Method and equipment for powder spray coating

Information

  • Patent Grant
  • 6217654
  • Patent Number
    6,217,654
  • Date Filed
    Monday, November 2, 1998
    26 years ago
  • Date Issued
    Tuesday, April 17, 2001
    23 years ago
Abstract
Powder spray coating equipment includes a spraying system (2), an injector (26) to pneumatically convey powder to the spraying system (2), and at least one flushing-air intake (73) to supply flushing compressed air into the air/powder path at a flushing-air supply site where the flow impedance to the flushing compressed air is less everywhere in the downstream direction through the spraying system (2) than in the upstream direction as far as through the injector (26) in order to drive flushing compressed air from the flushing air intake (73) through the air/powder path and out of the spraying system (2).
Description




TECHNICAL FIELD




The invention concerns a method and equipment for powder-spray coating of objects




BACKGROUND ART




Powder-coating equipment is known from the European patent application EP 0,718,043 A1 wherein a conveying airflow generates a partial vacuum in a vacuum zone of an injector and thereby sucks powder out of a container and moves it into a powder line. Downstream of the vacuum zone, supplemental air is supplied through a supplemental-air intake to the flow of conveying air and powder in order to implement a predetermined flow of total air.




European patent 0,412,289 B1 discloses electrostatic powder coating equipment having an injector fed with conveying and with supplemental air. The supplemental air can be conveyed as control air into the injector vacuum zone.




German Offenlegungsschrift DE 44 19 987 A1 discloses an injector/conveyor system to move coating powder, having a suction pipe connected to the injector vacuum zone and running downward into a powder container, whereby powder is sucked from this container into the vacuum zone. Compensating air is fed to the suction pipe end located remote from the vacuum zone to compensate for fluctuations in the suction amplitude. As shown by U.S. Pat. No. 3,746,254, the powder container can also be mounted above the injector vacuum zone, instead of underneath, whereby the powder suction aperture is located above the vacuum zone.




European patent application EP 0,769,327 A1 discloses powder coating equipment wherein the injector is located at the lower end of a pipe which is immersible into a powder container in order to convey powder from it.




The present invention encompasses all the above embodiments and is not restricted to any particular embodiment.




It is known with respect to powder coating equipment to cleanse the powder line of deposited powder particles from time to time, usually with a hose and spray apparatus, This procedure is required to preclude unchecked discharge of deposited, old powder particles which would interfere with coating the surface of an object. Ordinarily, compressed air is connected to the injector to flush the powder hose and the spray apparatus by being blown through the injector and the powder hose and spray apparatus. This known flushing procedure incurs a drawback in that the flushing air not only flows to the spray apparatus, but also divides inside the injector into other lines communicating with it. The known systems suffer from a further drawback in that the powder coating operation must be stopped when cleansing with flushing air and that later the conveying air and any supplemental air must be readjusted to the desired pressure levels and rates of conveyed powder. While powder deposits in the powder hose can be markedly reduced by using a hose made of an appropriate material, nevertheless, when dealing with great hose lengths, the quantity of deposited powder particles remains comparatively high.




The object of the invention is to achieve very high quality coating of a large series of objects without interfering with or interrupting this mass production on account of cleansing procedures or adjustments of the spray coating equipment. Illustratively, the invention enables mass-coating of automobile bodies with a surface quality as good as presently offered by liquid enamel. Accordingly, the object of the present invention is to place the highest requirements on powder coating quality regarding object adhesion, sealing of the powder coating after being baked onto the object, extreme uniformity and smoothness in the coating. The related method and equipment shall offer very high reliability in permanent operation.




SUMMARY OF THE INVENTION




A method for powder spray-coating objects utilizes pneumatic conveyance of powder from an injector to a spraying system having a spray coating zone through which objects are consecutively conveyed in an automated system. Power conveyance is interrupted between the consecutive objects as object gaps enter the spray coating zone while the conveying air flow is maintained by injection of controlling air into a vacuum zone of the injector which reduces the injector vacuum to a degree causing interruption of powder conveyance. Flushing compressed air may be injected between the injector and the spray device of the spraying system to automatically flush powder to maintain system integrity. Equipment for powder spray coating of objects utilizing the above method is also disclosed.











BRIEF DESCRIPTION OF THE DRAWING





FIG. 1

schematically depicts powder coating equipment of the invention (not to scale), and





FIG. 2

shows part of a further embodiment of powder coating equipment of the invention in which the omitted part is identical with the pertinent part of FIG.


1


.











BEST MODE FOR CARRYING OUT THE INVENTION




The powder spray coating equipment shown in

FIG. 1

contains a spraying system


2


comprising a spraying device


4


to spray coating powder on objects


6


, for instance automobile bodies, that are continuously conveyed along a conveyorized system


8


in the direction of an arrow


10


, transversely to and at the front side of the spraying device


4


, whereby these objects enter the spray coating zone of the spraying device. The objects


6


are separated from one another by a slight distance or gap


12


. The spraying device


4


may be a spray nozzle as shown in

FIG. 1

or a rotating unit, for instance a spray bell. The spraying device


4


is fitted with one or more high-voltage electrodes


14


to electrostatically charge the powder. The electrode


14


may project from a support tube


16


from which air passes over the electrode


14


to prevent powder particles from being deposited thereon. The high voltage for the electrode


14


may be generated by a high-voltage source mounted inside or outside the spraying system


2


. The spraying device


4


is located at the downstream end of a powder duct


18


of the spraying system


2


of which the upstream opening


20


communicates through a powder line


22


with the powder outlet


24


of an injector


26


. A conveying-air intake


28


is axially opposite the powder outlet


24


and is connected by a conveying-air line


30


containing a pressure regulator


32


and by a manifold


34


to a pressure source


36


. In the vicinity of the conveying-air intake


28


, an injector duct


38


comprises a vacuum zone


40


, hereafter called vacuum zone


40


, having a widened diameter and a reduced diameter powder-outlet duct


42


. A powder suction tube


46


runs from the vacuum zone


40


through a powder-intake aperture


44


into a powder container


48


, so that the conveying-air flow of the conveying-air line


30


causes a partial pressure, hereafter vacuum, in the vacuum zone


40


, to suck powder out of the powder container


48


and convey it through the powder line


22


to the spraying


5


system


2


which sprays the powder in the form of a spray cloud or spray cone onto the objects


6


.




A controlling-air intake


50


communicates with the vacuum zone


40


of the injector


26


and is connected by a controlling-air line


52


containing a pressure regulator


54


and by the manifold


34


to the compressed-air source


36


. By introducing controlling air into the vacuum zone


40


, the vacuum therein can be reduced to an extent, or eliminated, such that the powder conveyance from the container


48


is interrupted when the conveying air of the conveying-air line


32


flows at a constant rate through the injector


26


.




A supplemental-air intake


56


communicates with the powder-outlet duct


42


and is connected by a supplemental-air line


58


optionally containing a pressure regulator


60


and by the manifold


34


to the pressure source


36


. Together with the conveying air, the supplemental air provides a total air flow which prevents powder-flow pulses and substantial powder deposits in the powder line


22


. The total air flow might also be controlled using the controlling air from the controlling-air line


52


instead of the supplemental air of the supplemental-air line


58


, however, such a selection would be disadvantageous because the controlling air affects the vacuum effect in the vacuum zone


40


and hence the conveyor effect of the conveying air of the conveying-air line


30


and thereby the conveying air also would have to be changed if controlling air were used to compensate for changes in air flow in the powder line


22


. For that reason, the invention provides that the controlling air of the controlling-air line


52


is used only to negate the vacuum in the vacuum zone


40


in order to thereby shut down the conveyance of powder rather than only reduce it. During this stoppage of powder conveyance, the invention provides that, while an object gap


12


is present in front of the spray device


4


, the conveying air of the conveying-air line


30


and the supplemental air of the supplemental-air line


58


are fed unchanged to the injector


26


and to the powder line


22


. Powder conveyance is turned ON again once the next object


6


is in front of the spray device


4


by shutting OFF the controlling air of the controlling-air line


52


. The turning ON and OFF steps depend on conveyance rates and size of the objects


6


and is automated by a processor-controlled electronic control system


62


. The following advantages are achieved: when turning OFF powder conveyance, the residual powder is still being moved out of the powder/air path (


38


,


42


,


22


,


2


) and is sprayed by the spray device


4


. As a result, when the powder conveyance is again turned ON, a powder impact is prevented and hence also coating defects on the object


6


to be coated next. Preferably, the control system


62


is programmed in such manner that powder conveyance shall not be turned OFF at the object gap


12


, but shortly before the end of the object


6


that was just coated, whereby all the powder still present in the powder path shall still be deposited on this object without introducing coating defects. This procedure offers the further advantage of reducing powder loss, namely, powder not adhering to the objects


6


.




The suction tube


26


is fitted with a compensating-air intake


66


at its lower end segment


64


away from the injector


26


to move compressed air acting as compensating air into the suction tube


46


in order to compensate for or to damp any pressure fluctuations. The compensating-air intake


66


is connected by a compensating-air line


68


optionally containing a pressure regulator


70


to the manifold


34


of the compressed-air source


36


. The compensating air is supplied at constant pressure and constant flow both during powder conveyance and during pauses therein.




To keep the spraying system


2


and optionally also the powder line


22


clean, a flushing-air device


72


comprising at least one flushing-air intake


73


is provided. The flushing-air intake


73


is preferably situated at a site wherein the flow impedance to this flushing air in the air/powder path subtended by the powder line


22


, the spraying system


2


and the injector


26


will be smaller in the downstream direction as far as through the spraying system


2


than in the upstream direction through the injector


26


. As a result, the flushing air flows only toward the spray device


4


and then towards the objects


6


, not in the opposite direction to the injector


26


. Therefore the flushing-air intake


73


is located between the half length of the powder line


22


and the spray device


4


, and in a modified embodiment, several such sites or flushing-air intakes may also be provided. The more appropriate the material of the powder line


22


—which ordinarily is a hose—to preclude powder deposits inside it, the farther the flushing-air intake


73


can be shifted downstream toward the spray device


4


. The powder path in the spraying system


2


may consist of a similar material to reduce deposits of powder particles. The spray device


4


, even when of the same material, must be cleansed inside with flushing air because the powder particles not only slide along the inside surfaces of the spray device


4


, but also impinge transversely on these inside surfaces. Accordingly, preferred embodiments provide that the at least one flushing-air intake


73


be mounted at a flushing-air supply site located between the half length of the powder line


22


and the intake


20


preferably at about 75% downstream from the upstream end of the powder line


22


or directly at the powder intake


20


of the spraying system


2


, or, according to

FIG. 2

of the drawings, inside the spraying system


2


at a short upstream distance from the spray device


4


in order that the flushing air shall impinge free of throttling on the inside surfaces of the spray device


4


and shall flush away any powder particles.




In the embodiment of

FIG. 1

, the powder line


22


is a hose divided into an upward hose segment


22


-


1


of more than half-length and a short hose segment


22


-


2


substantially shorter than half the hose length. The two hose segments


22


-


1


and


22


-


2


communicate with each other through the flushing-air intake


73


which comprises an annular slit nozzle


74


. The flushing air flows from the slit nozzle


74


through the downstream hose segment


22


-


2


and then through the spraying system


2


, none of this flushing air flowing in the opposite direction to the injector


26


.




The flushing air is shut OFF during powder conveyance and is turned ON in the absence of powder conveyance either at each object gap


12


or only at one of several object gaps


12


in front of the spray device


4


. In a preferred embodiment of the invention, the flushing air is not supplied as a permanent flow of compressed air, but rather in the form of at least one, preferably at least two, three or four of brief, consecutive pulses of compressed air. To generate these impulsive compressed-air pulses, the flushing-air intake


73


is connected, through a compressed-air line


76


containing, in sequence of flow, a pressure regulator


78


, a pressure gauge


80


and a reversing valve


82


, to the compressed-air source


36


or its manifold


34


. Preferably, the reversing valve


82


is an electromagnetic or pneumatic two/two-way valve controlled by the electronic control


62


. The flushing-air intake


73


is fitted with a backflow stop


84


which may be a filter to filtrate powder particles and/or a check valve opening only in the direction of flow of the flushing air toward the flushing-air intake


73


but which will close when the fluid pressure is in the opposite direction. The compressed air used as flushing air is fed to the flushing-air intake


73


preferably at a rate of 15 to 40 Nm


3


/h and a pressure up to a maximum of 6 bars, preferably up to 5 bars. The pressure of the flushing air is correspondingly adjustable at its regulator


78


.




The flushing air can be turned ON either when all air hookups of the injector


26


are shut OFF or, in the preferred implementation, while all air hookups or at least the conveying air of the injector


26


remain ON. As a result and in this preferred implementation, while an object


6


to be coated is opposite the spray device


4


, conveying air from the conveying-air line


30


, supplemental air from the supplemental-air line


58


and compensating air from the compensating-air line


68


will flow through the spray device


4


; when, however, an object gap


12


is opposite the spray device


4


, and the powder conveyance is shut OFF due to the controlling-air supply from the controlling-air line


52


, then the supplemental air of the supplemental-air line


58


, the compensating air of the compensating-air line


68


, and, during the cleansing phase, the flushing air from the flushing-air intake


73


, will flow through the spray device


4


. In a special mode of implementation, the flushing air already is turned ON when an end segment of an object


6


to be coated still remains in the spray zone of the spray device


4


in order that all the powder for the coating procedure be used for coating. The powder coating on the object


6


thereby remains unaffected in thickness or other features when the powder conveyance also is turned OFF shortly ahead of the end of the object


6


that was just coated on account of turning ON the controlling air of the controlling-air line


52


and being moved into the vacuum zone


40


. The electronic control unit


62


assures time coordination of the diverse kinds of air.




In the embodiment of

FIG. 1

the flushing-air intake


73


comprises at least one annular slit nozzle


74


enclosing the air/powder path to preclude supplying to this path excessive flushing air and without need for especially high pressure. In the embodiment of

FIG. 2

the flushing-air intake


73


instead comprises a plurality of annular boreholes


75


issuing into the air/powder path. This embodiment achieves an effect similar to that obtained with an annular slit nozzle, however at a somewhat larger flow impedance. Preferably, both the annular slit nozzle


74


of FIG.


1


and the flushing-air boreholes


75


of

FIG. 2

are arranged obliquely at an angle of about 45° relative to the direction of the air/powder flow.



Claims
  • 1. Powder spray coating equipment comprising:a spraying system (2) including a spray device (4) to spray the powder onto an object (6) to be coated, an injector (26) to pneumatically convey powder from a powder container (48) to the spraying system (2), a powder line (22) connecting a powder outlet (24) of the injector (26) to a powder intake (20) of the spraying system (2) in such manner that the injector, the powder line and the spraying system together constitute an air/powder path, further comprising at least one supply site of flushing compressed air, located in the air/powder path between the spraying system and the injector at an intake location where the flow impedance to flushing compressed air is less in a downstream direction as far as through the spray device (4) than in an upstream direction as far as the injector (26), the air/powder path being fitted with at least one flushing-air intake (73) which is connected through an automatically switchable shutoff member (82) to a compressed-air source (78, 36) to drive flushing compressed air from the flushing-air intake (73) through the air/powder path out of the spraying system (2) wherein the at least one flushing-air intake (73) is located between the half length of the powder line (22) and the spray device (4) of the spraying system (2).
  • 2. Powder spray coating equipment as claimed in claim 1, wherein the at least one flushing-air intake (73) is located in the air/powder path between 75% of the length of the powder line (22) downstream of the injector (26) and the spray device (4).
  • 3. Powder spray coating equipment as claimed in claim 1, wherein the at least one flushing-air intake (73) is mounted at the powder intake (20) of the spraying system (2).
  • 4. Powder spray coating equipment as claimed in claim 1, wherein the at least one flushing-air intake (73) is mounted in the spraying system (2) upstream of the spray device (4) in such manner that the flushing compressed air flows without significant flow impedance directly onto the inside surfaces of the spray device (4) and flushes them.
  • 5. Powder spray coating equipment as claimed in claim 1, wherein that the flushing-air intake (73) issues in annular form from all sides into the powder-air path.
  • 6. Powder spray coating equipment as claimed in claim 5, wherein the flushing-air intake (73) comprises at least one annular slit nozzle (74).
  • 7. Powder spray coating equipment as claimed in claim 5, wherein the flushing-air intake (73) comprises a plurality of nozzle boreholes (75) issuing into the air/powder path and enclosing it annularly.
  • 8. Powder spray coating equipment as claimed in claim 1, wherein the flushing-air intake (73) is fitted with a check valve (84) automatically opening when the fluid pressure is in the direction of flow of the flushing air and automatically closing in the opposite direction.
  • 9. Powder spray coating equipment as claimed in claim 1, wherein the flow of flushing air is 15 to 40 Nm3/h.
  • 10. Powder spray coating equipment as claimed in claim 1, wherein the flushing air is supplied to the air/powder path at a pressure in the range of 2 to 6 bars.
  • 11. Powder spray coating equipment as claimed in claim 1, wherein the flushing compressed air guided into the air/powder path is pulsed compressed air, at least two pulses of compressed flushing air per flushing operation being guided into the air/powder path.
  • 12. Powder spray equipment as claimed in claim 11, wherein the duration of the compressed air pulses is from 0.5 to 3 seconds.
  • 13. Powder spray coating equipment as claimed in claim 12, wherein the time intervals between the pulses of the pulsed compressed flushing air are 0.5 to 3 seconds.
  • 14. Powder spray coating equipment as claimed in claim 1, further comprising a computer-controlled electrical control (62) actuating the compressed flushing air as a function of the displacement of objects (6) to be coated.
  • 15. Powder spray coating equipment as claimed in claim 1, wherein the injector is fitted with a supplemental compressed air connector (56, 58,60) at a site downstream of a vacuum zone (40) to convey supplemental air into the upstream beginning of the powder line (22) in addition to the conveying air (30).
  • 16. Powder spray coating equipment as claimed in claim 15 wherein a powder suction line (46) connected to the vacuum zone (40) is fitted at an end segment (64) away from the injector (26) with a compensating compressed-air intake (66) to compensate pressure fluctuations in [this] the powder suction line.
Priority Claims (1)
Number Date Country Kind
197 48 375 Nov 1997 DE
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