EP0238031A2 - Device for electrostatically coating objects - Google Patents

Abstract

In the device suitable for the use of so-called water-based paints or another, similarly conductive coating material, the electrical field charging the sprayed particles is generated between the grounded spray edge (6) of a bell atomizer (1) and a larger number of outer electrodes (10), which are integrated into one Ring body (20) made of insulating material are used.

Description

The invention relates to a device according to the preamble of claim 1.

Such a device, for example for coating vehicle body shells, in which, in contrast to conventional systems, instead of the spray head, only one arrangement of external electrodes is placed at high voltage potential, is known to have significant advantages when using highly conductive spray materials, such as so-called water-based paints (see DE-OS 34 29 075). In particular, significant insulation problems are avoided since the entire paint line system can be grounded up to the spray head.

In such a device with external electrodes, however, it is extremely difficult to avoid contamination of the spray device, the electrodes and the electrode holder by the coating material during operation with good application efficiency, which depends on a good charge of the sprayed coating material. Contamination of the electrode area results in a drop in performance, ie lower efficiency, which in turn further increases the tendency towards even greater contamination by the sprayed-off material. For this reason, the device known from DE-OS 34 29 075 should only have two, three or at most four charging electrodes, each in embedded a plastic holder protruding radially from the outer housing of the spray head and projecting axially in the direction of the object to be coated. Each of these holders contains a high-voltage cable leading to its respective electrode and is firmly connected at the rear end to a ring body which is also made of plastic and is placed on the outer housing. Although this design has already proven itself in practice, under certain operating conditions it has not yet been possible to avoid all the difficulties with regard to the risk of contamination mentioned. In addition, if the restriction to a maximum of four outer electrodes is required, there is a risk of uneven "spray patterns" due to a coating concentration in the area of the electrodes.

The invention has for its object to provide a coating device with external electrodes, which avoids contamination of the spraying device and the electrode holder arrangement as far as possible with good application efficiency. A uniform spray pattern should preferably be ensured for the object to be coated.

This object is achieved by the device characterized in claim 1.

The invention is based on the surprising finding that the problems resulting from the use of highly conductive coating materials (as described in the aforementioned DE-OS 34 29 075) also result from the distribution of a relatively large number of charging electrodes Have the spray head detached if there is sufficient mutual insulation between the electrode tips on the outside of the electrode holder. The insulation would be reduced by a substantial precipitation of the conductive coating material on the end face of the ring body forming the electrode holder, which would result in a sudden drop in the field strength at the electrode tips and thus a further increase in contamination. It was found that if the annular electrode holder between the electrode tips was contaminated in an electrically conductive manner, the coating material scarcely or at least irregularly migrated to the object to be coated, but would mainly coat the device itself; the same would apply to the use of a metallic retaining ring body for the electrodes. On the other hand, the risk of contamination of the ring body does not decrease with the mutual spacing of the charging electrodes, on the contrary, a minimum number of electrodes which is dependent on the diameter of the ring body is required (which may be related to the requirement of a sufficient electric field). For example, in the case of a diameter of the circle containing the electrode ends of approximately 400 mm, there should be at least eighteen electrodes, which in this case corresponds to a mutual distance of at most 70 mm, if no special additional measures to prevent contamination are provided.

• Fig. 1 eine Seitenansicht der Vorrichtung in verkleinerter, aber maßstabgetreuer Darstellung;
• Fig. 2 eine Draufsicht auf die Vorrichtung gemäß Fig. 1 , vom zu beschichtenden Gegenstand her gesehen; und
• Fig.3-5 zwei verschiedene Abwandlungen am Ringkörper der Vorrichtung.

The invention is explained in more detail below using an exemplary embodiment shown in the drawing. Show it:

• Figure 1 is a side view of the device in a reduced but true to scale representation.
• FIG. 2 shows a top view of the device according to FIG. 1, seen from the object to be coated; and
• Fig.3-5 two different modifications to the ring body of the device.

1, the device shown contains a spray device in the form of a rotary atomizer 1 of the known bell type, the bell plate 2 forming the spray head of which can preferably be driven by an air turbine at high speed. A line (not shown) that feeds the paint or other coating material from a supply system to the bell cup 2 runs along the axis of the spray device. With this line, which is formed, for example, by an earthed metal tube, the entire conductive coating material, such as water-based paint or the like, is at earth potential up to the spraying edge 6 of the bell cup 2.

The object to be coated (not shown), such as, for example, a part of a vehicle body, which is arranged at an axial distance in front of the bell plate 2, is also at earth potential.

The spray device can have an outer housing 7 made of an insulating plastic.

To charge the coating material sprayed largely radially from the spraying edge 6, 30 needle-shaped charging electrodes 10 are provided in the example shown on a circle concentric to the axis of the spraying device with a diameter of about 400 mm at uniform angular intervals. The charging electrodes 10 are embedded axially parallel with their central main part in a circular ring body 20 made of insulating material, as can be seen in FIG. 1. The front end (tip) of the electrodes is exposed in a depression 22 in the end face 21 of the ring body 20 facing the object to be coated. The depression 22 opens outward at an angle which is more than 90 ° (for example about 120 °) should be, which among other things any necessary cleaning of the electrode tips is facilitated. The rear ends of the charging electrodes 10 are connected in an electrically conductive manner to a conductor 12 made of wire or wire mesh, which interconnects all electrodes in a ring shape and which is to be completely enclosed in the interior of the ring body 20 for electrical insulation.

On the outer housing 7 of the spraying device, the ring body 20 is fastened by two spokes 24, which are also made of insulating material and which protrude radially from an insulating material ring 26 placed on the outer housing 7, but preferably obliquely inclined in the direction of the object to be coated. Different shaped and arranged spokes can also be provided. The ring body 20, the spokes 24 and the ring 26 can be formed in one piece or connected to one another. A clamping screw 29 can be used for fastening to the outer housing 7.

A high-voltage cable 14 leads through an outer connecting part 28, the ring 26 and one of the tubular spokes 24 and is connected to the conductor 12 connecting the charging electrodes 10 via a contact arrangement 16 provided at the (in FIG. 1 upper) end of the memory 24. The high voltage potential thus applied to the electrodes can be, for example, 60 to 80 kV or more. As shown, the contact arrangement 16 can e.g. contain a compression spring 17 and a screwed against the conductor 12 contact pin 18. An advantage of the device described here is therefore that only a single high-voltage cable is required for the electrical connection of the outer electrodes, while in the known device with electrodes located in their own holders, each of them has a separate cable which leads outside the holder to the each other cables must be coupled together at a connection point.

The number of charging electrodes 10 is of course not limited to the example chosen here, but should be chosen so that there is a sufficiently small distance between the electrodes to avoid a risk of contamination from the coating material on the front end face of the ring body 20. With a pitch circle diameter of the electrodes of 400 mm, between about 18 and 30 electrodes should be used. With significantly fewer charging electrodes, one would find a substantial coating of the end face 21, that is to say conductively connecting the electrodes outside of the insulating ring body 20, with the sequence explained at the beginning of an increase in further contamination of the coating device, while more than 30 electrodes in this example without noteworthy further improvement of the electric field would only increase the structural effort. If you choose a smaller or larger pitch circle diameter for the electrodes, their possible minimum number must be reduced or enlarged accordingly. In a relatively large range of pitch circle diameters around the value of 400 mm of the example described here, the distance between the electrode tips should accordingly be between approximately 40 and 70 mm.

The radially measured distance of the electrode tips from the spray edge 6, as in the known device, should be greater than twice the diameter (here approximately 70 mm) of the spray edge. A currently preferred range of possible pitch circle diameters of the electrodes 10 is approximately 350 to 450 mm.

The axial position of the electrode tips with respect to the plane of the spraying edge 6 is also important for the risk of contamination. As in the known device, in the embodiment shown in FIG. 1 the electrode tips are to be set back a certain distance behind the spraying edge 6 in the axial direction. This distance is chosen so that there is a usable compromise between the charging of the sprayed coating material, which improves with decreasing distance, and, at the same time, increasing pollution, particularly of the bell cup 2 and the atomizer or its housing. In the example shown, axially measured distances between 25 and 60 mm and preferably about 50 mm have proven to be useful. In general, the front ends of the charging electrodes should be set back axially by less than 1/3 of the distance of the electrode tips from the spraying edge 6 measured in the radial direction behind the plane of the spraying edge.

As has already been explained, according to the invention, an electrically conductive connection between the charging electrodes outside the ring body 20 which forms their holder is to be avoided by coating with conductive material (water-based paint). In the simple embodiment shown in FIG. 1, this can already be largely achieved by a corresponding minimum number of electrodes or the limitation of their distance to a maximum value. However, it may be advisable to take additional measures to avoid the undesired coating.

A first additional measure is to increase the "leakage current" or surface path between the electrode tips. For this purpose one can e.g. 3 embed longer needle-shaped electrodes 10ʹ in a finger-like projection 31 made of insulating material axially projecting from the end face 21ʹ of the ring body 20ʹ in the direction of the object to be coated, or in any case enclose it. These pins 31 can be used with their rear ends in the ring body 20 Ring or molded. The electrodes 10ʹ are exposed with their front end in a depression similar to the depression 22 in the front pin end, while at the rear end they are connected to a connecting conductor 12ʹ as in the exemplary embodiment according to FIG. 1.

Another additional measure consists, according to FIGS. 4 and 5, in the interior of the annular body 20ʺ in addition to the connecting conductor to form an annular fluid channel 35 under fluid pressure, from which axially opening fluid openings 36 to the outside towards the end face 21ʺ Guide ring body 20ʺ between the charging electrodes 10ʺ. The fluid, preferably air, flowing out of the openings 36 keeps the coating material away from the end face. The connection of the fluid channel 35 to an external compressed air or other fluid source indicated by arrow 37 in FIG. 1 can lead through one of the spokes 24, expediently through the one in which the high-voltage cable 14 is not located.

Claims (10)

1. Device for electrostatically coating objects with an electrically conductive material,

with a spray device, in particular a rotary atomizer;

with an outer housing holding the spray head;

with a the coating material of one
Storage system of a spraying edge on the line supplying the spray head, which is placed with the material into the spray head at earth potential;

with needle-shaped charging electrodes distributed radially around the spray head on a circle concentric to the spray head axis with uniform mutual angular distances, which are connected to a high voltage source for charging the coating material and for generating an electric field,

wherein the radial distance of the front ends of the charging electrodes facing the object to be coated is greater than twice the diameter of the spraying edge;

and with an electrode holder arrangement made of insulating material, in which the charging electrodes are enclosed with the exception of their front ends and which has at least one support projecting radially from the outer housing of the spray head,

characterized,

that the charging electrodes (10) are inserted into an annular body (20) made of insulating material which surrounds the outer housing (7) of the spray head at a distance,

in which an electrical conductor (12) connecting the charging electrodes (10) to one another in a ring-like manner and connected to the high-voltage line (14) is arranged insulated from the end face (21) of the ring body (20) facing the object to be coated,

and that the arrangement and the mutual distance of the charging electrodes (10) are selected so that no significant precipitation of coating material occurs on the end face (21) of the ring body (20) during operation. 2. Device according to claim 1, characterized in that at a diameter of the circle on which the electrode ends lie, of more than 200 mm at least nine charging electrodes (10) are present. 3. Apparatus according to claim 2, characterized in that at a circle diameter of about 400 mm or more, at least eighteen charging electrodes (10) are present. 4. Device according to one of the preceding claims, characterized in that the insulating ring body (20) consists of polypropylene (PP). 5. Device according to one of the preceding claims, characterized in that the front electrode ends are exposed in a depression (22) whose opening angle is more than 90 °. 6. Device according to one of the preceding claims, characterized in that on the end face (21ʹ) of the ring body (20ʹ) means (31) for a substantial increase in the surface path between the exposed front ends of the charging electrodes (10ʹ) are provided. 7. The device according to claim 6, characterized in that the electrodes (10ʹ) in finger-like axially from the end face (21ʹ) of the annular body (20ʹ) projecting pins (31) are arranged from insulating material. 8. Device according to one of the preceding claims, characterized in that the annular body (12ʺ) has means (36) for preventing precipitation of coating material on its end face (21ʺ). 9. The device according to claim 8, characterized in that the annular body (12ʺ) contains a fluid channel (35) under fluid pressure, from which openings open axially in the end face (21ʺ) between the electrodes (10 "). 10. Device according to one of the preceding claims, characterized in that the front ends of the charging electrodes (10) axially by less than 1/3 of the radial distance of the electrodes (10) from the spray edge (6) behind the plane of the spray edge (6) are reset.

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