1. Field of the Invention
The present invention relates to a coating method and an atomizer, and more particularly to a coating technique using supersonic vibration.
2. Related Background Art
Some types of atomizers are currently known. They are rotary atomizers configured to atomize a coating material with a bell-shaped rotating member driven at a high speed, spray type atomizers configured to atomize a coating material by expelling it together with air from a nozzle, and hydraulic atomizers configured to atomize a compressed coating material by extruding it from a minute opening.
Rotary atomizers, in general, have a bell-shaped cup at one end of a rotary shaft of its main body as disclosed in Japanese Patent Laid-open Publication JP-H03-101858-A (equivalent to Japanese Patent No. 2600390), for example. A coating material supplied to the bell-shaped cup from a paint supply pipe spreads in form of a thin film along the inner surface of the bell-shaped cup radially outwardly under the centrifugal force, and it is next atomized while flying outwardly from the outer circumferential perimeter of the bell-shaped cup. Then, a shaping airflow drives the atomized coating material forward toward a work to be coated.
A known problem with rotary atomizers is irregularity of the grain size of the atomized coating material. Distribution of grain sizes includes two major peaks, i.e., one peak of a relatively large grain size and the other peak of a relatively small grain size. Irregularity of the grain size of the coating material invites instability of the film quality and degradation of the deposition efficiency of the coating material. This problem is known to occur in spray type atomizers and hydraulic atomizers as well.
It is therefore an object of the invention to provide an atomizer capable of supplying an atomized coating material uniformed in grain size.
Another object of the invention is to provide an atomizer capable of spraying a coating material without air.
Still another object of the invention is to provide an atomizer capable of easily adjusting the coating pattern of an atomized coating material in size and shape.
Yet another object of the invention is to provide an atomizer capable of atomizing a coating material even under a relatively low rotation speed.
Yet another object of the invention is to provide a spray type atomizer capable of reducing the amount of air discharged from a nozzle together with a coating material.
Yet another object of the invention is to provide an atomizer capable of atomizing a coating material by using a spray type nozzle while removing the need of air.
Yet another object of the invention is to provide a hydraulic atomizer capable of atomizing a coating material even under a relatively low hydraulic pressure.
Yet another object of the invention is to provide an atomizer capable of reducing its optimum distance from a work to assure quality coating on the work.
To accomplish those objects, the present invention is essentially characterized in atomizing a coating material by spattering the coating material into a form easy to atomize from a material spattering means and exerting supersonic vibration onto the coating material just flying from the spattering means. The material spattering means is typically a rotary atomizing head that centrifugally spreads the coating material radially outwardly. Alternatively, the material spattering means may be a paint nozzle used in a conventional spray type atomizer. Alternatively, the material spattering means may be a material discharge opening capable of hydraulic atomization (herein after referred to as a material discharge/hydraulic atomization opening) employed in a conventional hydraulic atomizer.
In case the present invention is applied to an atomizer having a rotary atomizing head, supersonic vibration is preferably exerted forward in a region adjacent to and around the outer circumferential perimeter of the rotary atomizing head to reliably propel the atomized coating material forward with the vibration energy. In case the present invention is applied to an atomizer having a paint nozzle, supersonic vibration is preferably exerted diagonally forward from the area encircling the paint nozzle toward a region adjacent to the paint nozzle to concentrate the vibration energy onto the material just after expelled from the paint nozzle. Similarly, in case the present invention is applied to a hydraulic atomizer, supersonic vibration is preferably exerted diagonally forward from the area encircling the opening toward a region adjacent to a material discharge/hydraulic atomization opening to concentrate the vibration energy onto the material just after expelled from the opening.
Those and other objects, features and advantages of the present invention will become more apparent from the following detailed description of the preferred embodiments in conjunction with the accompanying drawings.
Some preferred embodiments and specific examples of the invention will now be explained below in detail with reference to the drawings.
The present invention is applicable to rotary atomizers, spray type atomizers and hydraulic atomizers. These atomizers may be either electrostatic atomizers configured to deposit an electrically charged coating material onto a work held in a ground potential or other type atomizers configured to deposit a non-charged coating material onto a work. Furthermore, the invention is equally usable with any kind of coating materials, including water-based paints, oil-based paints and metallic paints.
With reference to
The atomizer 1 further includes an internal paint passage or paint supply pipe 5. A coating material is supplied through the paint supply pipe 5 to a central portion of the rotary atomizing head 4. The coating material having reached the central part of the rotary atomizing head 4 spreads radially outwardly along the surface of the rotary atomizing head 4 under a centrifugal force, and scatters radially outwardly from the outer circumferential perimeter 4a of the rotary atomizing head 4. In the region adjacent to the outer circumferential perimeter 4a of the rotary atomizing head 4, the coating material is in a condition easy to atomize. More specifically, although it depends upon the feed rate of the coating material and the rotational speed of the rotary atomizing head 4, the coating material spattered from the rotary atomizing head 4 is atomized through the form of a thin layer or a number of filaments.
The rotary atomizer 1 further includes a cylindrical supersonic horn 6 having a vibration plane 6a located adjacent to the outer circumferential perimeter 4a of the rotary atomizing head 4. More specifically, the vibration plane 6a of the supersonic horn 6 is preferably located at a position where it can effectively impart supersonic vibration to the filament-like coating material, film-like coating material or coating material immediately before atomized. The vibration plane 6a of the supersonic horn 6 vibrates with supersonic vibration generated by a supersonic generator 7. In
The vibration plane 6a of the supersonic horn 6 is an inclined annular plane gradually increasing its diameter forward from its rear end adjacent to the outer circumferential perimeter 4a of the rotary atomizing head 4. Thus, the vibration plane 6a exerts supersonic vibration to the coating material immediately after departing from the outer circumferential perimeter 4a of the rotary atomizing head 4, and can atomize it to particles of a substantially uniform grain size. Simultaneously, the inclined vibration plane 6a orients the flying direction of the atomized coating material forward toward a work (not shown).
The rotary atomizing head 4 and the annular vibration plane 6a surrounding the rotary atomizing head 4 are preferably adjustable in relative positions in the front-and-rear directions. In a first example, the front-and-rear relative positions of the rotary atomizing head 4 and the vibration plane 6a may be determined so that the coating material jumping from the outer circumferential perimeter 4a of the rotary atomizing head 4 is exposed to the supersonic vibration from the vibration plane 6a without directly contacting the vibration plane 6a. In a second example, the front-and-rear relative positions of the rotary atomizing head 4 and the vibration plane 6a may be determined so that the coating material exiting from the outer circumferential perimeter 4a of the rotary atomizing head 4 forms a thin film on the vibration plane 6a and the thin film can be atomized and propelled forward by the supersonic vibration. In a third example, the front-and-rear relative positions of the rotary atomizing head 4 and the vibration plane 6a may be determined so that both phenomena explained in the first and second examples occur in combination.
The phenomena explained in the first to third examples undergo influences from the inclination angle θ of the vibration plane 6a of the supersonic horn 6. The inclination angle θ of the vibration plane 6a is preferably adjustable as desired.
By changing the inclination angle θ of the vibration plane 6a, the phenomena explained in the first to third examples and the size of the coating pattern of the coating material can be easily adjusted.
The vibration plane 6a of the supersonic horn 6 may be an annular plane continuous in the circumferential direction. Alternatively, it may be formed of a plurality of segments annularly aligned in the circumferential direction, if so desired. In this case, individual segments of the vibration plane 6a may be adjustable independently in inclination angle θ and/or front-and-rear position relative to the rotary atomizing head 4. In this manner, the coating pattern of the coating material can be readily adjusted in size and/or shape.
A paint nozzle 11 heretofore used in a conventional spray type atomizer may be used to spatter the coating material without atomizing air, and supersonic vibration may impinge the coating material just after departing the nozzle 11, not assisted by air, to atomize it. This phenomenon is schematically illustrated in
Although
In the atomizer 10 having the nozzle 11 according to the invention, the coating material dashes out of the nozzle 11 with or without atomizing air, and it is next atomized. Similarly, in the atomizer having the hydraulic atomization opening according to the invention, the coating material is expelled from the hydraulic atomization opening in form of a thin film that is easy to atomize, and it is next atomized. The point P mentioned before is preferably determined in the range from the front end of the nozzle 11 or hydraulic atomization opening to the region where the coating material begins to atomize.
In
The rotary electrostatic atomizer 100 may be mounted on a robot arm, for example. The bell-shaped cup 103 can be changed in the front-and-rear direction (the arrow X direction in
A supersonic vibrator 105 can atomize the coating material by imparting supersonic vibration to the coating material just after flying from the outer circumferential perimeter of the bell-shaped cup 103 that rotates at a relatively low speed (such as 4,000 romp to 5,000 rpm). Moreover, the supersonic vibrator 105 can uniform the grain size of the coating material, and can apply kinetic energy to the coating material to propel the coating material forward.
The supersonic vibrator 105 may be a supersonic horn having a ring-shaped vibration plane 106 facing forward as shown in
The vibration plane 106 is adjacent to and encircles the outer circumferential perimeter of the bell-shaped cup 103. The vibration plane 106 can move in the front-and-rear direction its positional relation with the bell-shaped cup 103.
The vibration plane 106 can apply supersonic vibration to the coating material immediately after flying outwardly from the outer circumferential perimeter of the bell-shaped cup 103. By controlling the amplitude, frequency, or the like, of the vibration plane 106, it is possible to adjust the level of the kinetic energy applied to the coating material as well as the level of the atomization. As a result, it is possible to improve the adhesion efficiency of the coating material onto the work and the quality of the coating on the work.
The vibration plane 106 is preferably adjustable in inclination angle θ explained before with reference to
The vibration plane 106 is more preferably adjustable both in inclination angle θ and in front-and-read position relative to the bell-shaped cup 103. Thereby, the coating pattern 109 can be adjusted in size and shape as shown in
The individual segments 106a of the vibration plane 106 are preferably adjustable independently in inclination angle θ and in front-and-rear position relative to the bell-shaped cup 103 independently from each other. In this case, the coating pattern 109 can be controlled in shape and size more freely.
The rotary atomizer 100 has a high-voltage generator 110 to electrically charge the coating material by applying a high voltage from the high-voltage generator 110 to the coating material. In the illustrated example, a high voltage is applied directly to the bell-shaped cup 103. However, any of other various known techniques may be used to electrically charge the coating material. For example, the coating material, after atomized, may be electrically charged by supersonic vibration of the vibration plane 106.
According to the rotary electrostatic atomizer 100 according to the first embodiment explained in conjunction with
The above-explained supersonic atomization technique not only enhances atomization of the coating material but also uniforms the grain size of the coating material as compared with conventional electrostatic coating techniques relying on air. For example, the grain size of the coating material is from 30 μm. or even more, in conventional electrostatic coating techniques relying upon air. However, the supersonic atomization technique according to the invention can atomize the coating material to the grain size as small as 20 μm or less. Moreover, the coating material is uniformed in grain size to exhibit a grain size distribution having a single peak. Therefore, the supersonic atomization technique improves the adhesion efficiency of the coating material and its coating quality. Furthermore, the electrostatic coating technique enables easy adjustment of the area and shape of the coating on the work. That is, it permits flexible coating.
A supersonic vibrator 202 is located adjacent to the outer circumferential perimeter of the bell-shaped cup 103 to exert supersonic vibration onto the coating material immediately after it scatters from the outer circumferential perimeter of the cup 103.
The supersonic vibrator 202 has a plurality of ring-shaped frames 203 that are concentrically aligned in intervals in the radial direction as shown in
The plural ring-shaped frames 203 lie on a plane extending perpendicularly to the axial line of the bell-shaped cup 103. The coating material scattering from the outer circumferential perimeter of the bell-shaped cup 103 is exposed to supersonic vibration from the vibration plates 204 while traveling from radially inner ring-shaped frames to radially outer ring-shaped frames 203. In this process, the supersonic vibration atomizes particles of the coating material to more minute particles, and drives them forward. Reference numeral 206 in
Reference numeral 208 in
The rotary electrostatic atomizer 100 is controlled in rotational speed of the air motor, orientation of the bell-shaped cup 103, etc., by control signals S1 and S2 from a main control board 21.
Regarding the supply of the coating material to the rotary electrostatic atomizer 100, a mixer 22 mixes some primary coating materials selected from pumps 23 through 27 containing five primary colors (cyan, magenta, yellow, black and white) respectively, and supplies the mixture to the coating supply pipe 104 (see
A supersonic controller 28 controls orientation, etc. of individual segments 106a of the vibration plane 106 of the rotary electrostatic atomizer 100. A high-voltage controller 29 controls the high voltage to be generated by the high-voltage generator 110 (see
The supersonic vibration generator 110 may be any appropriate one of known devices, such as a magnetostriction converter element.
Next explained are examples of coating on a relatively large work W such as a car body with reference to
A plurality of units U1˜U10 may be prepared. In each unit U1˜U10, a plurality of atomizers 1 may be closely aligned in two lines. The first line L1 and the second line L2 may be parallel to each other. Thus, the units U may be reciprocated (in the arrow Y direction) over the coating surface of the work W to coat the car body W. In this manner, the coating material depositing on the work W can be uniformed in thickness. Preferably, the atomizers 1 of the first line L1 and the atomizers 1 of the second line L2 are arranged in a zigzag layout.
The atomizers forming each unit U may be of any type among various types of atomizers according to the present invention (for example, the rotary atomizers 1 of
The rotary atomizers 1, 100 and 200 do not need air for driving the coating material to the work. In addition, the rotational speed of the rotary atomizing head 4 such as the bell-shaped cup may be relatively low. The atomizer explained with reference to
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20050136190 A1 | Jun 2005 | US |