US3547672A - Electrostatically coating the outer surface of hollow objects with flock - Google Patents

Electrostatically coating the outer surface of hollow objects with flock Download PDF

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US3547672A
US3547672A US822751*A US3547672DA US3547672A US 3547672 A US3547672 A US 3547672A US 3547672D A US3547672D A US 3547672DA US 3547672 A US3547672 A US 3547672A
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flock
objects
flocking
conveyor
electrodes
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US822751*A
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Walter Linneborn
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Singer Co
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Singer Co
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B05SPRAYING OR ATOMISING IN GENERAL; APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
    • B05CAPPARATUS FOR APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
    • B05C19/00Apparatus specially adapted for applying particulate materials to surfaces
    • B05C19/001Flocking
    • B05C19/002Electrostatic flocking

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  • the flock dispensers may be isolated by a field of alternating voltage from the flock applicator zone.
  • the movable electrodes rotate in the applicator zones and the excess flock material may be recycled to the dispensers.
  • This invention relates to coating the outer surface of hollow objects with flock. More particularly, the invention relates to electrostatic flocking.
  • One object of the present invention is to provide an improved apparatus of the above-mentioned type that causes practically all the flock dispensed at the flocking station to reach the treated object and to adhere thereto, so that there is no pollution of the machine itself not on its surroundings by flock, which is diflicult to remove when it forms a layer on the machine parts.
  • the invention proposes guiding the conveyor means successively through a plurality of flocking stations, the sliding contacts on the holders being applied to insulated grounded guide rail sections between said stations.
  • This simple expedient produces the surprising result that the flock no longer strays uncontrolled to the outside or onto the outside of the apparatus and, further, flock no longer passes from one flocking station to the adjacent station; for example, large amounts of shorter fibers from neighboring stations are no longer caught by a particularly potent electrostatic field used for flocking with particularly long fibers.
  • the electrically conductive guide rail sections are connected to negative potential. .It has been found that due to this simple measure, all flock material reaches the objects which are being coated.
  • the electrically conductive rail portions may be connected to electrostatic generators of different voltages, for working 'with flock requiring electrostatic fields of different intensity.
  • the invention further provides grid electrodes disposed between the flocking stations and connected to alternating-current voltage. These electrodes prevent flock which has not yet reached the objects which are being coated from leaving the range of the electrostatic field to which it has been delivered.
  • special boxes may be used for feeding the material, the boxes being screened by electrodes subject to alternating voltage. Like the electrodes separating the successive flocking stations, these electrodes may be grid electrodes.
  • a collector device for excess flock material is disposed underneath the terminal point of reversal for the conveyor belt facing away from the box, the collector device being connected to a pneumatic conveyor device leading to the feed box.
  • the collector device consists preferably of a hopper for proper introduction of excess flock into the pneumatic conveyor device, the lower end of the hopper opening into a nozzlelike constricted spot in a tube forming part of the conveyor device.
  • the flocking process may be carried out without hitch and a faultless product may be obtained only if care is taken of proper conditioning, that is to say, if the flock material is moistened as required at any given time.
  • a particularly simple and effective solution for achieving the required moistening is provided in this invention, in that a sprayer device is provided at the air inlet of the pneumatic conveyor device. The air stream thereby assumes a twofold task, namely, first, to transport the excess flock back and, second, to transmit moisture for maintaining the required humidity.
  • FIG. 1 is a schematic top view of apparatus embodying the principles of the invention
  • FIG. 2 is a schematic view in side elevation of the apparatus showing flock feed, recovery and conditioning devices, and
  • FIG. 3 is a top plan view of a support device for holding an article to be fiocked.
  • Hollow objects 1, such as hat bodies, which have already been coated with a suitable glue and are now to be coated with flock, may be supported by holders or arms 2.
  • the holders 2 are secured, in a manner per se known, to a conveyor means, such as an endless chain 30 running around two sprocket wheels 31 and 32 for transporting the holders 2 and thereby also the objects 1 along a substantially elliptical path.
  • the objects 1 are preferably disposed on the holders 2 with the closed end of the hat bodies leading as they are moved forward by the conveyor in the direction indicated by the arrow P.
  • the holders 2 may be suitably angled, as shown, and may be provided with rotatable supports 34, so that the entire surface of each object 1 may be exposed uniformly to the electrostatic field present at the flocking stations.
  • rotation of the objects 1 about an axis which is horizontal in the illustrated embodiment can be achieved by a shaft 3 supported in the forwardly angled arm 2 and connected via beveled gears 4 to a shaft 5 supported in the section of the arm 2 which projects transversely from the conveyor means 30.
  • a toothed gear 35 may be secured, the gear 35 being in engagement with a toothed rack 39 or the like within the range of rotation of the workpiece 1 on the holder.
  • the metal holding assembly 2, 3, 4, S is equipped with a (schematically represented) sliding contact 6 with which it slides on a guide rail 7.
  • the guide rail 7 comprises conductive section 7' and nonconductive sections 7".
  • the conductive sections 7 are disposed so that the connection to the holders 2 is electrically conductive within the regions of the flocking stations, while, when passing from one station to the succeeding station, the holders 2 are without a conductive connection as a result of their contacts 6 sliding over the nonconductive rail portions 7".
  • the conductive rail sections 7 are connected to suitable electrostatic generators (not shown) which supply the high voltage required for carrying out the process.
  • the holder 2 which reaches into the interior of the hollow object 1, forms an electrode which is effective only when it is passing through a charging station.
  • the two other electrodes required for carrying out the process and which are connected to a potential different from that of the holders 2, are disposed within the flocking stations above and below the regions which are contacted by the objects 1.
  • the flocking stations are designated A, B and C.
  • a conveyor belt 10a, 10b, 10c disposed below the holders 2 carrying objects 1, conveys flock material from boxes 11, in the direction of the arrows Q toward the conveyor means.
  • gridlike lower electrodes 36 are provided, each preferably having platelike counter-electrodes 37 secured above the holders 2.
  • the electrodes 36 and 37 may be connected to potentials of different power, and similarly the holder 2 (acting as a counter-electrode via the sliding contact 6 and the conductive rail sections 7 within the various stations) may be connected to potentials of different magnitude.
  • a grid electrode 12 connected to alternating voltage may be provided between the stations A and B.
  • a grid electrode with two sections 13 and 13' may be provided between the stations B and C, again comprising several wires connected to alternating voltage.
  • a distance of, for example 2 cm. may be provided between the wires of the grid electrodes.
  • the corresponding nonconductive section 7 of the guide rail 7 may be provided with a bridge which, when not required, may be removed or interrupted.
  • Adjustable high voltage electrostatic generators are preferably connected to the conductive sections 7' of the guide rail, the generators being of the type known in connection with cable testing devices and with other technological uses which require direct voltage.
  • FIG. 2 illustrates the devices for feeding the flock material, for recovering excess material and for conditioning the same.
  • the storage container or box 11 for flock is provided with a screenlike floor 15.
  • An endlessbelt 16 is disposed closely above the floor 1S, and its width corresponds to that of the box 11.
  • brushes 17 are secured at uniform intervals and extend across the entire width of the belt 16.
  • the distance of the lower run 16a of the belt from the floor 15 is somewhat less than the length of the brushes 17, so that the brushes moving on the lower run of the belt brush over the screen floor 15.
  • substantially semi-circular guide surfaces 18, extending concentrically to the turns 16b, are secured in the container 11, and their lower ends are joined to the screen floor 15.
  • a conveyor belt a, 10b, or 100 is provided below each box 11 for receiving flock falling through the floor 15 and bringing it into the effective range of the electrostatic field.
  • the excess flock remaining on the belt 10a, 1012, or 100 is deposited into a collector hopper 19 at a turn 10:: of the belt 10, a brush roller 20 being provided at the turn 38 to take care of thorough cleaning of the belt.
  • the lower end of the hopper 19 leads into a conveyor conduit 24 which is constructed at the outlet 22 of the hopper 19 in the manner of a nozzle.
  • a fan 21 blows an air current through the tube 24, which entrains the flock passing through the hopper 19.
  • the tube 24 enters into the box 11 at an inlet 23, the box 11 having an air filter 27 at its upper end, through which air can escape to atmosphere while the flock carried along by it is held back.
  • Flock of different materials used for electrostatic flocking requires different degrees of humidity for insuring a faultless flocking process.
  • this humidity which is instrumental in rendering the flock receptive to the effect of electrostatic fields, is added to the air stream. This not only imparts the required humidity to the recovered flock, but also suitably wets the storage supply in the container 11. Air sucked in by the fan 21 is sucked through an atomizer assembly 25 in which a rapidly swinging member generates a mist of finely divided water droplets in the sucked-in air stream, in known manner.
  • a hydrometer 26 for adjusting the desired humidity content is mounted in the container 11 and is operatively connected to the assembly 25 for controlling its operation in dependence on the desired value.
  • the length of the conveyor tube 24 between the discharge outlet 22 of the hopper 19 and the container 11, that is, the length of the course within which the recovered flock is exposed to moistened air, is also of importance for a faultless operation, so that a possibility is advantageously provided for altering the length of the tube depending on the flock material employed.
  • the operation of the device illustrated in FIG. 2 is as follows: As it rotates in the chambers or compartments between the successive transverse rows of brushes 17, in the lower part of the box 11 filled with flock material, the conveyor belt is filled with a certain amount of such flock material which it receives from the bottom layer of the storage supply. Since the curved guide surfaces 18 surround the turns of the conveyor belt 16, the flock material cannot become bunched-up by additional material squeezing into the gap, which is usually present at the turn and tapers in the direction of the movement. On the contrary, the guide surfaces 18 insure that the amount of fill between the brushes at the turn remains unchanged. This avoids launching-up of the flock materials, and breakdowns of the plant are thereby avoided.
  • the flock material which has trickled down onto the conveyor belt 10b is used for flocking the hollow objects 1, as explained hereinabove.
  • the excess flock received by the hopper 19 arrives laterally into the nozzlelike constricted sector 22 of the conveyor tube 24 and is carried back into the box 11 by the air current generated by the fan 21, the flock absorbing, mostly superficially, the moisture from the air which had been added thereto by means of the atomizer assembly 25.
  • the thus moistened flock and the air still containing moisture, are introduced at the inlet 23 into the container 11, whence the air escapes to atmosphere through the air filter 22, which holds the flock back.
  • a method for flocking the outer surface of a plurality of separate hollow objects so that each object has a plurality of different kinds of flock properly applied thereto comprising the steps of:
  • the method of claim 1 including the step of furthering the isolation of the successive electrostatic fields by following each said field in each instance with a field of alternating voltages through which said objects pass.
  • each said object is continually rotated during at least the flock applying steps.
  • each electrostatic field provides a different potential, suited to the proper application of the type of flock therein applied.

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  • Electrostatic Spraying Apparatus (AREA)

Description

W. LINNEBORN- ELECTROSTATICALLY COATING THE OUTER SURFACE Dec. 15, 1970 HOLLOW OBJECTS WITH FLOCK 19, 1965 I 3 Sheets-Sheet 1 Original Filed Oct In ventor: WAL TE L INA/[BORN 0w. MM f L EQS 333:8
. 3355a uzsheaul ATTORNEYS Dec. 15, 1970 w. LINNEBORN 3,547,672
ELECTROSTATICALLY COATING THE OUTER SURFACE OF HOLLOW OBJECTS WITH FLOCK Original Filed Oct. 19,, 1965 ssheets-sheet 2 In ventor: WAL TE)? Ll/WVEBORN 00, (L/QL-LIJQAM.
4 r mR/vE rs Dec. 15, 1970 w. LINNEBORN 3,547,672
ELECTROSTATICALLY COATING THE OUTER SURFACE OF HOLLOW OBJECTS WITH FLOCK Original Filed m. 19, 1965 s Sheets-Sheet a Inventor; WAL TE? 1. II'WVE'BO FW ATTORNEYS United States Patent Int Cl. B05b 5/00; B44c N08 US. Cl. 11717 9 Claims ABSTRACT OF THE DISCLOSURE An electrostatic method of applying different types of flock material to the outside of adhesively coated hollow objects mounted on movable electrodes. As the electrodes move through the different flock application zones a po tential is applied to attract the flock up to the object. Between the application zones no potential is applied and field alternating voltage is applied to isolate and prevent mixing of the different flock. The flock dispensers may be isolated by a field of alternating voltage from the flock applicator zone. The movable electrodes rotate in the applicator zones and the excess flock material may be recycled to the dispensers.
This application is a division of application Ser. No. 497,975, filed Oct. 19, 1965.
This invention relates to coating the outer surface of hollow objects with flock. More particularly, the invention relates to electrostatic flocking.
In a prior art flocking apparatus used for making paint rollers to apply paint on walls and ceilings of rooms, the surface of a roller-type object mounted on a holder that is secured to a chain, is coated with adhesive and then is guided between two electrodes while rotating. With the aid of an air current, fibrous material is blown into the space between the two platelike electrodes, where an electrical field is present. The effect of the lines of force is to position the fibrous material radially in relation to the rollers and to form a brushlike deposit thereon, each hair or each fiber being secured in the adhesive by one of its ends. The rollers carrying the holders are connected to positive voltage by means of sliding contacts, while the electrodes carry negative voltage.
A problem with this prior art device has been that a considerable proportion of the fibers delivered to the flocking station failed to adhere to the adhesive-coated object, and, notwithstanding the presence of the electrical field, escaped to the outside. It was therefore necessary to work with suction hoods so as to keep the atmosphere free of such fibers in the region of the flocking device. However, not only did the installation of such suction devices involve additional costs, but considerable losses of flock material resulted, and it was diflicult to recover such material from the evacuated air.
One object of the present invention is to provide an improved apparatus of the above-mentioned type that causes practically all the flock dispensed at the flocking station to reach the treated object and to adhere thereto, so that there is no pollution of the machine itself not on its surroundings by flock, which is diflicult to remove when it forms a layer on the machine parts.
When a plurality of flocking stations is used in series in conventional apparatus, the freely floating flock often penetrates into the range of the adjacent station where,
3,547,672 Patented Dec. 15, 1970 due to the effect of the electrostatic field, part of it is deposited on the object which is being coated there. This, however, is a considerable disadvantage since, for many uses, the objects must be flocked successively, for example with flock of different length or color, each kind of flock being applied separately and not in admixture with others.
In order to avoid these difliculties, the invention proposes guiding the conveyor means successively through a plurality of flocking stations, the sliding contacts on the holders being applied to insulated grounded guide rail sections between said stations. This simple expedient produces the surprising result that the flock no longer strays uncontrolled to the outside or onto the outside of the apparatus and, further, flock no longer passes from one flocking station to the adjacent station; for example, large amounts of shorter fibers from neighboring stations are no longer caught by a particularly potent electrostatic field used for flocking with particularly long fibers.
In accordance with a further proposal of the invention, the electrically conductive guide rail sections are connected to negative potential. .It has been found that due to this simple measure, all flock material reaches the objects which are being coated. In accordance with a further proposal of the invention, the electrically conductive rail portions may be connected to electrostatic generators of different voltages, for working 'with flock requiring electrostatic fields of different intensity.
In order to achieve complete separation of the flocking stations so that flock material from one station cannot reach the adjacent station, the invention further provides grid electrodes disposed between the flocking stations and connected to alternating-current voltage. These electrodes prevent flock which has not yet reached the objects which are being coated from leaving the range of the electrostatic field to which it has been delivered.
To prevent flock material from moving back into the charging device before the adhesive has secured it to the objects which are being coated, special boxes may be used for feeding the material, the boxes being screened by electrodes subject to alternating voltage. Like the electrodes separating the successive flocking stations, these electrodes may be grid electrodes.
To obtain a uniformly flocked product, it is important for the feed of {the flock onto the conveyor belt to be uniform. Such uniform feed is particularly difficult to achieve with the flock material here involved because, first, the material tends to accumulate or bunch-up when being moved and, second, while moving it absorbs electrostatic charges even without the presence of an exterior field.
It has now been found that faultless feed of flock from the boxes to the conveyor belt may be achieved by constructing the box floor as a screen and by rotating above the screen floor an endless conveyor with brushes disposed transversely to the direction of the movement of the conveyor. The brushes passing the lower run of the conveyor brush over the screen floor, while, at the turns of the conveyor, guide surfaces are provided which are concentric to the turns and surround the turn at an angle of about This arrangement insures uniform feed of flock through the screen floor regardless of the level of fill in the box, and the guide surfaces at the turns insure that flock does not accumulate or bunch up particularly at the point of reversal where the conveyor runs downwardly. Thus, compartments, as it were, filled with flock, are created between the individual rows of brushes, and they cannot decrease when entering the turn, nor can additional flock squeeze into them at the turn.
Of particular importance also is the recovery of flock material which did not reach the object being treated. The
invention provides a particularly advantageous solution in that a collector device for excess flock material is disposed underneath the terminal point of reversal for the conveyor belt facing away from the box, the collector device being connected to a pneumatic conveyor device leading to the feed box. The collector device consists preferably of a hopper for proper introduction of excess flock into the pneumatic conveyor device, the lower end of the hopper opening into a nozzlelike constricted spot in a tube forming part of the conveyor device.
The flocking process may be carried out without hitch and a faultless product may be obtained only if care is taken of proper conditioning, that is to say, if the flock material is moistened as required at any given time. A particularly simple and effective solution for achieving the required moistening is provided in this invention, in that a sprayer device is provided at the air inlet of the pneumatic conveyor device. The air stream thereby assumes a twofold task, namely, first, to transport the excess flock back and, second, to transmit moisture for maintaining the required humidity.
The invention is described hereinbelow in connection with the attached drawings showing the apparatus in simplified representation.
In the drawings:
FIG. 1 is a schematic top view of apparatus embodying the principles of the invention,
FIG. 2 is a schematic view in side elevation of the apparatus showing flock feed, recovery and conditioning devices, and
FIG. 3 is a top plan view of a support device for holding an article to be fiocked.
Hollow objects 1, such as hat bodies, which have already been coated with a suitable glue and are now to be coated with flock, may be supported by holders or arms 2. The holders 2 are secured, in a manner per se known, to a conveyor means, such as an endless chain 30 running around two sprocket wheels 31 and 32 for transporting the holders 2 and thereby also the objects 1 along a substantially elliptical path. The objects 1 are preferably disposed on the holders 2 with the closed end of the hat bodies leading as they are moved forward by the conveyor in the direction indicated by the arrow P. The holders 2 may be suitably angled, as shown, and may be provided with rotatable supports 34, so that the entire surface of each object 1 may be exposed uniformly to the electrostatic field present at the flocking stations. As can be seen from FIGS. 2 and 3, rotation of the objects 1 about an axis which is horizontal in the illustrated embodiment, can be achieved by a shaft 3 supported in the forwardly angled arm 2 and connected via beveled gears 4 to a shaft 5 supported in the section of the arm 2 which projects transversely from the conveyor means 30. To the inner end of the shaft 5, a toothed gear 35 may be secured, the gear 35 being in engagement with a toothed rack 39 or the like within the range of rotation of the workpiece 1 on the holder.
The metal holding assembly 2, 3, 4, S is equipped with a (schematically represented) sliding contact 6 with which it slides on a guide rail 7. The guide rail 7 comprises conductive section 7' and nonconductive sections 7". The conductive sections 7 are disposed so that the connection to the holders 2 is electrically conductive within the regions of the flocking stations, while, when passing from one station to the succeeding station, the holders 2 are without a conductive connection as a result of their contacts 6 sliding over the nonconductive rail portions 7".
The conductive rail sections 7 are connected to suitable electrostatic generators (not shown) which supply the high voltage required for carrying out the process. Thus, the holder 2 which reaches into the interior of the hollow object 1, forms an electrode which is effective only when it is passing through a charging station.
The two other electrodes required for carrying out the process and which are connected to a potential different from that of the holders 2, are disposed within the flocking stations above and below the regions which are contacted by the objects 1.
In the embodiment illustrated in the drawing, the flocking stations are designated A, B and C. In each, a conveyor belt 10a, 10b, 10c, disposed below the holders 2 carrying objects 1, conveys flock material from boxes 11, in the direction of the arrows Q toward the conveyor means. Above the belts 10a, 10b, and 100 of the stations A, B and C, gridlike lower electrodes 36 are provided, each preferably having platelike counter-electrodes 37 secured above the holders 2. At the different flocking stations A, B and C the electrodes 36 and 37 may be connected to potentials of different power, and similarly the holder 2 (acting as a counter-electrode via the sliding contact 6 and the conductive rail sections 7 within the various stations) may be connected to potentials of different magnitude. Thus it is possible to adjust the intensity of the electrical field to the flock material being used at any given time, so that different materials may be workedup successively at the various stations.
When the conductive sections of the guide rail are connected to negative potential, for example 60,000 v., and when a suitable potential differential is generated by means of the electrodes 36 and 37 disposed above and below the holders 2 in the region of the belts at the stations A, B and C, all flock fed by means of the belts 10a, 10b, and 100 travels to the object 1 which is to be treated, while the object 1, driven by the endless conveyor 30, travels over its respective belt in a direction transverse to the latter.
In order to prevent flock material from passing from station A to station B where a different potential differential is possibly being employed because a different flock material is possibly being used there, a grid electrode 12 connected to alternating voltage may be provided between the stations A and B. Correspondingly, a grid electrode with two sections 13 and 13' may be provided between the stations B and C, again comprising several wires connected to alternating voltage. A distance of, for example 2 cm. may be provided between the wires of the grid electrodes. These grid electrodes 12, 13, and 13" prevent flock material from straying from one station to an adjacent station, so that the apparatus in accordance with the invention operates without any pollution of the machine parts or of the surrounding area.
To screen the boxes 11 also against the action of the electrical fields, further grid electrodes 14 under alternating tension are disposed at the outlets of the boxes.
When the holders 2 at two adjacent stations A and B are to be connected to the same potential, the corresponding nonconductive section 7 of the guide rail 7 may be provided with a bridge which, when not required, may be removed or interrupted.
Adjustable high voltage electrostatic generators are preferably connected to the conductive sections 7' of the guide rail, the generators being of the type known in connection with cable testing devices and with other technological uses which require direct voltage.
In the case of an apparatus of the type described which had been tested in practice, the speed of conveyance of the hollow objects was 1.5-5 meters per minute. When working with flock of 10 mm. length, the objects 1 were sufficiently covered after revolving twice and, when flock was fed on all three belts, after two revolutions. When flocking with lo-millimeter-long synthetic flock, a voltage of 40 kv. was used with an air humidity of FIG. 2 illustrates the devices for feeding the flock material, for recovering excess material and for conditioning the same. The storage container or box 11 for flock is provided with a screenlike floor 15. An endlessbelt 16 is disposed closely above the floor 1S, and its width corresponds to that of the box 11. On the smooth surface of the conveyor belt 16, brushes 17 are secured at uniform intervals and extend across the entire width of the belt 16.
The distance of the lower run 16a of the belt from the floor 15 is somewhat less than the length of the brushes 17, so that the brushes moving on the lower run of the belt brush over the screen floor 15. At the terminal points of reversal of the belt 16, substantially semi-circular guide surfaces 18, extending concentrically to the turns 16b, are secured in the container 11, and their lower ends are joined to the screen floor 15.
As already explained in connection with FIG. 1, a conveyor belt a, 10b, or 100 is provided below each box 11 for receiving flock falling through the floor 15 and bringing it into the effective range of the electrostatic field.
The excess flock remaining on the belt 10a, 1012, or 100 is deposited into a collector hopper 19 at a turn 10:: of the belt 10, a brush roller 20 being provided at the turn 38 to take care of thorough cleaning of the belt. The lower end of the hopper 19 leads into a conveyor conduit 24 which is constructed at the outlet 22 of the hopper 19 in the manner of a nozzle. A fan 21 blows an air current through the tube 24, which entrains the flock passing through the hopper 19. The tube 24 enters into the box 11 at an inlet 23, the box 11 having an air filter 27 at its upper end, through which air can escape to atmosphere while the flock carried along by it is held back.
Flock of different materials used for electrostatic flocking requires different degrees of humidity for insuring a faultless flocking process. In accordance with the advantageous embodiment illustrated in FIG. 2, this humidity which is instrumental in rendering the flock receptive to the effect of electrostatic fields, is added to the air stream. This not only imparts the required humidity to the recovered flock, but also suitably wets the storage supply in the container 11. Air sucked in by the fan 21 is sucked through an atomizer assembly 25 in which a rapidly swinging member generates a mist of finely divided water droplets in the sucked-in air stream, in known manner.
A hydrometer 26 for adjusting the desired humidity content is mounted in the container 11 and is operatively connected to the assembly 25 for controlling its operation in dependence on the desired value. The length of the conveyor tube 24 between the discharge outlet 22 of the hopper 19 and the container 11, that is, the length of the course within which the recovered flock is exposed to moistened air, is also of importance for a faultless operation, so that a possibility is advantageously provided for altering the length of the tube depending on the flock material employed.
The operation of the device illustrated in FIG. 2 is as follows: As it rotates in the chambers or compartments between the successive transverse rows of brushes 17, in the lower part of the box 11 filled with flock material, the conveyor belt is filled with a certain amount of such flock material which it receives from the bottom layer of the storage supply. Since the curved guide surfaces 18 surround the turns of the conveyor belt 16, the flock material cannot become bunched-up by additional material squeezing into the gap, which is usually present at the turn and tapers in the direction of the movement. On the contrary, the guide surfaces 18 insure that the amount of fill between the brushes at the turn remains unchanged. This avoids launching-up of the flock materials, and breakdowns of the plant are thereby avoided.
When passing over the screen floor 15, the fill of flock corresponding to the size of the compartment between two brushes 17 is simultaneously brushed through said screen floor 15. It has been found that the trickle of flock material through the screen 15 is particularly good and uniform if the mesh size of the screen floor 15 corresponds substantially to the length of the flock fibers. Any fibers which may have remained in the compartment formed between the two rows of brushes after they have passed over the screen floor 15, are taken along upwardly at the second turn, the semicircularly curved guide surfaces again taking care that flock material should not form little lumps.
The flock material which has trickled down onto the conveyor belt 10b is used for flocking the hollow objects 1, as explained hereinabove. The excess flock remaining on the belt or falling back thereon, falls into the collector hopper 19' at the turn 38, the brush roller 20 accomplishing thorough cleaning of the belt. The excess flock received by the hopper 19 arrives laterally into the nozzlelike constricted sector 22 of the conveyor tube 24 and is carried back into the box 11 by the air current generated by the fan 21, the flock absorbing, mostly superficially, the moisture from the air which had been added thereto by means of the atomizer assembly 25. The thus moistened flock and the air still containing moisture, are introduced at the inlet 23 into the container 11, whence the air escapes to atmosphere through the air filter 22, which holds the flock back.
The invention is not, of course, limited to the illustrated and described embodiment, but can be employed, within the scope of the underlying inventive concept, in the most varied ways, supplemented, and combined.
I claim:
1. A method for flocking the outer surface of a plurality of separate hollow objects so that each object has a plurality of different kinds of flock properly applied thereto, comprising the steps of:
supporting each object separately upon a movable electrode that extends within said hollow object, and separating the objects from each other during the following step,
applying adhesive to each of said objects,
electrostatically applying flock to each of said objects separately by passing said objects through a plurality of electrically isolated electrostatic fields, while supplying each said field with a. different type of flock material and while subjecting each of said objects to electrical potential in each said field by charging said movable electrode oppositely to a different stationary electrode for each said field outside each of said objects,
maintaining the isolation of each said field and preventing the mixing of the different types of flock by grounding said movable electrode between successive fields, and
then drying said adhesive.
2. The method of claim 1 including the step of furthering the isolation of the successive electrostatic fields by following each said field in each instance with a field of alternating voltages through which said objects pass.
3. The method of claim 2 wherein each said object is continually rotated during at least the flock applying steps.
4. The method of claim 1 wherein the flock material is fed from storage into its said electrostatic field through an alternating voltage field that isolates said storage from said field and prevents electrostatic effects within said storage.
5. The method of claim 1 wherein at each said electrostatic field the movable electrode is negatively charged.
6. The method of claim 1 wherein each electrostatic field provides a different potential, suited to the proper application of the type of flock therein applied.
7. The method of claim 1 wherein the flock at each electrostatic field is supplied below the level of said object and its electrodes so that the electrostatic application moves the flock counter to gravity.
8. The method of claim 7 wherein the flock is supplied to each said electrostatic field as a uniform sheet-like deposit moving perpendicular to the direction of movement of said object and along a lower plane.
9. The method of claim 1 wherein the flock applied in each said electrostatic field but not adhering to said object is recovered and pneumatically recirculated to its storage, the air for pneumatic recirculation being humidified and passing from storage into that said electrostatic field to maintain the proper humidity Within that said References Cited UNITED STATES PATENTS Benner et a1. 11725X 5 Meston et a1 117-17X Crompton 11717X Hiers 11717 Hiers 11717 Burridge Hug 118621 Lindguist 118-636 Thackara et a1. 118-630X 8 Juvinall 118-626X Klein 117-25 Schwartz et a1. 11725X Okma et a1. 11717X Roberts et a1 118-622X Barford et a1 118622X Burns et al 11717 WILLIAM D. MARTIN, Primary Examiner 118 638X 10 E. J. CABIC, Assistant Examiner US. Cl. X.R.
US822751*A 1965-03-05 1968-09-23 Electrostatically coating the outer surface of hollow objects with flock Expired - Lifetime US3547672A (en)

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Cited By (2)

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Publication number Priority date Publication date Assignee Title
US20030168877A1 (en) * 2000-03-16 2003-09-11 Esteban Miguel Angel Sabrido Flocked sun-visor
US20110052829A1 (en) * 2007-06-12 2011-03-03 Gerhard Brendel Coating method, coating station, and method for coating an object

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US4169903A (en) * 1977-06-10 1979-10-02 Ball Corporation Electrostatic process for coating electrically conductive objects such as beverage cans
US6048422A (en) * 1998-09-16 2000-04-11 Kim, Ii; John Method of applying glitter and the like to non-planar surfaces and three-dimensional articles
US20050050665A1 (en) * 2003-06-09 2005-03-10 Linda Mitchell Roller Cover
US20040248716A1 (en) * 2003-06-09 2004-12-09 Linda Mitchell Method for applying a flocking material to a foamable and sleeve shaped roller as well flock applied roller article used in applying a wallpaper adhesive or a gel removal fluid
WO2016051270A1 (en) * 2014-10-01 2016-04-07 Tamicare Ltd. Apparatus to produce 3d curved flocked articles

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US2358227A (en) * 1941-03-15 1944-09-12 Collins & Aikman Corp Simultaneous flocking
US2686733A (en) * 1951-07-17 1954-08-17 Dunlop Tire & Rubber Corp Production of pile fabrics
US2706963A (en) * 1949-07-05 1955-04-26 Hug Rudolf Device for fiber-coating materials and objects
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US2881087A (en) * 1954-10-28 1959-04-07 Velveray Corp Method and apparatus for flocking and removing excess flock
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US3411931A (en) * 1964-12-03 1968-11-19 Painter Corp E Z Electrostatic method of applying flock to a paint roller sleeve

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US2174328A (en) * 1935-02-06 1939-09-26 Behr Manning Corp Piled surface in pattern form
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US2231324A (en) * 1938-05-04 1941-02-11 Behr Manning Corp Apparatus for and method of making hat bats
US2358227A (en) * 1941-03-15 1944-09-12 Collins & Aikman Corp Simultaneous flocking
US2328904A (en) * 1941-04-02 1943-09-07 Collins & Aikman Corp Method of attaching and straightening flock
US2706963A (en) * 1949-07-05 1955-04-26 Hug Rudolf Device for fiber-coating materials and objects
US2686733A (en) * 1951-07-17 1954-08-17 Dunlop Tire & Rubber Corp Production of pile fabrics
US2806803A (en) * 1952-07-11 1957-09-17 Rubberset Company Method of making painting roller
US2759449A (en) * 1954-10-05 1956-08-21 Lindquist Theodore Flock applying machine
US2881087A (en) * 1954-10-28 1959-04-07 Velveray Corp Method and apparatus for flocking and removing excess flock
US2884341A (en) * 1955-03-07 1959-04-28 Ransburg Electro Coating Corp Electrostatic spray coating method
US2976839A (en) * 1955-08-29 1961-03-28 D & S Proc Company Inc Apparatus for making pile fabrics
US2900270A (en) * 1956-05-04 1959-08-18 Vertipile Inc Ornamental material and method for making same
US2992126A (en) * 1957-11-29 1961-07-11 Internat Ind Developers Inc Flocking machine and method
US3248253A (en) * 1962-06-22 1966-04-26 Sames Sa De Machines Electrost Electrostatic transfer method and apparatus for coating articles with a fluidized composition
US3411931A (en) * 1964-12-03 1968-11-19 Painter Corp E Z Electrostatic method of applying flock to a paint roller sleeve

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20030168877A1 (en) * 2000-03-16 2003-09-11 Esteban Miguel Angel Sabrido Flocked sun-visor
US6945586B2 (en) * 2000-03-16 2005-09-20 Fico I.T.M. S.A. Flocked sun-visor
US20110052829A1 (en) * 2007-06-12 2011-03-03 Gerhard Brendel Coating method, coating station, and method for coating an object

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