claims 8 to 14 for a large number of selectable coating materials of different colors, characterized in that each intermediate container (A, B) consists of a plurality of partial containers each assigned to a color and separated from one another by partition walls and forming a structural unit, and the two intermediate containers (A, B) are arranged parallel to one another and to a row corresponding to a large number of outlet openings (1) of the supply system. System according to one of Claims 8 to 15, characterized in that one or both intermediate containers (A, B), with the exception of inlet and / or outlet openings (4, 5, 6), are completely closed, cylinder-like containers made of insulating material.

Images