FR2610849A1 - Device for electrostatically spraying a substance in powder form - Google Patents

Abstract

Device for electrostatically spraying powder, especially for application of powder paint. The device includes a flow pipe 13 for the air-powder mixture, a charging electrode 20 in front of the ejection orifice 15 of the said air-powder mixture and a counterelectrode 38, porous in this case, through which air passes, the counterelectrode 38 being extended by a protective sleeve 40 preventing it from becoming clogged up. Application to the implementation of heat-meltable powder spray painting.

Description

"Electrostatic product projection device in
powder"
The invention relates to a device for electrostatic spraying of powdered product - and more particularly a coating product transported by air, the invention relates more particularly to an improvement making it possible to prevent a counter-electrode (including ie the role is, in particular, to capture the free ions of the air-powder mixture ejected towards an object to be covered), does not gradually lose its eff, icacity ~ by being covered by the coating product (prfanting an insulating film).

 -l, e electrostatic dusting is- commonly used in industry, in particular -to reconvert objects of a hot melt paint applied in.powder. When such objects are completely covered with a sufficient layer of powder, they are transported to an oven where the powder coating becomes a homogeneous and resistant layer of paint, by melting the grains of powder together followed in general by polymerization. .

 To electrically charge the powder particles of the air-powder mixture, an electric charge field can be created between a charging electrode placed in the air-powder mixture and a counter electrode separated from the charging electrode by a distance of a few centimeters. It is necessary, too, to ,. create a deposit field between the projection device and the object to be covered. This is generally achieved by bringing the charging electrode to a high electrical voltage and connecting the object to earth.

the counter-electrode can itself be connected to earth or brought to an intermediate potential, to create the desired field, taking into account the dimensions of the projector and in particular the distance between the two electrodes.

 From this point of view, we seek to develop devices implementing voltages which are not excessively high. It is particularly desirable to create a charge field over a distance of 30 to 40mm with a potential difference of the order of 30kV between the electrodes.

 C) found that, if free ions propagated at the same time as the air-powder mixture towards the object to be covered, being entrained by the deposition field, differences in the concentration of powder deposition could occur between the reliefs and fractures of the object.

These differences in powder concentration are obviously the source of differences in thickness in the paint layer, after passing through the oven. It is therefore desirable that substantially all of the free ions which could not charge the powder are recovered by an ion trap, in this case the counter-electrode. Several counter electrode electrodes have been proposed to best assure the "recovery" of free ions. Many of the solutions proposed place the counter-electrode inside the air-powder mixture circulation conduit or in direct communication with the interior of this conduit.

 These sc> luLions are generally unsatisfactory due to the fact that the powder comes more or less quickly to cover the counter-electrode resulting in the formation of a coating. insulating preventing it from playing its role of ion trap. It is assumed that one of the phenomena in question is a local melting of the grains of powder resulting from their impact energy on the counter-electrode. To avoid such agglomeration of powder on the counter-electrode, it has been proposed to permanently clean it with a circulation of clean air and even to provide a porous counter-electrode l: permanently spilled by air. of this type is. for example described in French patent N 2 288 729. It has also been proposed to place the electrode outside the circulation duct of the air-powder mixture but it has not been possible, until now, to prevent that powder particles entrained by vortices do not cover the counter-electrode. In this connection, the American patent N 4 228 961 proposes a structure with an axial cylindrical counter-electrode, cleaned by a jet of air maintained in a very small annular space around the counter-electrode. counter-electrode by this air jet has not given good results and this failure can be attributed to the fact that the air jet can itself promote the formation of vortices in the vicinity of the counter electrode. In addition, it seems that the shape of this counter-electrode and the small cross-section of the passage which the free ions must take to come and meet the counter-electrode, considerably reduce the effectiveness of the latter as an ion trap. In addition, a passage of such a small section can be closed in use.

 The invention provides a new arrangement of an electrostatic powder projection device, comprising a counter-electrode situated outside the circulation duct, of a shape and dimensions suitable for enabling it to effectively play its role of ion trap, said counter -electrode being associated with blowing means ensuring, among other things, its permanent cleaning.

The invention relates in particular to an arrangement making it possible to prevent vortices of air-powder mixture from forming in the immediate vicinity of the counter electrode, in particular due to the very flow of the air responsible for cleaning this counter electrode .

 In this spirit, the invention therefore relates to a device for electrostatic projection of powdered product, in particular a coating product, of the type comprising a duct for circulation of an air-powder mixture provided with an ejection orifice at one end. , a charging electrode disposed in the vicinity of said orifice. ejection and a counter electrode arranged coaxially to said charging electrode and behind it with respect to the direction of ejection of said air-powder mixture, a potential difference being applied between the two electrodes to create an electric field capable of entraining free ions towards said counter-electrode, blowing means being arranged in the vicinity of the counter-electrode, characterized in that said counter-electrode is outside the circulation duct and extends substantially perpendicularly to the axis of the latter and in that an annular space extending in the direction of said charging electrode from said counter-electrode is defined around said circulation conduit, said blowing means opening into this annular space.

 In a simple manner, the abovementioned annular space is defined between the external surface of said conduit for circulation of the mixture, air-powder and an outer sleeve and coaxial with this conduit.

 Thus, the counter-electrode can, without disadvantage, have a relatively large annular surface (perpendicular to the axis of the device) and arranged in such an outlet that the free ions remaining in the space where the charge field prevails, are almost -all attracted to it Du would be that the air is channeled into said annular space, relatively long, the powder particles which could be attracted towards the counter-electrode due to their charge, are repelled by the force of the jet of air. The latter's role is therefore no longer only to clean the counter-electrode, but also to prevent grains of powder from reaching it. In addition, eddies capable of transporting powder to the cir, nt.re-éledtrode are no longer to be feared since no call for polluted ambient air is possible in the vicinity thereof.

the invention will be better understood and other advantages thereof will appear more clearly in the light of the following description of an embodiment in accordance with its principle, given solely by way of example and made in reference to the attached drawing in which:
- The single figure is a schematic view in longitudinal section of a possible embodiment of an electrostatic powder spraying device according to the invention.

 The powder spraying device 11, as shown, mainly consists of the assembly of a metal body 12 and connected to the ground in the example described containing a number of passages and cavities and a circulation duct 13 of the tubular and cylindrical air-powder mixture, tightly connected to the body 12 by one of its ends, with the interposition of an annular seal 14. The insulating conduit 13 has at its other end an ejection orifice 15 of said air-powder mixture. The body 12 and the circulation duct 13 are traversed by an insulating rod 16, arranged coaxially with the duct 13, with a tubular structure housing a high-voltage cable 17 whose train 17a is in contact with a spring 18 establishing the electrical connection with one end of a resistor 19; the other end of this resistor is in contact with a charging electrode 20 comprising a disc-shaped collar 21 coaxial with the rod 16 and with the conduit 13 and extending substantially perpendicular to this axis . Its circular outline emerges from the lateral surface of the insulating rod 16. The latter is held in its axial position by being engaged in a bore 22 of the body 12 on the one hand, and in the central bore of a part 24 provided with 'radial fins 26 bearing against the internal wall of the conduit 13, on the other hand. The charging electrode 20 is located outside of the ejection orifice 15, in the axial extension of the circulation duct 13 of the air-powder mixture. In a way that, in itself, the insulating rod is extended in the direction of ejection of the air-powder mixture by an enlarged part 27 forming a deflector. The charging electrode 20 is here interposed between the cylindrical rod 16 and the enlarged part 27 and constitute, by means of threaded portions located in the extension of one another, the means of assembly of these two elements. The body 12 is provided with a connector 29 by which the air-powder mixture is introduced into an inclined passage 30. The latter communicates with the end of the circulation duct 13, assembled to said body 12.

 Another connector (not visible in the drawing) communicates with holes 31, 32 of the body 12. It is intended to be connected to a source of compressed air. The bore 32 opens into an annular housing 34 defined between the external surface of the duct 13 and a duct element 35, generally cylindrical, attached in leaktight manner to the body 12, by one of its ends, with the interposition of a seal 36 The arrangement (31, 32, 34, 35) forms blowing means for cleaning a counter-electrode 38 placed outside the circulation duct 13 so as to close off one end of the annular housing 34. In the device described, the counter electrode is porous, for example made of porous bronze. This feature is known in itself. Thus, pressurized air injected into the annular housing 34 escapes through said counter-electrode 38. The latter forms a flat annular wall bearing internally against a shoulder of the external surface of said circulation conduit 13 and, externally, against one end of the conduit element 35. The conduit 13 and the conduit element 35 are made of insulating material and the counter-electrode is brought to 'a selected potential, in in this case the potential of the earth, by a spring 39 slightly compressed in the annular housing and coming into contact with the body 12.

 According to an important characteristic of the invention, the counter-electrode, external to the conduit 13 and which extends perpendicular to the axis of the latter is protected by an external sleeve 40 which defines with the circulation conduit 13 and around that here, an elongated annular space 41. The latter is therefore located in the extension of the counter electrode in the direction of the charging electrode 20 and, as a result. here that the counter-electrode is porous, the blowing means defined above open into this annular space 41. The counter-electrode 38, in the form of a flat annular wall, therefore extends between the external surface of the circulation duct and one end of the outer sleeve 40. To facilitate mounting, the conduit element 35 and the sleeve 40 are located coaxially in the extension of one another and the counter electrode 38 is clamped externally between the opposite ends of said conduit element 35 and said sleeve 40. To do this, an internally threaded mounting ring 45 is screwed onto an external threaded portion of the conduit element 35 and it has an internal shoulder 46 at one end, which is supported against an external shoulder 47 of the sleeve 40. Advantageously, the ring 40 and the sleeve 45 can be made in one piece.

 It has been found that with this arrangement, the force imparted by the air flowing in the sleeve 40 to the charged particles (this force essentially depends on the speed of the flow of air in the sleeve and on the surface of the particles) was greater than the force of electrical origin attracting these same charged particles.

These conditions are only realized in the presence of the sleeve due to the channeling of the air escaping from the counter-electrode. Furthermore, no vortex (capable of causing powder) can form in the vicinity of the counter-electrode, the vortex zones being, at worst, carried forward, in the vicinity of the end of the sleeve 40.

 A metal rod 48, in electrical contact with the charging electrode 20 (and which can advantageously be an extension of the latter) emerges axially from the end of said enlarged part 27. This feature improves the configuration of the deposition field.

 Of course, the invention is not limited to the embodiment which has just been described. The sleeve 40 is not necessarily cylindrical, it can be conical, widening in the direction of the counter electrode 38, which makes it possible to use a larger counter electrode. If the charging electrode is not brought to a very high high voltage, the counter electrode 38 can be earthed. On the other hand, if one wants to increase the voltage applied to the charging electrode, so as to increase the deposition field, one can avoid modifying the dimensions of the device, that is to say in particular the distance between the electrode load and the counter-electrode, by bringing said counter-electrode to an intermediate voltage. As an example, we try to maintain a potential difference of 30kV between the two electrodes. If we wish to increase the deposit field, we can carry the charging electrode up to 90kV, the counter-electrode then being worn at 60kV. Other modifications are possible. In particular, the charging electrode 20 is not necessarily located at the junction between the cylindrical part of the rod 16 and the enlarged part 27.

 The charging electrode can in particular emerge at any point of said enlarged part and even consist of a simple metal disc covering the end of the deflector, the rod 48 then being eliminated. It is also possible to envisage making the charging electrode in the form of several points, for example three, regularly distributed angularly and projecting preferably at the periphery of the deflector. Finally, the counter electrode can be formed from another porous metal ( for example porous stainless steel) or in a conductive synthetic material. Nor does it have to be porous; one could perfectly conceive a variant in which air passages would bypass it to establish air circulation between the housing 34 and the annular space 41.

Claims (12)

 1- Device for electrostatic projection of powdered product, in particular a coating product, of the type comprising a circulation duct (13) of an air-powder mixture provided with an ejection orifice (15) at one end, a charging electrode (20) disposed in the vicinity of said ejection orifice and a counter electrode (38) arranged coaxially with said charging electrode and behind it with respect to the direction of ejection of said air-powder mixture, a potential difference being applied between the two electrodes to create an electric field capable of entraining free ions towards said counter-electrode, blowing means being arranged in the vicinity of the counter-electrode, characterized in that said counter-electrode ( 38) is outside the circulation conduit and extends substantially perpendicular to the axis of the latter and in that an annular space (41) extending in the direction of said charging electrode from said counter -electrode is defined around said circulation duct (13), said blowing means opening into this annular space.  2- Device according to claim 1, characterized in that said charging electrode (20) is located outside said ejection orifice (15), in the axial extension of said circulation conduit (13).  3- Device according to claim 1 or 2, characterized in that said annular space (40) is defined between the external surface of said circulation duct (13) and a sleeve (40) outside this duct.  4- Device according to claim 3, characterized in that said counter-electrode (38) forms a flat annular wall extending at least between the outer surface of said circulation conduit and said outer sleeve.  5- Device according to one of claims 1 to 4, characterized in that said counter-electrode (38) is a porous wall and that said blowing means comprise a conduit element (35) closed at one end by this porous wall , this duct element being adapted to be connected to air supply means.  6- device according to claim 5, characterized in that said conduit element (35) surrounds said circulation conduit (13).  7- Device according to claim 5 or 6, characterized in that said conduit element (353 and said outer sleeve (40) are located coaxially in the extension of one another and in that said counter-electrode (38 ) is clamped externally between the opposite ends of said conduit element and said outer sleeve.  8- Device according to claim 7, characterized in that a mounting ring (45) internally threaded eeit. screwed onto an external threaded portion of said connection element (35) and has an internal shoulder (46) at one end, which bears against an external shoulder (47) corresponding to said external sleeve (40).  - Device according to one of claims 1 to 8, characterized in that said charging electrode is provided with a part (21) with circular contour, coaxial with said circulation conduit.  10- Device according to claim 9, characterized in that said charging electrode comprises a metal disc (21) whose circular edge emerges from the lateral surface of an insulating rod (16) arranged coaxially with said circulation conduit.  11- Device according to claim 10, characterized in that, in a manner known per se, said insulating rod (16) Lermine ends with an enlarged part (27) forming a deflector.  12- Device according to claim 11, characterized in that a metal rod (48) in electrical contact with said charging electrode (20) emerges axially from the end of said enlarged portion (27).  13- Device according to claim 10, characterized in that said charging electrode comprises a metal disc mounted at an enlarged end forming a deflector, an insulating rod arranged coaxially with said circulation conduit.  14- Device according to one of claims 1 to 8, characterized in that said charging electrode comprises several tips regularly distributed angularly.