DE9305642U1 - Electrostatic spray device - Google Patents

Description

Our ref: G 798 DE 29 March 1993

Gema Volstatic AG

Electrostatic spray device

The invention relates to an electrostatic spraying device according to the preamble of claim

The invention is suitable for powdered coating material such as plastic powder or enamel powder.

When electrostatically spraying objects, the powder is sprayed onto an outlet

opening of the spray device and is positively or negatively electrostatically charged either immediately before or after this outlet opening. Electrodes are used for this purpose, hereinafter referred to as charging electrodes, which are connected to a high electrical voltage in the range between 40 KV and 140 KV. The objects to be coated have a different electrical potential, preferably earth potential. The atomized powder particles move along electrical field lines which are generated by the high voltage between the charging electrode and the object to be coated. After a thin layer of powder has formed on the object to be coated, this layer repels subsequent powder particles with its electrical charge because they are electrostatically charged in the same way. As a result, only a limited layer thickness can be produced on the object to be coated in one operation. Furthermore, the mutual repulsion of the powder particles on the surface of the object to be coated creates an unstable balance of forces. This unstable force ratio means that no smooth, even coating surface is formed, but rather a kind of "hilly landscape ^{" 11} , which forms a so-called "orange peel" effect during the subsequent firing of the layer and should therefore be avoided if possible.

The electrostatic attraction of the object to be coated is different at corners and edges as well as at openings in this object than on flat, larger surfaces. Corners and edges are usually coated more poorly or less strongly than adjacent larger surface areas. The powder particles fly around the outer peripheral edges and around the edges of openings of the object to be coated under the influence of the electrostatic field and are then drawn to the back of the object due to the electrostatic attraction of the object, so that the back of the object to be coated is also coated. This can be referred to as "electrical wraparound".

By using a counter electrode, which sucks free ions out of the sprayed powder stream, the surface quality and the penetration capacity of the powder into recesses in the objects to be coated can be improved. Furthermore, a thicker layer of powder can be applied to the objects to be coated in one spraying process without excessive amounts of powder particles bouncing off the object or being electrostatically repelled. In particular, an "orange peel"-like coating surface can be avoided.

The invention is intended to solve the problem of creating means by which one or more counter electrodes can be provided inexpensively and with little space requirement in spray devices and in particular, commercially available spray devices can be retrofitted with at least one counter electrode. These means and

-A-

the counter electrode should not impair the easy handling of the spray device.

This object is achieved according to the invention by the characterizing features of claim 1.

Further features of the invention are contained in the subclaims.

The invention is described below with reference to preferred embodiments as examples. In the drawings show

Fig. 1 a spray device for electrostatic spray coating of objects, in which a counter electrode in the form of a ring is arranged coaxially to a charging electrode,

Fig. 2 shows a further embodiment of a spray device for electrostatic spray coating of objects, in which several rod-shaped wires are provided as counter electrodes,

Fig. 3 is a side view of another electrostatic spraying device according to the invention,

Fig. 4 is a side view of the spray device of.
Fig. 3 with counter electrode device removed,

Fig. 5 a side view of a pistol-like

electrostatic spraying device after the
Invention.

The spray device or spray gun 2 shown in Figures 1 and 2 for electrostatic spray coating of objects 4 or 6 has a spray body 3 with an inlet 8 for pneumatically conveyed coating powder, an outlet 10 for atomizing or spraying the powder onto an object 4 or 6, and at least one charging electrode 12 located axially in the powder flow. The charging electrode 12 is located in the outlet 10 or in the immediate vicinity upstream or downstream of the outlet 10 and is connected to a

High voltage generator 16 is connected, which generates an electrical output voltage in the range between 40 KV and 140 KV. The high voltage generator 16 can be arranged inside the housing 18 of the spray gun 2 or externally therefrom, as shown in the drawings. Both embodiments are known. The high voltage generator 16 of Figs. 1 and 2 is connected to a direct current low voltage source (not shown) arranged externally of the spray gun 2 and also to earth potential 20. Instead of an axial needle-shaped charging electrode 12 in the outlet 10, several charging electrodes could be arranged in the core of the coating material stream or around it, inside the housing 18 or in a nozzle forming the outlet 10, at the downstream end of the housing 18. In practice, various charging electrodes and arrangements of charging electrodes are known. Furthermore, one or more charging electrodes could also be arranged outside the spray gun 2 in or next to the stream of atomized powder. Such embodiments are also known.

The spray gun 2 shown is attached to a

Machine part or a robot 22 of a

Spray coating system. Instead,

They also have a handle and can be used as a hand-held spray gun.

The object 4 or 6 to be coated is usually transported by a transport device which

not shown, and transported through a spray coating booth. The transport device is earthed so that the object 4 or 6 carried by it is also earthed by the transport device.

The high electrical voltage generates electrical field lines 24, which run from the tip 26 of the charging electrode 12 to the object 4 or 6 to be coated. The powder particles sprayed at the outlet 10 move along these field lines 24 onto the object 4 or 6 to be coated. In doing so, they also penetrate into recesses 28 of the object to be coated and through openings 30 in this object. As a result, the particles reach the rear side 32 of the object through the "electrical wraparound effect" in edge areas of the object, as shown in Fig. 1 by field lines 36 "wrapping" the opening edge 34. On protruding edges 38 or corners, a thicker layer thickness is achieved due to electrostatic interactions than on raised surfaces 40 or larger flat surfaces 42 of the object 4 to be coated.

The sprayed powder, viewed in longitudinal section, has the shape of a particle cloud, as shown in Figures 1 and 2 by the field lines 24.

In Fig. 1, a ring-shaped counter electrode 44 is arranged coaxially to the charging electrode 12, which

has a different electrical potential than the charging electrode 12 and serves to suck up free ions, which are generated during the electrostatic charging of the powder. In doing so, the counter electrode 44 also attracts some electrons. This ion current and its path from the charging electrode 12 to the counter electrode 44 is designated by the reference number 46. The counter electrode 44 can be at a higher or lower electrical potential than the charging electrode 12. The counter electrode 44 is preferably connected to ground potential 20. The counter electrode 44 is preferably arranged according to Fig. 1 against the flow direction 48 of the powder upstream of the tip 26 of the charging electrode 12 coaxially with it, and thus outside and upstream of the powder cloud corresponding to the electrical field lines 24.

The outer surface 50 of the powder cloud, which corresponds in size and shape to the electric field lines 24, is not a sharp cloud boundary, but a diffuse transition between an area of uniform particle distribution and the surrounding atmosphere. In the description given here, the "outer surface 50" of the powder cloud is understood to mean the area where the particles no longer fly specifically along field lines 24 onto the object 4 or 6 to be coated, but rather wander out of the field line area. The distance "d" between the counter electrode 44 and the charging electrode 12,

between the counter electrode 44 and the tip 26 of the charging electrode 12, and between the counter electrode 44 and the outer surface 50 of the powder cloud should be smaller than the distance ¹¹ D" between the tip 26 of the charging electrode 12 and the object 4 or 6 to be coated. Preferably, the distance "d" between the tip 26 of the charging electrode 12 and the counter electrode 44 is only one third to one half of the distance "D" between the tip 26 of the charging electrode 12 and the object 4 or 6 to be coated.

A compressed air nozzle arrangement 52 blows air over the counter electrode 44 or into the space between the counter electrode 44 and the charging electrode 12 in order to prevent the counter electrode 44 from being coated with powder. Compressed air is only required if coating of the counter electrode 44 cannot be prevented in any other way.

The counter electrode 44 is preferably carried by the housing 18 of the spray gun 2.

Instead of a charging electrode 12 or a counter electrode 44, several electrodes can also be present.

The embodiment of a spray gun 2 shown in Fig. 2 is identical to that of Fig. 1, with the exception of at least one counter electrode 64, which in the embodiment shown in Fig. 2 is a

needle-shaped wire electrode. It is coaxially surrounded by compressed air 66 and is thereby kept free of coating material. Preferably, a number of counter electrodes 64 are arranged coaxially to the charging electrode 12. These counter electrodes 64 are preferably arranged at the same circumferential distance from one another around the charging electrode 12. In Fig. 2, parts that correspond to parts of Fig. 1 are provided with the same reference numbers.

If desired, means 68 for axial and/or radial positioning of the counter electrode 44 or 64 relative to the charging electrode 12 can be provided.

Functions of the embodiments according to Fig. 1 and 2: a) Without counter electrode 44 or 64:

Electrons are released under high electrical voltage at the at least one charging electrode 12, which according to Figures 1 and 2 can be an axial needle electrode, or can be present in the form of a multiplicity of such or other electrodes. In the vicinity of the high electrical field 24 of the charging electrode 12, a small part (approx. 1% to 5%) of the electrons are charged onto the coating material, in this case powder. The rest flies to the nearest grounded point, for example approximately 80% onto the object 4 or 6 to be coated, approximately 10% onto the

Walls of the booth in which the objects are coated and approximately 5% to 20% on the downstream end of the spray gun, depending on the distance between the charging electrode 12 and the object 4 or 6 to be coated. The electrostatically charged powder finds its way onto the object 4 or 6 to be coated and largely adheres there. The powder forms an electrically insulating layer on the object. The excess electrons form an increased electrical charge together with the powder on the surface of the object 4 or 6 and repel powder particles that arrive later. An electrostatically unstable force balance is created on the surface of the object 4 or 6. This mechanism leaves a "hilly landscape" on the surface, which is referred to as "orange peel" after the layer has been baked on. The free ions in the air between the charging electrode 12 and the object 4 or 6 to be coated move at a very high speed of over 100 m/s. They follow the relevant stronger electrostatic field, i.e. the electrostatic forces. The electrostatically charged powder particles are subject to the kinematic flow forces because they are transported in a gas or air stream. The speed of movement of the powder particles is significantly lower than that of the ions and is only approximately 10 to 15 m/s. This means that the ions move independently of the powder particles.

Each individual ion has its own electrostatic field. In the vicinity of an object, this field is very strong due to the short distance to the grounded object. This is why the Faraday effect is also correspondingly strong. The free ions as a whole form a high electrostatic space charge. As a whole, this space charge therefore acts as a strong Faraday cage on all corners and edges of the object to be coated, preventing the powder particles from penetrating properly into recesses and grooves.

b) With counter electrode or counter electrodes 44 or 64:

When using a counter electrode, the free ions are attracted to the counter electrode 44 or 64 and are diverted from the powder stream. The counter electrode must be close to the charging electrode. The distance "d" between the charging electrode 12 and the counter electrode 44 or 64 is preferably about one-third to one-half of the distance "D" between the counter electrode and the object 4 or 6 to be coated. If the distance "d" is greater, the counter electrode loses its effect; the free electrons and ions are more strongly attracted to the object 4 or 6 to be coated than to the counter electrode 44 or 64. If the distance "d" is smaller, too much electrical current flows between the charging electrode and the counter electrode, which reduces the high electrical voltage at the tip 26 of the charging electrode and thus the electrostatic field 24 necessary to charge the powder. The

Counter electrode 44 or 64 causes an increased electrical current flow at the tip 26 of the charging electrode 12. As a result, significantly more free ions or electrons are generated by the charging electrode 12 for electrostatic charging of the powder at the outlet 10 of the device 2 and are then available for electrostatic charging. The electrostatic charging of the powder is thereby significantly improved. In addition, the efficiency of applying the powder to the object 4 or 6 to be coated is also significantly improved. The counter electrode 44 or 64 conducts away the majority of the ions, approximately 60 to 80%. Only the charged powder particles fly onto the object 4 or 6 to be coated, namely only 2% to 8% of the total electrical current. The undesirable free ions are thus separated from the powder flow. The ion space charge still exists here, but the flow of free ions is concentrated on the counter electrode 44 or 64. The Faraday effect is very strong on the counter electrode, but very small on the object 4 or 6 to be coated. The electrostatically charged powder particles therefore penetrate better into the recesses and grooves of the object 4 or 6. The "electrostatic coverage" is also better. There is no accumulation of free ions on the surface of the object 4 or 6. The electrostatic forces on the surface of the object 4 or 6 are significantly smaller. There is no unstable state

on the surface. The formation of an orange peel effect is inhibited. A significantly thicker layer of powder can be applied to the object 4 or 6 in a single spraying process. Since there is a risk that the counter electrode 44 or 64 will also be coated by the electrostatically charged powder, it is expedient to rinse the counter electrode 44 or 64 with compressed air. To avoid coating the counter electrode 44 or 64, it is expedient if it is arranged outside the powder flow, preferably set back upstream with respect to the downstream tip 26 of the charging electrode 12, and not arranged between the charging electrode 12 and the object 4 or 6 to be coated.

The electric current at the charging electrode is higher when a counter electrode 44 or 64 is used. The current rose in tests from about 70 μα to about 100 μα. The powder cloud forms an electric resistance and promotes the flow of ions to the counter electrode 44 or 64.

The electrostatic spray device 2 shown in Figs. 3 and 4 consists essentially of a tubular spray body 3, to the downstream end of which a slot nozzle 70 is attached for atomizing the pneumatically conveyed powder. Inside the spray nozzle 70 or the spray body 3 there is at least one charging electrode 12 for electrostatically charging the powder. On the downstream section 72 of the spray body 3, to which the spray nozzle 70 is attached, an annular body 74 is attached, which forms a counter electrode and/or several needle-like

Counter electrodes 76 which protrude from it. The counter electrodes 74 and 76 are connected to an electrical potential, preferably to ground potential, which is different from the electrical potential of the charging electrode 12. The ring-shaped body 74 is attached to the downstream end of a connecting web 78 which extends axially parallel to the spray body 3 and is inserted with its upstream end 80 into a holder 22 and is axially positioned there by a screw with a knurled screw head 84.

Fig. 4 shows the spray device 2 of Fig. 3 with the counter electrode device 86 removed, with arrows 88 showing the direction of movement for attaching the ring-shaped body 74 to the downstream section 72. An arrow 90 also shows the direction of insertion for the screw 84 into a threaded hole 91 in the holder 22. Fig. 4 shows a ground potential connection 20. The ground potential connection 20 can be connected directly to the connecting web 78 if it and the ring-shaped body 74 are made of electrically conductive material. If at least the connecting web 78 is made of electrically insulating material, an electrical line 73 is provided which connects the ground potential connection 20 to the counter electrodes 76 and extends through the connecting web 78 and the ring-shaped body 74. The annular body 74 is made of electrically conductive material when it acts as a counter electrode. If it is not intended to act as a counter electrode, it can be made of electrically insulating material. The earth potential connection 20 can be formed by the carrier 22 if it is made of electrically conductive material.

Fig. 5 shows a pistol-shaped electrostatic spray device 2. Near the upstream end 94 of its spray body 3, the spray body is provided with a handle 95. The upstream end 80 of the connecting web 78 and the screw 84 are located directly above the handle 95 on the spray body 3. This allows the electrical grounding line 73 to be guided on the handle 95 or through it to the ground potential connection 20. This has the advantage that the material center of gravity of the spray device 2 is in or near the handle 95, so that the gun can be held without fatigue. In Fig. 5, the charging electrode 12 is shown as an axial electrode, while in Figs. 3 and 4 it was assumed that several needle-like charging electrodes 12 are arranged distributed around the powder path.

In all embodiments, the annular body 74 is preferably adjustable to different axial positions relative to the spray body 3. In all cases, when the annular body 74 acts as a counter electrode or carries counter electrodes 76, it is located upstream of the tip 26 of the charging electrode 12.

Claims (13)

Our reference number: G 798 DE 29 March 1993 Gema-Volstatic AG Protection claims 1. Electrostatic spray device for electrostatic spray coating of objects with powder, which has the following features: a tubular spray body (3); at least one charging electrode (12) for transferring electrostatic charges to the powder; the charging electrode (12) has an electrical potential which is different from the electrical potential of the object to be coated in such a way that the charged powder is electrostatically attracted to the object/ at least one counter electrode (44; 64; 74, 76) arranged near the charging electrode (12) which is connected to a different electrical potential (20) than the charging electrode (12) so that it absorbs at least some of the free ions generated during the electrical charging of the powder; at least one annular body (44; 68; 74) which forms or carries the counter electrode (44; 64; 74, 76) and extends around the downstream portion (72) of the spray body (3) on which it is radially supported; -2- characterized in that at least one connecting web (78) is provided which extends outside the spray body (3) parallel to it; that the connecting web (78) carries the annular body (74) at its downstream end (79) and is detachably attached to the spray body (3) with its upstream end in the vicinity of the upstream end of this spray body; that an electrical connection between an electrical potential connection (20) and the counter electrode (44; 64; 74, 76) is formed by the connecting web (78). 2. Spray device according to claim 1, characterized in that the connecting web (78) consists of electrically conductive material which forms the electrical connection. 3. Spray device according to claim 1, characterized in that the electrical connection is an electrical line (73) extending through the connecting web (78). 4. Spray device according to one of the preceding Expectations, characterized, that the connecting web (78) is a tube. 5. Spray device according to one of the preceding Expectations, characterized, that several counter electrodes (76) in the form of -3- Needle electrodes protrude from the ring-shaped body (74). 6. Spray device according to one of the preceding Expectations, characterized in that the distance (d) between the charging electrode (12) and the counter electrode (44; 64, 64/2) is smaller than the distance (D) between the charging electrode (12) and the object to be coated (4; 6). 7. Spray device according to claim 6, characterized in that the distance (d) between the charging electrode (12) and the counter electrode (44; 64) is one third to one half of the distance (D) between the charging electrode (12) and the object to be coated (4; 6). 8. Spray device according to one of the preceding Expectations, characterized in that means (52; 66) are provided by which the counter electrode (44; 64) is surrounded by compressed air (66) in order to keep it free of coating material. 9. Spray device according to one of the preceding Expectations, characterized in that the counter electrode (44; 64; 74, 76) is arranged upstream of the downstream end (26) of the charging electrode (12). -A- 10. Spray device according to one of the preceding claims, characterized in that the counter electrode (44; 64) is arranged at a distance from the atomized powder cloud, and that the distance (d) between the counter electrode (44; 64) and the powder cloud is smaller than the distance (D) between the charging electrode (12) and the object to be coated (4; 6). 11. Spray device according to one of the preceding Expectations, characterized in that the counter electrode (44; 64) is connected to earth potential. 12. Spray device according to one of the preceding Expectations, characterized in that the counter electrode (44; 64) is displaceable relative to the charging electrode (12) in the axial and/or radial direction and can be locked in the selected position by positioning means (68; 84). 13. Spray device according to one of the preceding Expectations, characterized in that the connecting web (78) consists entirely or at least on its outer surface of electrically insulating material.