FR2868342A1 - Spraying bowl for rotary sprayer, has two magnetic couplings exerting partially axial effort with respect to axis of rotation of bowl, wherein effort induces coupling in rotation of bowl with corresponding drive member - Google Patents

Abstract

The bowl (3) has two magnetic couplings that cooperate mutually, with second magnetic coupling fixed on the non-rotary part of a sprayer. Both magnetic couplings exert partially axial effort with respect to the axis of rotation of the bowl, wherein the effort induces coupling in rotation of the bowl with a corresponding drive member. Independent claims are included for the following (A) a rotary sprayer for spraying coating product; and (B) an installation for spraying coating product.

Description

The present invention relates to a spray bowl for a projector

  rotary coating product. The invention also relates to a coating product projector comprising such a bowl, as well as to

  a coating product projection installation incorporating such a projector.

  In a coating product spraying installation, it is known to spray the product by means of a rotating element, called bowl or cup, supplied with product and rotating at a speed usually between 2000 and 120 000 revolutions / minute. At the speeds considered, the bowl must be as light as possible and balanced to avoid, as far as possible, unbalance, especially if its rotating drive means comprise an air bearing turbine and / or magnetic.

  It is known, for example from WO-A-94/12 286, to connect a bowl to a rotor by means of an interlocking ring which can expand radially. It is also known, for example from WO-A-01/62 396, to use magnetic coupling means between a bowl and the rotor of a turbine. These coupling means comprise permanent magnets whose mounting on the bowl or the rotor of the turbine is relatively complex, especially to prevent these magnets burst under the effect of centrifugal force. Such an arrangement most often prevents rapid replacement of magnetic coupling magnets. In addition, the balancing of the rotating parts must be as perfect as possible in order to limit the effect of the forces of inertia. The magnet or magnets used must therefore be balanced in rotation, which is difficult to achieve because the material constituting the magnet or magnets does not have an isotropic density and because such a material is brittle, and therefore difficult to machine.

  It is these drawbacks that the invention intends to remedy more particularly by proposing a spray bowl which can be easily driven by a rotor provided for this purpose by virtue of an effective magnetic coupling, without the need to mount permanent magnets on a rotating part of the projector.

  In this spirit, the invention relates to a spraying bowl for a rotating coating product which is characterized in that it is equipped with first magnetic coupling means adapted to cooperate with second complementary magnetic coupling means fixed on a non-rotating portion of the projector, these first and second coupling means being adapted to exert a force at least partially axial with respect to the axis of rotation of the bowl, this force inducing the coupling in rotation of the bowl with a drive member corresponding.

  Thanks to the invention, the force resulting from the magnetic coupling makes it possible to secure the bowl and its drive means, in particular the rotor of a turbine, even though the magnetic coupling takes place between the bowl, which is rotatable, and a non-rotating part of the projector. It is therefore possible to mount the coupling magnet or magnets on this non-rotating part, this or these magnets then not having to be balanced.

  According to advantageous but not mandatory aspects, a spraying bowl may incorporate one or more of the following features: The coupling means carried by the bowl are arranged such that the coupling force is essentially axial.

  - A male portion of generally frustoconical outer shape is adapted to be engaged in a central housing of corresponding shape formed in the rotary drive member, the bowl being secured in rotation with this member by adhesion between the male part and the housing above, because of the axial force due to the coupling means. In a variant, the bowl defines a generally frustoconical housing, while a male portion of corresponding shape and integral with the drive member is provided to be engaged in this housing and allows the rotation of the bowl and the organ in rotation. traction drive, due to the axial force mentioned above.

  - The first magnetic coupling means define an annular or frustoconical surface which defines an air gap between the magnetic coupling means, while the radial width of this surface is greater than the total radial width of the second coupling means. Thanks to this aspect of the invention, the magnetic coupling force in the gap remains substantially axial, including in case of radial offset between the coupling means, which prevents the magnetic coupling force exerts on the bowl an unbalanced effort that could lead to a contact between a rotating part and a non-rotating part of the projector.

  - The first magnetic coupling means are formed by an annular element of magnetic material fitted or screwed around the main body of the bowl and defining an annular or frustoconical surface defining the air gap with the second coupling means.

  The invention also relates to a rotating coating product which comprises a bowl and a rotational driving member of this bowl, this projector being characterized in that it also comprises magnetic coupling means between the bowl and a part non-rotating the projector, these means being adapted to exert a force at least partially axial with respect to the axis of rotation of the bowl, this force inducing the rotational coupling of the above-mentioned bowl and body.

  According to advantageous but non-mandatory aspects, such a projector may incorporate one or more of the following features taken in any technically permissible combination: The coupling means are arranged in such a way that the coupling force obtained is essentially axial.

  - The bowl and the aforementioned member are respectively provided with complementary shapes portions of rotation coupling by adhesion.

  - The magnetic coupling means comprise at least one magnet arranged annularly around the axis of rotation of the bowl and fixed on the non-rotating portion, while the coupling means carried by the bowl define an annular or frustoconical surface defining a air gap between the coupling means carried by the bowl and the magnet and that the radial width of this surface is greater than the radial width of the magnet. Thanks to this aspect of the invention and, in particular, when the aforementioned surface is annular, the magnetic coupling force remains substantially axial, including in case of radial offset of the annular interaction surface with respect to the magnet. . In this case, it can be provided that the average radius of this surface is substantially equal to the average radius of this magnet and / or that the magnet is bordered radially, internally and externally, by two volumes of non-magnetic material or low magnetic permeability, while the radial width of the aforementioned surface is greater than the radial width of the magnet increased by the radial width of these volumes. These volumes of non-magnetic or low magnetic permeability material may be formed by air, annular rings made of aluminum-based alloy or filled with adhesive for fixing the magnet or magnets in a receiving volume integral with the non-rotating part. of the projector. The radial widths of each of these volumes are advantageously greater than the gap defined between the aforementioned surface and the magnet, preferably at least three times greater than this gap, preferably still of the order of five times this gap. It can further be provided that the aforementioned surface protrudes radially, inwardly and outwardly, with respect to the magnet and the volumes of non-magnetic material, an overhang at least greater than the gap between this surface and this magnet, preferably at least three times greater than this gap, preferably still of the order of five times this gap.

  Part of the magnetic coupling means is integrated in an annular support attached to the body of the headlight and extending axially. This aspect of the invention makes it possible to equip an existing turbine of the annular support in question, so as to allow the leveling of an existing projector into a projector according to the invention.

  - The gap between the parts of the magnetic coupling means respectively integral with the bowl and the non-rotating portion is such that the axial force has an intensity of between 5 and 20 daN.

  - The bowl and / or the drive member is provided with a disassembly assembly / disassembly, which prevents a jamming of the bowl on the drive member in the event of presence of dirt at the interface between these elements .

  - An air flow is provided in the gap between the magnetic coupling means, which prevents the accumulation of dirt in this gap, such dirt may be due to the entry of solid or liquid particles from the cloud of sprayed by the bowl.

  The invention finally relates to a coating product projection installation which comprises at least one projector as previously described. Such an installation is easier to operate and maintain than those of the state of the art, especially since the mounting of the bowls on the turbines and disassembly is facilitated.

  The invention will be better understood and other advantages thereof will appear more clearly in the light of the following description of two embodiments of a projector according to the invention comprising a bowl according to the invention, given only by way of example and with reference to the accompanying drawings in which: - Figure 1 is a longitudinal sectional view of a coating product projector according to a first embodiment of the invention incorporating a bowl compliant to the invention and forming part of an installation according to the invention; Figure 2 is an enlarged view of Detail II in Figure 1; Figure 2A is similar to Figure 2 but shows only the magnetic coupling elements in an offset configuration, the offset being exaggerated for clarity of the drawing; - Figure 3 is a section similar to Figure 1, the bowl being offset from the body of the projector; - Figure 4 is a perspective view partially broken away from the projector of Figures 1 to 3; FIG. 5 is a schematic representation of the variation of the magnetic coupling force as a function of the air gap and FIG. 6 is a section similar to FIG. 2 for a projector and a bowl according to a second embodiment of FIG. embodiment of the invention.

  The projector P shown in Figures 1 to 4 is intended to be supplied with coating material from one or more sources S and moved, for example, with a substantially vertical movement represented by the double arrow F1i facing objects 0 to be coated in an installation I coating these objects. The projector P comprises an air turbine of which only the front end 1 is represented, that is to say the part oriented towards the objects 0 to be coated. This end 1 is surrounded by a protective cover 2 and supports a bowl 3 intended to be rotated about an axis X-X 'by the rotor 11 of the turbine.

  The rotor 11 makes it possible to drive the bowl 3 at a speed of several tens of thousands of revolutions per minute, for example 80,000 revolutions per minute, so that the coating product coming from the source S through a tube of injection 18 is sprayed towards an object 0, as represented by the arrows F2.

  According to an advantageous aspect of the invention which is not shown, the projector P may be of the electrostatic type, that is to say include electrostatic charging means of the coating product before or after it has been discharged from the edge 31 of the bowl 3. As partially shown in the figures, the bowl 3 may be provided with a notch 32.

  The bowl 3 comprises a bi-partite hub 33 and a body 34 forming a cup and defining a surface 35 of flow and distribution of the coating product in the direction of the edge 31. The hub 33 is hollow and defines a channel longitudinal axis 36 which is centered on an axis X3-X'3 coincides with the axis XX 'when the bowl 3 is mounted on the rotor 11. The axis X3-X'3 is an axis of symmetry of the body 34 which is, for example, made of titanium.

  A ring 4 made of ferromagnetic material, for example magnetic stainless steel, is mounted around the body 34. The ring 4 is in one piece and comprises an annular skirt 41 and provided with an internal thread enabling the fixing of the ring 4 by screwing on a external thread 37 of the body 34. Alternatively, the ring 4 can be force-fitted around the bowl 3. According to another variant, the ring 4 can be integral with the body 34.

  The ring 4 comprises a portion 42 generally perpendicular to the skirt 41 and which defines an annular surface S42 and perpendicular to the axis X3-X'3. Note 142 the radial width of the surface S42, this width being measured in a radial direction relative to the axis X3-X'3.

  The body 34 forms a male portion 38 intended to penetrate into a central housing 12 of the rotor 11. The outer surface 38a of the portion 38 is generally frustoconical and convergent towards the rear of the bowl 3, that is to say the opposite of the ridge 31. The surface 12a of the housing 12 is also frustoconical and divergent towards the front face 13 of the rotor 11. There is a half angle at the top of the portion 38 and ss the half angle at the top of the housing 12 The angles cx and ss are substantially equal, which allows surface support surfaces 38a and 12a. Such surface support allows adhesion rotation rotation of elements 11 and 3.

  According to a variant not shown of the invention, the bowl may be provided with a generally frustoconical housing similar to the housing 12, while the rotor is equipped with a male part also frustoconical similar to the part 38, these reliefs also allowing a bonding of the elements 11 and 3 by adhesion.

  To prevent jamming of the portion 38 in the housing 12, a first clearance 38b is formed at the junction of the surface 38a and a connecting surface 34b of the body 34 to the surface S42. A second clearance 12b is provided in the bottom of the housing 12 in the form of a radial groove. The clearances 38b and 12b are intended to be arranged, when the bowl 3 is mounted on the rotor 11, respectively facing an inlet chamfer 12c of the housing 12 and the end edge 38c of the portion 38. These clearances prevent dirt from catching the portion 38 in the housing 12.

  A body 15 of the turbine surrounds the rotor 11 and is, in practice, the stator of the turbine. This body 15 is not rotatable. A support 5 made of magnetic material, for example magnetic stainless steel, is mounted on the front face 16 of the body 15, this support being provided with an annular groove 51 centered on the axis XX 'and in which a magnet is arranged. 52 also annular. The magnet 52 is held in place in the groove 51 by two adhesive layers 53 and 54 which extend radially on either side of the magnet 52. The adhesive layers 53 and 54 thus form two substantially annular washers arranged on either side of the magnet 52. Given the nature of the glue, which may be epoxy resin glue, these washers are non-magnetic.

  In place of a single magnet 52, several magnets may be disposed in the groove 51 together forming a ring. The magnet or magnets may or may be made of ferromagnetic metal or synthetic resin loaded with ferromagnetic metal particles injected in such a way that these particles are oriented in the same overall direction.

  In place of the layers 53 and 54 of glue, washers of non-magnetic metal or low magnetic permeability, in particular of aluminum, may be used. Similarly, volumes filled with air may be suitable, provided that the magnet is fixed in the groove 51 by other means.

  The radial width of the magnet 52 is noted.

  We denote 153 and the radial widths or the respective thicknesses of the layers or washers 53 and 54.

  The average radius of the magnet 52 is denoted by R52. The average radius of the surface 42 is denoted R 42. The radii R 42 and R 52 are substantially equal, which corresponds to the fact that, when the bowl 3 is mounted on the rotor 11, the surface S42 is disposed facing the exposed surface S52 of the magnet 52 and centered thereon. The magnetic field due to the magnet 52 thus closes through the portion 42 of the ring 4, as is apparent from the representation of its field lines L in FIG. 2.

  This magnetic field makes it possible to exert on the ring 4 a force F3 parallel to the axis X-X ', that is to say axial, and having a tendency to firmly press the bowl 3 onto the rotor 11; that is, the surface 38a on the surface 12a. Given this effort, the contacting surfaces 38a and 12a are secured in rotation, which allows a drive of the bowl 3 by the rotor 11.

  It is noted that the force F3 is parallel to the axis XX 'in the plane of FIG. 2, as in any section plane containing the axis X-X', which results from the fact that the surfaces S42 and S52 are perpendicular to the X-X 'axis.

  Since the width 142 is greater than the width 1S2 and, in practice, greater than the sum S2 of the width 152 and the widths 153 and 154, the magnetic field due to the polarization of the magnet 52 closes through the part 42 of the ring 4 even if it is slightly offset radially relative to the magnet 52, as shown in Figure 2A. This figure corresponds to the case where the axis X3-X'3 of the bowl 3 is not aligned with the axis X-X 'of the rotor 11 during the introduction of the bowl on the rotor. In this case, the force F3 remains substantially axial, which does not risk causing a displacement of the bowl 3 relative to the rotor 11 in a radial direction, such a movement can lead to damage to the contact areas 12 and 38 between these parts or a transverse displacement of the rotor 11 may damage its own drive means, for example its fins in the case of an air turbine.

  Provided that the width 142 has a sufficiently large value with respect to the widths 152, 153 and 154, the radii R42 and R52 may not be equal.

  Note e the value of the gap formed between the surfaces S52 and S42. The distance over which the surface S 42 projects radially outwards with respect to the layer 53 is noted. The distance over which the surface S 42 projects radially inwards with respect to the layer 54 is noted. The overhangs d 1 and d2 are different. They can, however, be equal. Each of the overhangs d1 and d2 is greater than the value of the gap e. In practice, these overhangs are at least three times greater than this gap and, preferably, of the order of five times this gap, which gives a good stability of the force F3, including in case of slight radial displacement of bowl 3 with respect to the rotor 11.

  Furthermore, the thicknesses 153 and 154 are greater than the gap e, preferably at least three times greater than this gap. In practice, a choice of thicknesses 153 and 154 substantially equal to five times this gap allows a good distribution of the field lines.

  The support 5 is immobilized on the front face 16 of the body 15 by means of three screws 6 whose countersunk head 61 bears on the layer 53 and possibly on the magnet 52, which contributes to the immobilization of the coupling means 52 to 54 in the groove 51. The support 5 axially extends the body 15 forwards, that is to say in the direction of the objects O. The fact that the magnets 52 and 54 are integrated in the support 5 makes it possible to provide report such support on the body 15 of a conventional turbine in which a bowl is normally immobilized on the rotor 11 by screwing through a thread 17 provided in the central bore 11a of the rotor 11 in which the tube 18 is disposed. , mounting the support 5 on a turbine makes it possible to transform a conventional projector, in which a bowl is screwed onto the rotor, into a projector according to the invention. This aspect of the invention makes it possible to envisage an upgrade of the existing equipment.

  According to a not shown variant of the invention, the magnetic coupling means 52, 53 and 54 can be integrated directly on the body 15, without the use of an attached support.

  As is more particularly apparent from FIG. 5, the force F3 is substantially inversely proportional to the value of the square of the gap e. The gap e is chosen so that the force F3 is greater than a minimum value F3min of the order of 5 daN corresponding to a satisfactory retention of the bowl 3 on the rotor 11. The gap e is also chosen so that the F3 force is less than a maximum value F3max of the order of 20 daN, this to prevent the bowl 3 is pressed against the support 5 without the pressurization of the air bearing of the turbine can take off the bowl and the rotor. Indeed, there is a risk that the force F3 pushes the rotor 11 to the left in FIGS. 1 to 3, which would have the effect of firmly immobilizing the bowl 3. It is therefore intended to obtain a force F3 of which the Intensity is located in the unhatched zone in Figure 5. In this zone, the variation of the value of the force F3 with respect to the change in the value of the air gap e is smaller than in the shaded area at above the F3max value. Thus, the machining and assembly tolerances do not influence too much the value of the force F3 or, at least, affect less than in the aforementioned shaded area.

  In practice, the effort F3 is chosen with a value equal to about 12 daN. this makes it possible to determine the value of the air gap e from the curve of FIG. 5. This value can vary over a range oe visible in FIG. 5 and depending on the values F3min and F3maxÉ This value depends in practice on the inertia of the bowl, so its geometry. It may be different depending on the types of bowls used.

  To prevent the accumulation of dirt between the surfaces facing the portion 42 and the magnet 52, an air flow E is formed in the gap between these coupling means.

  In the second embodiment of the invention shown in FIG. 6, elements similar to those of the first embodiment bear identical references. The bowl 3 of this embodiment is equipped with a ring 4 force-fitted on the body 34 of this bowl. This ring 4 comprises an annular skirt 41 and a frustoconical portion 32 converging towards the rear of the bowl 3 and centered on the axis X-X 'of rotation of this bowl. A support 5 attached to a turbine body, of the body type 15 of the first embodiment, is equipped with a magnet 52 bordered by two washers of non-magnetic material 53 and 54.

  The elements 52 to 54 are arranged in the support 5 so that their exposed surfaces are frustoconical and convergent towards the rear of the turbine, with a half angle at the vertex y equal to the half-angle at the apex 8 of the surface S42 of the part 42 which faces the elements 52 to 54. S52 is the exposed surface of the element 52. The surfaces S42 and S52 are parallel and define between them an air gap e of substantially constant thickness, this gap is also frustoconical with a half angle at the apex equal to y and 8. R42 and R52 respectively denote the average radii of the surfaces S42 and S52, these mean radii being substantially equal.

  When the bowl 3 is in place on the front end 1 of the turbine, a magnetic coupling force F3 is exerted, this force being substantially perpendicular to the surfaces S42 and S52 in the sectional plane of FIG. 6, so that it has an axial component parallel to the X-X 'axis. The resultant of the unitary forces F3 around the axis X-X 'is, for its part, substantially axial.

  The radial width of the surface 42 is denoted 142. The radial width of the surface S52 and 153 is also 152 and the radial widths of the rings 53 and 54 are 154 and the sum of the widths 152, 153 and 154 is indicated. As in the first embodiment, the width 142 is greater than the width S2r the surface 42 protruding radially outwardly and inwardly relative to the rings 53 and 54 of an overflow dl or d2 which is practical, of the order of five times the thickness of the gap e.

  L magnetic field lines are closed through the portion 42 of the ring 4, which ensures effective maintenance of the bowl in position relative to the end 1 of the turbine.

  The bowl 3 is provided with a male portion 38 intended to be received in a housing formed by the rotor 11 of the turbine, an adhesion joining taking place under the effect of the force F3i between the outer frustoconical surface 38a of the part 38 and a frustoconical surface 12a defining the housing formed by the rotor 11.

  In this embodiment, an air flow E may also be provided in the air gap with the particular advantage that the rotation of the bowl induces a pumping effect of the air from the inside to the outside of the air gap. gap e.

2868342 16

Claims (19)

  1. Spraying bowl for rotating projector coating product, characterized in that it is equipped with first means (4) for magnetic coupling capable of cooperating with second means (52) of complementary magnetic coupling fixed on a non-rotating part (5, 15) of said projector (P), said first and second coupling means being able to exert a force (F3) at least partially axial with respect to the axis of rotation (X-X ') of said bowl (3) , said force inducing rotational coupling of said bowl (3) with a corresponding driving member (11).   2. Bowl according to claim 1, characterized in that said first coupling means (4) are arranged such that said force (F3) is substantially axial.   3. Bowl according to one of the preceding claims, characterized in that it comprises a male portion (38) of generally frustoconical outer shape (a) adapted to be engaged in a central housing (12) of corresponding shape (ss) arranged in said member (11), said bowl (3) being adapted to be secured in rotation with said member by adhesion between said male portion and said housing, due to said axial force (F3).   4. Bowl according to one of claims 1 or 2, characterized in that it defines a generally frustoconical shaped housing adapted to receive a male portion of corresponding form integral with said member, said bowl being adapted to be secured in rotation with said member by adhesion between said housing and said male part, due to said axial force.   5. Bowl according to one of the preceding claims, characterized in that said first magnetic coupling means (4) define a surface (S42), annular or frustoconical and delimiting an air gap (e) between said first (4) and second ( 52-54) magnetic coupling means and in that the radial width (142) of said surface is greater than the total radial width (52) of said second coupling means.   6. Bowl according to one of the preceding claims, characterized in that said first magnetic coupling means are formed by an annular element (4) of magnetic material fitted or screwed (at 37) around the main body (34) of said bowl ( 3) and defining an annular or frustoconical surface (S42) delimiting an air gap (e) with said second coupling means (52-54).   7. Rotating projector coating product comprising a bowl and a member adapted to drive said bowl in rotation, characterized in that it comprises means (4, 52-54) for magnetic coupling between said bowl (3) and a part non-rotatable (5, 15) of said projector (P), said means being able to exert a force (F3) at least partially axial with respect to the axis (X-X ') of rotation of said bowl, said force inducing the coupling in rotation of said bowl (3) and said member (11).   8. Projector according to claim 7, characterized in that said coupling means (4, 52-54) are arranged such that said force (F3) is substantially axial.   9. Projector according to one of claims 7 or 8, characterized in that said bowl (3) and said member (11) are provided respectively with portions (38, 12) of complementary forms (38a, 12a) of coupling. rotation by adhesion.   10. Projector according to one of claims 7 to 9, characterized in that said coupling means comprise at least one magnet (52) arranged annularly about the axis (X-X ') of rotation of said bowl (3). ) and fixed on said non-rotating part (5, 15), whereas the coupling means (4) carried by said bowl define an annular or frustoconical surface (S42) delimiting an air gap (e) between said coupling means (4) carried by said bowl and said magnet and that the radial width (142) of said surface is greater than the radial width (152) of said magnet.   11. Projector according to claim 10, characterized in that the average radius (R42) of said surface (42) is substantially equal to the average radius (R52) of said magnet (52).   12. Projector according to one of claims 10 or 11, characterized in that said magnet (52) is bordered radially, internally and externally, by two volumes (53, 54) of non-magnetic material or low magnetic permeability, while the radial width (142) of said surface (S42) is greater than the radial width (152) of said magnet increased by the radial width (153, 154) of said volumes.   13. Headlight according to claim 12, characterized in that the radial widths (153, 154) of each of said volumes (53, 54) are greater than the air gap (e) between said surface (S42) and said magnet (52). preferably at least three times greater than said gap, more preferably of the order of five times said gap.   14. Projector according to one of claims 12 or 13, characterized in that said surface (S42) projects radially, inwardly and outwardly, relative to said magnet (52) and said volumes (53, 54). , an overflow (dl, d2) at least greater than the gap (e) between said surface and said magnet, preferably at least three times greater than said gap, more preferably of the order of five times said air gap.   15. Spotlight according to one of claims 7 to 14, characterized in that a portion (52-54) of said magnetic coupling means (4, 52-54) is integrated in an annular support (5) attached to the body (15) of said projector (P) and extending axially.   16. Projector according to one of claims 7 to 15, characterized in that the air gap (e) between the portions (4, 52) of said coupling means (4, 52-54) magnetic respectively integral with said bowl (3) and said non-rotating portion (5, 15) is such that said axial force (F3) has an intensity of between 5 and 20 daN.   17. Projector according to one of claims 7 to 16, characterized in that said bowl (3) and / or said drive member (11) is provided with at least one clearance (38b, 12b) mounting / dismounting .   18. Headlamp according to one of claims 7 to 17, characterized in that an air flow (E) is provided in the air gap (e) between said magnetic coupling means (4, 52-54).   19. Apparatus (I) for projecting coating product, characterized in that it comprises at least one projector (P) according to one of claims 7 to 18.