JP4239125B2 - Powder coating system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a novel electrostatic powder coating system that is different from conventional electrostatic powder coating, and more specifically, generates a floating cloud of powder paint in a limited space surrounding a workpiece. The present invention also relates to a novel coating system capable of performing electrostatic powder coating by applying a high voltage to electrodes in the space.
[0002]
[Prior art]
Conventionally, electrostatic powder coating methods using a coating gun for spraying powder coatings are known and utilized. This means that a high voltage is applied between the tip of the paint gun and the work, and at the same time, the powder paint is sprayed from the paint gun toward the work to attach the ionized powder paint to the outer surface of the work. It is a painting method.
Recently, a remarkable electrostatic powder coating method that does not use a coating gun has been proposed in JP-A-11-57592. The coating apparatus disclosed in this publication is provided with a mechanism for continuously conveying a plate-shaped workpiece in a housing for coating while being suspended, and an appropriate number of electrodes are arranged in the housing so as to face the surface of the workpiece. The bottom of the housing is equipped with a mechanism for blowing powder paint from the fluid tank into the housing, and the top of the housing sucks air in the housing upward and is then sucked together. A mechanism for separating the powder coating material and returning it to the fluidized tank, generating a cloud in which the powder coating material floats in the housing, and applying a high voltage to the electrode in that state, The paint is applied to the workpiece.
This electrostatic powder coating method that does not use a coating gun can be referred to as an electric field flow powder electrostatic coating method, which is different from the conventional electrostatic powder coating method that uses a coating gun. In comparison, it has various characteristics and advantages, such as a coating film having a very high smoothness, and a thinner coating film can be formed by adjusting the concentration of the powder coating cloud.
[0003]
[Problems to be solved by the invention]
By the way, in recent years, as a countermeasure to environmental protection problems, it has been required to reduce VOC (Volatile Organic Compound) and odor emission in the painting process of automobile production. As one of the measures to respond, it is required to make it possible to satisfactorily perform top coating of automobile bodies by powder coating where no solvent is used.
However, the electrostatic powder coating apparatus disclosed in the above-mentioned publication is an apparatus for coating a planar workpiece such as an electrical component panel, and is a three-dimensional object having large irregularities such as an automobile body or its parts. It cannot be applied to powder electrostatic coating for a workpiece having a shape.
Further, the disclosed apparatus is a continuous coating apparatus that sequentially performs electrostatic powder coating on individual workpieces while suspending and transporting the workpieces. It is necessary to always operate the paint circulation mechanism in which the paint is continuously blown into the housing from below the housing while the powder paint thus blown is continuously sucked from above the housing and reused. Since this paint circulation mechanism blows and circulates a large amount of powder paint, a large amount of energy is consumed for the continuous operation. Therefore, this conventional apparatus consumes a large amount of energy, and this will be a matter to be improved in terms of energy saving.
[0004]
The present invention has been made in consideration of these various circumstances, and the object of the present invention is to form a limited space surrounding the workpiece for each workpiece to be transported, and to form a powder in the space. An object of the present invention is to provide a novel powder coating system capable of generating a floating cloud of body paint and subsequently performing electrostatic powder coating on a workpiece.
Another object of the present invention is that electrostatic powder coating can be performed on a three-dimensional workpiece having irregularities in a cloud in which the powder coating is floating, and energy consumption required for coating is also achieved. The object is to provide a batch type powder coating system which requires less amount.
In addition, the other objective of this invention can be easily understood from the following description or based on a matter obvious from the description.
[0005]
[Means for Solving the Problems]
  In order to achieve such an object, the present invention provides a powder electrostatic coating system, in which a substantially closed space surrounding a workpiece is covered with a base floor and a dome lid covering the workpiece with respect to one workpiece to be coated. Or with a base tank and ceiling material for storing workpieces, and then generating a floating cloud of powder paint in the closed space, followed by applying a high voltage to the electrodes in the space, The body paint can be applied to the workpiece. More specifically, the present invention is a coating system that performs powder electrostatic coating by generating a cloud of floating powder coating in a limited space surrounding the workpiece. Consists of a workpiece transport device that transports the workpiece to the painting position above the base floor, stops it, and feeds the workpiece from the painting position after painting, and an integrated lid or a plurality of lid members, and covers the workpiece as a whole. A dome lid having a shape capable of being attached, an electrode-attached frame, an electrode frame fixed to the inside of the dome lid, and a device for moving the dome lid forward and backward relative to the workpiece at the painting position. A lid moving device capable of covering the workpiece with the dome lid and forming a substantially closed coating space surrounding the workpiece with the dome lid and the base floor; and mixing of the powder paint and air Supply fluid A paint spraying device in which the outlet of the mixed fluid is provided in the lower part of the coating space, and the air in the coating space is sucked upward, and the powder coating sprayed from the outlet is cloud-like The air suction device that floats in the painting space and a high voltage is applied between the electrode inside the dome lid and the workpiece at the painting position to apply the powder paint floating in the painting space to the workpiece. The present invention relates to a powder coating system comprising a voltage applying device. In the powder coating method according to the present invention, it is more preferable to uniformly generate and maintain a cloud in which the powder coating is floating in the coating space in order to make the finish of the coated product uniform. From this point of view, in a more preferable aspect of the present invention, in the above powder coating system, the filter wall is stretched over the entire inner surface between the inner surface of the dome lid and the electrode frame, and between the filter wall and the dome lid. The present invention relates to a powder coating system including a first air suction device that sucks air in a space between the inner surface and a second air suction device that sucks air in a coating space inside the filter wall. According to another more preferable aspect, in the above powder coating system, the slit forming wall is stretched over the entire inner surface between the inner surface of the dome lid and the electrode frame, and the slit forming wall and the dome lid are The present invention relates to a powder coating system including an air suction device that sucks air in a space between an inner surface and an inner surface. The principle of powder coating according to the present invention is not only when the workpiece is transported on the base floor while supporting the workpiece from below using a cart or the like as in the above powder coating system, but also the workpiece is suspended. However, the present invention can also be applied to the case of transporting into the base tank below the base surface. Therefore,Other inventionsIs a coating system that generates a cloud of floating powder coating in a limited space surrounding a workpiece and performs electrostatic powder coating, and includes a base bath and the base bath while holding the workpiece. A workpiece carrying device that transports to a painting position inside and stops, and sends the workpiece out of the base tank after painting, an electrode frame, and an electrode frame fixed inside the base tank; A ceiling material having a shape capable of covering the inside of the base tank, and when the work is in the coating apparatus, the ceiling material and the base tank form a substantially closed paint space surrounding the work. A device for supplying a mixed fluid of a ceiling material and a powder coating material and air, the paint blowing device having an outlet of the mixed fluid provided in a lower portion of the coating space; Aspirate the air upward and Applying a high voltage between the electrode in the base tank and the workpiece at the coating position, and painting by applying an air suction device that floats the powder paint blown out from the spout in the coating space like a cloud The present invention relates to a powder coating system comprising a voltage application device for applying a powder paint floating in a space to a workpiece.
[0006]
DETAILED DESCRIPTION OF THE INVENTION
Next, each part and element which comprise the powder coating system of this invention are demonstrated in order.
The base floor refers to a floor that is a base at a position (painting position) where a work (such as an automobile body) is to be painted, and may be a general fixed floor that can support the work or its transport device from below, It may be a movable floor that opens and closes in conjunction with the loading and unloading of the workpiece. The base floor surrounds the lower side of the workpiece when the workpiece is transported to a position (painting position) where painting is performed above the base floor, and forms the following painting space together with the dome lid.
The work transportation device consists of a carriage and its drive mechanism, etc., and can carry out intermittent transportation by transporting the work to the painting position above the base floor and stopping it, and sending the work from the painting position after painting. is there.
The dome lid is a lid having a shape capable of covering and covering the workpiece as a whole, and may be, for example, an inverted lid-shaped integral lid, or more preferably a plurality of, for example, a pair of left and right semi-cylindrical shapes It is comprised from this lid member.
The electrode frame is a frame to which an electrode is attached, and is fixed inside the dome lid. When the work is covered with the dome cover, the electrode frame is also arranged so as to cover the work without contacting the work. When the work is covered with a dome cover, the electrodes are attached to an appropriate number of electrode frames so as to face the entire outer surface of the work, and preferably to follow the outer shape of the work.
Preferably, a filter wall or a slit forming wall is stretched over the entire inner surface of the lid between the inner surface of the dome lid and the electrode frame. The filter wall is a curved wall made of a filter material that allows the passage of air but inhibits the passage of the powder paint. The slit forming wall is a curved wall in which an appropriate number of slits are formed at various locations on the wall surface, and allows air and paint powder to be sucked through the slit. More preferably, the appropriate number of slits is configured such that the slit located at the lowermost side is the narrowest and the slit opening is further enlarged as it is positioned higher than that. The filter wall and slit forming wall make the air suction in the space inside the dome lid (painting space) more even across the top and bottom of the dome lid, so that the floating cloud of powder paint is uniformly in the painting space Contributes to generating and maintaining.
The lid moving device is a device that moves the dome lid forward and backward with respect to the workpiece at the painting position.For example, when the dome lid is an integral lid with an inverted bowl shape, the dome lid is suspended so as to be movable up and down, Any device that lowers the dome lid and covers the workpiece when the workpiece is in the painting position may be used. Further, the lid moving device, when the dome lid is composed of a pair of left and right semi-cylindrical lid members, moves the opposed left and right lid members horizontally toward and away from the workpiece at the painting position, and Any device may be used as long as the dome lid is completed and the workpiece is covered and covered by the contact or connection of the lid member. Accordingly, the operation of the lid moving device causes the dome lid to be in a posture to cover and cover the workpiece, so that a substantially closed space (painting space) surrounding the workpiece is formed by the dome lid and the base floor.
The coupling portion where the left and right lid members are coupled may have a structure that can completely seal the inside of the dome lid, but the inner space of the dome lid can be substantially blocked from the atmosphere outside the dome lid. Things are also sufficient.
The paint spraying device is a spraying device capable of spraying a mixed fluid of a powder paint and air upward, and has a spray outlet for the mixed fluid provided in the lower part of the coating space. This device is, for example, a powder coating fluidized bed device, that is, a device that can blow up powder coating material stored on the floor upward by the inflow of air from the bottom of the floor, or paint powder supplied by a separate system. It consists of a device that stirs and mixes body and air in a mixing zone to produce a mixed fluid of both. By the operation of the paint blowing device, powder of the powder paint, that is, paint powder is blown up into the paint space inside the dome lid like smoke.
The air suction device is composed of a suction fan, a duct connecting the dome lid and the like, and sucks air in the painting space upward, and also sucks paint powder floating in the painting space upward. be able to. The mist-like paint powder blown up into the painting space by the operation of the paint blowing device falls within a while due to its own weight and settles downward. At that time, when the air in the coating space is pulled upward by the operation of the air suction device, the coating powder is prevented from falling and the coating powder floats in the coating space. That is, by balancing the gravity and buoyancy applied to the powder paint, the blowing force for blowing the paint powder of the paint blowing device, and the suction force for sucking the paint powder of the air suction device upward, In the painting space, the coating powder can be suspended evenly over the entire space like a cloud.
As described above, the filter wall and the slit-forming wall uniformly generate a floating cloud of powder paint in the coating space so that the air suction action by the air suction device works from the entire inner surface of the dome lid. By this, it is a uniformizing means that achieves uniform air suction throughout the painting space. The filter wall makes the air suction uniform by the filtration performance of the filter material, particularly by changing the performance of each wall part. As an air suction device, the filter wall is provided between the filter wall and the inner surface of the dome lid. A device for sucking air in the space is provided. The slit forming wall makes air suction uniform according to the size and number of slits, and the air suction device is a device that sucks air in the space between the slit forming wall and the inner surface of the dome lid. Is provided.
The air suction device is also a device that removes the paint powder remaining in the painting space inside the dome lid after the painting is finished, and collects it by air suction. Therefore, in the aspect in which the filter wall is provided on the inner side of the dome lid, the filter wall and the inner surface of the dome lid are disposed in order to quickly collect unused powder paint remaining in the painting space after the painting is completed. In addition to the above-described first air suction device that sucks air in the space between, the second air suction device that can quickly and directly suck the air in the painting space inside the filter wall without going through the filter wall It is more preferable to comprise.
Finally, the voltage application device consists of a high voltage generator connected to each electrode of the electrode frame inside the dome lid, and applies the required high voltage between each electrode and the workpiece at the painting position. Can do. By operating this device, that is, by applying a high voltage to the cloud of powder paint floating in the paint space, the paint powder floating in the paint space is ionized and guided to the workpiece along the lines of electric force. Apply to the work surface.
In order to avoid coating powder on the inner surface of the work and ensure powder coating on the outer surface of the work, lead the air inflow pipe to the inside of the work, It is more preferable that the breeze can be sent from the inside to the outside of the work.
[0007]
As described above, the powder coating system of the present invention performs electrostatic powder coating on a workpiece by applying a high voltage in a cloud in which the powder coating is floating in the coating space inside the dome lid. It is something that can be done.
In other words, the powder coating system of the present invention generates a cloud of paint powder in the space inside the dome for each individual work, electrostatically applies the paint powder to the work, and is unused. By collecting the coating powder, it is possible to achieve so-called batch-type electrostatic powder coating in a limited space.
Therefore, for example, as compared with the conventional coating system disclosed in Japanese Patent Application Laid-Open No. 11-57592, the coating powder is constantly circulated while being blown up from below and sucked from above in the housing. The powder coating system of the invention can significantly reduce energy consumption. In addition, the coating system of the present invention can perform powder coating on the entire surface of an uneven three-dimensional workpiece like an automobile body at once.
[0008]
  next,Other inventionsEach element and component which comprise the powder coating system of this invention are demonstrated. Descriptions of matters similar to those in the case of the coating system of the aspect described above are omitted. The base tank is a box-shaped tank that can store a workpiece to be painted. Therefore, when the work is at the painting position in the base tank, the base tank surrounds the lower side and the entire side surface of the work, and together with the following ceiling material, forms a painting space. The work conveying device is composed of a hanging conveyor, etc., and can be intermittently conveyed by stopping the work by conveying it to the painting position in the base tank while holding the work, and sending the work out of the base tank after the completion of painting. . The electrode frame is fixed to the inside of the base tank. More preferably, in order to be able to quickly carry the work into and out of the base tank without hindering the work, On the carry-out side, a part of the electrode frame is provided so as to be tiltable or rotatable so as to avoid contact with the work to be carried in and out. A ceiling material is a ceiling of the shape which can cover the inside of a base tank, Comprising: When a workpiece | work exists in a coating device, it can surround the upper side of a workpiece | work. Therefore, when the work is stored in the base tank, the ceiling material covering the work and the base tank form a substantially closed coating space surrounding the work. The paint blowing device has a spray port for a mixed fluid of powder paint and air arranged in the lower part of the painting space, and the air suction device has a suction duct arranged in the upper part of the painting space, Air in the painting space can be sucked upward through this duct. Furthermore, the voltage application device is configured so that a high voltage can be applied between the electrode in the base tank and the workpiece at the coating position. Even in the coating system of this aspect, the floating powder coating cloud may be generated in the entire coating space inside the base tank due to the balance of the weight of the powder coating, the spraying ability of the coating powder, and the air suction force. it can. Therefore, in this state, ionized paint powder is applied to the surface of the workpiece by applying a high voltage. Therefore,Other inventionsThe powder coating system can perform electrostatic powder coating for each individual workpiece within the limited space inside the base tank, and therefore the energy consumption required for coating is extremely small. This has the advantage that powder coating can be reliably performed even on a three-dimensional workpiece.
[0009]
【Example】
DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be clarified further by describing an embodiment embodied with the drawings as the best embodiment of the present invention.
[0010]
Example 1
As shown in FIGS. 1 to 8, the powder coating system of this embodiment is a system for coating a work (automobile body) 1 at a painting position A one by one, and a base floor 2 and The set of dome lids 3 forms a substantially closed paint space 4.
The base floor 2 is a horizontal fixed floor. The workpiece 1 is horizontally conveyed on the base floor 2 in the direction of arrow P (FIGS. 2 and 5) by the operation of a workpiece conveying device (not shown), and stops at the painting position A above the base floor 2. After the completion of painting, the paint is sent out from the painting position A.
As shown in FIGS. 1 to 3, the dome lid 3 is composed of a pair of left and right lid members 5 and 5 obtained by dividing an elliptical dome into two along the longitudinal direction. It has a dome shape that can be covered.
As shown in FIGS. 1, 3, and 4, a support curved plate 21 in which several insulators 20 are assembled is provided inside the dome lid 3, and the electrode frame 6 is fixed to the insulator 20. It is supported. The electrode frame 6 is a frame to which the electrodes 7 are attached on the left and right sides. When the work 1 is covered with the left and right lid members 5 and 5 of the dome lid 3, the electrode frame 6 is also shown in detail in FIG. Thus, it arrange | positions so that the workpiece | work 1 may be covered, without contacting the workpiece | work 1. FIG. That is, an appropriate number of electrodes 7 are attached to the electrode frame 6 so as to face the entire outer surface of the work 1 and follow the outer shape of the work 1 when the dome cover 3 covers the work 1. Yes.
As shown in FIGS. 1, 3, and 4, a filter wall 10 is stretched between the inner surface 12 of the dome lid 3 and the electrode frame 6 over the entire inner surface 12 of the dome lid 3. The filter wall 10 is a curved wall made of a filter material that allows the passage of air but prevents the passage of powder paint.
Further, the coating system of the present embodiment includes a lid moving device 11 that opens and closes the dome lid 3 by moving the left and right lid members 5 and 5 forward and backward with respect to the workpiece 1 at the painting position A. Yes. That is, the lid moving device 11 is composed of an open / close robot connected to the outside of the left and right two lid members 5, 5, and the left and right lid members 5, 5 are moved horizontally inward by the operation thereof. When the left and right lid members 5 and 5 are brought into contact with each other and joined together as shown in FIGS. 2 and 3, the dome lid 3 is completed. The work 1 is covered and covered in it. Accordingly, when the lid moving device 11 is operated, the dome lid 3 is placed in a position to cover and cover the workpiece 1, so that the coating space 4 of the substantially closed space surrounding the workpiece 1 is formed by the dome lid 3 and the base floor 2. It is the structure formed. On the contrary, the lid moving device 11 moves the opposing left and right lid members 5 and 5 horizontally outward to separate them from the workpiece 1 at the painting position A, and FIG. As shown in FIG. 6, the dome lid 3 is opened.
The connecting portion 13 where the left and right lid members 5 and 5 are joined may have a structure that can completely seal the inside of the dome lid 3, but the inner space of the dome lid 3 has an atmosphere outside the dome lid. A structure that can be substantially cut off is sufficient.
In addition, the coating system of the present embodiment includes a paint blowing device 14 that can spray a mixed fluid of powder paint and air upward into the painting space 4. As shown in FIGS. 3 and 4, the blowing device 14 includes several blowing ports 15... Provided in the lower part of the coating space 4, and a powder coating material supply device 16 communicating with the blowing port 15. And an air supply source 17 connected midway from the powder coating material supply device 16 to the outlet 15. Several outlets 15 are provided along the lower contour of the workpiece 1 as shown in detail in FIG. Further, as shown in FIG. 1, the powder coating material supply device 16 is connected to a fresh powder coating material supply source and a recovered powder coating material tank 18 so that the fresh powder coating material and / or the recovered powder coating material is supplied to the device. It is thrown in. This supply device 16 is designed so that the powder coating material for exactly one workpiece can be supplied in one operation. Therefore, by the operation of the paint spraying device 14, the fluid mixture of the powder paint and air is supplied into the paint space 4 inside the dome lid 3 from the spray outlet 15 every time the workpiece 1 is coated. The paint space 4 is blown upward like a plume. Moreover, an amount of coating powder necessary for painting one workpiece 1 is supplied to the painting space 4 in one operation. That is, there is no wasteful energy consumption for supplying paint, and the optimum use of energy is achieved. In addition, the powder coating material supply device 16 secures two systems of supply sources of fresh powder coating material and recovered powder coating material, and the recovered powder coating material is once stored in the paint tank 18 and then supplied. Therefore, even if a coating failure occurs, the amount of paint to be discarded can be suppressed to a smaller amount.
In addition, the coating system of the present embodiment sucks the air in the painting space 4 inside the dome lid upward, whereby the paint powder floating in the painting space 4 can also be sucked upward. An air suction device for removing paint powder remaining in the painting space 4 outside the painting space 4 after completion is provided. As shown in FIGS. 1 and 3, this apparatus is composed of two systems, that is, first and second air suction devices 22 and 23.
The first air suction device 22 is a device for sucking air in the space 9 between the filter wall 10 and the inner surface 12 of the dome lid as shown in these drawings, and the dome lid 3 as shown in FIG. A flexible suction duct 24 connected to the space 9 between the filter wall 10 and the inner surface 12 of the dome lid, and three suction fans connected to the suction duct 24. 50 (FIG. 1), and damper A to damper D (FIG. 1), and only the air that has passed through the filter wall 10 is sucked by the operation of the suction fan 50. A suction force sucked upward is applied to the floating coating powder. The coating system of this example has gravity and buoyancy applied to the powder paint, a blowing force for blowing up the paint powder by the paint blowing device, and a suction force for sucking the paint powder upward by the first air suction device 22. The balance is designed so that the coating powder can float evenly over the entire space in the coating space 4 inside the dome lid 3 by this balancing action.
Further, in this case, the filter wall 10 acts so that the action of air suction by the first air suction device 22 works more evenly from the entire inner surface 12 of the dome lid 3. That is, the filter wall 10 achieves uniform air suction throughout the painting space 4. Therefore, the coating system of this example can uniformly generate a cloud in which the powder paint floats in the coating space 4 by the action of the filter wall 10.
The second air suction device 23 is a device that directly sucks air in the space 8 inside the filter wall 10 without passing through the filter wall 10 as shown in FIGS. A suction duct 25 communicating with the space 8 inside the filter wall 10 by a duct connected at the top three places (FIG. 2) of the lid 3, and a powder paint recovery device 26 connected to the suction duct 25; By the operation 27 of the suction fan of the recovery device 26, the air and the remaining paint powder in the space 8 inside the filter wall 10 are sucked together, whereby the unused paint powder in the paint space 4 is collected. The body can be quickly recovered by the powder coating material recovery device 26. The recovery device 26 separates and recovers the recovered paint powder from the air in the filter 28. The separated recovered powder paint is finally returned to the recovered paint tank 18 through the vibrating sieve 19. Thereafter, the powder coating material stored in the tank 18 is blown up into the coating space 4 from the outlet 15 by the operation of the coating material blowing device 14 and reused.
Finally, as shown in FIG. 1, the coating system of this embodiment includes a voltage applying device 29 of a high voltage generator connected to each electrode 7 of the electrode frame 6 inside the dome lid 3. With this operation, a required high voltage can be applied between each electrode 7 of the electrode frame 6 inside the dome lid and the workpiece 1 at the coating position A. Therefore, by applying a high voltage in the cloud in which the powder coating material floats in the coating space 4, the coating powder floating in the coating space 4 is ionized and travels to the work 1 along the lines of electric force. It is guided and applied to the surface of the work 1.
As shown in FIG. 1, the coating system of the present example is configured such that a gentle air flow supply pipe 30 is guided from the lower part of the coating space 4 to the inside of the work 1, and a breeze is sent from the inside of the work 1 to the outside. It has become. Therefore, the coating of the coating powder on the inner surface of the workpiece 1 is prevented, and the powder coating on the outer surface of the workpiece 1 is reliably achieved.
[0011]
Next, the procedure of powder coating using the coating system of the present embodiment will be described. First, the workpiece | work 1 is conveyed by the driving | operation of a workpiece | work conveyance apparatus to the coating position A on the base floor 2, and stops (FIG. 2). Next, when the lid moving device 11 is operated, the left and right lid members 5 and 5 approach each other on the base floor 2 toward the workpiece 1 at the painting position A in opposite directions, and both the lid members 5 and 5 are coupled. The dome lid 3 is completed, and the work 1 is covered with the dome lid 3. Subsequently, the paint spraying device 14 and the first air suction device 22 start operation simultaneously, and the powder paint is sprayed into the coating space 4 from the spraying port 15. At the same time, the filter wall 10 and the inner surface 12 of the dome lid The air in the painting space 4 in the center inside the dome lid is sucked upward by the air between the two. Accordingly, the sprayed paint powder does not settle downward and floats in the coating space 4, and eventually a cloud of paint powder is uniformly generated in the paint space 4. Further, a light airflow is supplied to the inside of the work 1. In this state, by operating the voltage application device 29, a high voltage is applied between each electrode 7 in the coating space 4 and the workpiece 1, and the floating coating powder is applied to the outer surface of the workpiece 1. To do.
Therefore, after the powder electrostatic coating is completed, the paint spraying device 14 stops supplying the powder paint and flows only air. At the same time, the second air suction device 23 resumes operation, and the air in the space 8 inside the filter wall 10 is sucked directly upward without passing through the filter wall 10. The unused paint powder remaining on the surface is quickly removed from the coating space 4 through the suction duct 25 and fed to the powder paint recovery device 26. Thereafter, the recovered powder paint is separated, stored in the recovered paint tank 18, sent to the powder paint supply device 16, and reused.
Further, in the unused paint collecting step, the first air suction device 22 changes the air flow in the reverse direction by switching the opening and closing of the dampers A to D, and the pressurized air is changed to the dome lid inner surface 12 and the filter wall. 10 is sent to the space 9 between the filter wall 10 and the filter wall 10. Thereby, the coating powder adhering to the filter wall 10 also falls and is removed. The filter wall 10 is prevented from being clogged, and the filter wall 10 can be used for a long time.
Then, at the stage where the collection of the unused paint is completed, the dome lid 3 is opened by the operation of the lid moving device 11 (FIGS. 5 and 6), and then the painted workpiece 1 is The workpiece 1 to be painted next is transported to the painting position A. Thereafter, powder coating on the second workpiece 1 is performed in the same procedure as described above, and thereafter, the same coating procedure is repeated. FIG. 9 is a time chart showing the above-described operation procedure of the coating system of the present embodiment.
As described above, in the powder coating system of this embodiment, in the coating space 4 inside the dome lid, the electrostatic powder coating is performed on the workpiece 1 by applying a high voltage in the cloud in which the powder coating is floating. Can be performed. That is, the coating system of the present embodiment generates a cloud of paint powder in the space 8 inside the dome for each work 1, performs electrostatic coating of the paint powder on the work 1, and is not yet performed. By collecting the paint powder used, batch-type powder electrostatic coating in a limited space can be achieved. Therefore, according to the powder coating system of the present embodiment, it is possible to significantly reduce the energy consumption required for coating, and in addition to a three-dimensional workpiece 1 having unevenness like an automobile body. Powder coating can be done at once over the entire surface.
Further, the above powder coating system is provided with a base floor 2 of a fixed floor. However, like the powder coating system of Modification Example 1 shown in FIG. It is possible to apply a base floor 31 that is composed of a floor and that opens and closes together in conjunction with the opening and closing operations of the left and right lid members 5 and 5. The powder coating system of the improved example 1 has an advantage that floating coating powder is prevented from adhering onto the base floor 31 and cleaning of the base floor 31 in that case becomes easier.
Further, the powder coating system of the above embodiment includes two left and right lid members 5 and 5 and a lid moving device 11 that moves them horizontally in opposite directions to approach and separate the workpiece 1. As shown in the powder coating system of Modification 2 shown in FIG. 11, it is composed of an elliptical integrated dome lid 32 and a robot that can bend and stretch. It is also possible to have a configuration provided with a lid moving device 33 that is moved toward and away from 1. The powder coating system of the improved example 2 has the advantage that it is not necessary to consider the structure of the joint portion 13 between the two left and right lid members 5 and 5, and the installation space for the coating system is smaller.
[0012]
Example 2
In the powder coating system of this embodiment, as shown in FIGS. 12 to 14, instead of the filter wall 10 in the coating system of the first embodiment, the slit forming wall 34 is replaced with the electrode frame 6 and the inner surface 12 of the dome lid 3. It is prepared in between.
The slit forming wall 34 is a curved wall formed with an appropriate number of slits, and allows air and paint powder to be sucked through the slits. In this example, the slit located at the lowest side is the narrowest, and the slit opening is further enlarged as it is located at the upper side. With this configuration, the suction of air in the space 8 inside the dome lid becomes more uniform across the top and bottom of the dome lid 3, and therefore a cloud of powder paint floating is uniformly generated and maintained in the painting space 4. can do.
Further, when such a slit forming wall 34 is provided, it is not necessary to provide the two air suction devices 22 and 23 as in the first embodiment. Therefore, in the coating system of the present embodiment, a system of air suction devices 35 for sucking air in the space 9 between the slit forming wall 34 and the inner surface 12 of the dome lid 3 is provided. That is, as shown in FIG. 13, flexible suction ducts 36 respectively connected to the space 9 between the slit forming wall 34 and the inner surface 12 of the dome lid, three on the left and right sides in the center of the side surface of the dome lid 3, A powder coating material recovery device 26 communicating with the suction duct 36 is provided, and the air in the space 8 inside the dome lid and the floating coating material pass through the slit of the slit forming wall 34 by the operation of the suction fan 27 of the recovery device 26. The powder is sucked together and collected.
The coating system of the present embodiment sucks up the paint powder by the gravity of the powder paint itself, the buoyancy due to air resistance, the blowing force to blow up the paint powder by the paint blowing device 14, and the air suction device 35. The suction force is designed to be balanced, and therefore, by this balancing action, the coating powder can float evenly over the entire space in the coating space 4 inside the dome lid. .
Other configurations are the same as those in the powder coating system of the first embodiment.
Therefore, the powder coating system of this embodiment also performs electrostatic powder coating on the workpiece 1 by applying a high voltage in the cloud where the powder coating floats in the coating space 4 inside the dome lid. be able to. That is, in the coating system of this example, a cloud of paint powder is generated in the paint space 4 inside the dome for each individual work, and the paint powder is electrostatically applied to the work 1 and is not used. By collecting the coating powder, it is possible to achieve batch-type electrostatic powder coating in a limited space. In the powder coating system of the present embodiment, as in the case of the first embodiment, the energy consumption required for the coating is remarkably low, and the three-dimensional workpiece 1 having unevenness such as an automobile body is provided. However, it has the advantage that powder coating can be reliably performed.
[0013]
Reference example
  thisReference exampleAs shown in FIGS. 15 to 18, the powder coating system is a system for coating a work (automobile body) 1 at a painting position A one by one, and includes a base tank 41 and a ceiling material 42. Thus, a substantially closed coating space 40 is formed. The base tank 41 is a box-shaped tank in which the work 1 can be stored. When the work 1 is stored in the base tank 41 in the upside down posture and is in the painting position A, the base tank 41 is Surrounds the upper and entire sides. A ceiling material 42 is attached to the upper side of the base tank 41. This is a ceiling having a shape that can cover the inside of the base tank 41, and can surround the lower side of the work 1 when the work 1 is at the painting position A. Therefore, when the work 1 is stored in the base tank 41, the base tank 41 and the ceiling material 42 form a substantially closed coating space 40 surrounding the work 1. As shown in FIG. 15, the coating system of this example includes a work conveying device 43 including a carriage 44 that moves on the ceiling material 42 and a hanging hanger 45 that extends downward therefrom. By the operation of the workpiece conveying device 43, the workpiece 1 is horizontally conveyed in the direction of the arrow P (FIG. 16) while being suspended in an upside down posture, stopped at the painting position A in the base tank 41, and painted. After the completion, it is sent out of the base tank 41. Further, several insulators 20 are vertically installed on the inner wall surface of the base tank 41, and the electrode frame 6 is fixedly supported on the insulators 20. The electrode frame 6 is a frame to which the electrode 7 is attached, and is shown in FIG. 16 so that the work 1 can be quickly carried into and out of the base tank 41 without hindrance. As described above, the part 6a of the electrode frame 6 and a part of the base tank that supports this part are divided and provided to be rotatable on the work carry-in side and the carry-out side, respectively. Therefore, when the workpiece 1 is carried in and out, the part 6a of the divided electrode frame and a part of the base tank are rotated in the direction of the arrow Q in the drawing by the operation of the electrode opening / closing robot 49. The configuration is such that contact with the workpiece 1 is avoided. An appropriate number of electrodes 7 are arranged so as to face the outer surface except the lower surface of the work 1 and to follow the outer shape of the work 1 when the work 1 is stored in the base tank 41 in the upside down posture. ing. Also bookReference exampleThis coating system includes a paint spraying device 14 that can spray a fluid mixture of powder paint and air upward into the paint space 40. As shown in FIG. 15, the blowing device 14 includes four blowing ports 48 (FIG. 17) provided in the lower center of the coating space 40, and powders communicating with the blowing ports 48. The paint supply device 16 and an air supply source 17 connected midway from the powder paint supply device 16 to the outlet 48. As shown in FIG. 15, the powder coating material supply device 16 is connected to a fresh powder coating material supply source and a recovered powder coating material tank 18 so that the fresh powder coating material and / or the recovered powder coating material is contained in the device. It is thrown. This supply device 16 is designed so that the powder coating material for exactly one workpiece can be supplied in one operation. Therefore, by the operation of the paint spraying device 14, the mixed fluid of the powder paint and air is supplied to the coating space 40 in the base tank 41 from the spray port 48 every time the work 1 is applied, that is, the paint powder is applied. It is blown upward in the space 40 like smoke. Moreover, an amount of coating powder necessary for painting one workpiece 1 is supplied to the painting space 40 in one operation. That is, there is no wasteful energy consumption for supplying paint, and the optimum use of energy is achieved. Also bookReference exampleIn this coating system, the air in the painting space 40 in the base tank 41 is sucked upward, whereby the paint powder floating in the painting space 40 can also be sucked upward. An air suction device 46 for removing the coating powder remaining in the space 40 to the outside of the coating space 40 is provided. As shown in FIG. 15, the device 46 communicates with a suction duct 47 (FIG. 18) having a loop shape disposed in the upper part of the painting space 40 along the lower contour of the work, and the suction duct 47. It consists of a powder coating material recovery device 26, and sucks together air and floating coating material powder in the coating space 40 in the base tank 41 by operating the suction fan 27 of the recovery device 26. If the suction force is set weak, the gravity of the powder coating itself, the buoyancy applied to it, the spraying ability of the coating powder and the above air suction force are well balanced, so the cloud where the powder coating is floating When the above suction force is increased, the coating powder floating and remaining in the coating space 40 is strongly sucked upward, and thus unused in the coating space 40. The paint powder can be quickly collected by the powder paint collection device 26. The recovery device 26 separates and recovers the recovered paint powder from the air in the filter 28. The separated recovered powder paint is finally returned to the recovered paint tank 18 through the vibrating sieve 19. Thereafter, the powder coating material stored in the tank 18 is blown up into the coating space 40 from the outlet 48 by the operation of the coating material blowing device 14 and reused. Finally, bookReference exampleAs shown in FIG. 15, the coating system of FIG. 15 includes a voltage applying device 29 of a high voltage generator connected to each electrode 7 of the electrode frame 6 in the base tank 41. A high voltage can be applied between each electrode 7 and the workpiece 1 at the coating position A. Therefore, by applying a high voltage in the cloud in which the powder coating is floating in the coating space 40, the coating powder floating in the coating space 40 is ionized and travels to the work 1 along the lines of electric force. It is guided and applied to the surface of the work 1. So bookReference exampleThe powder coating system can also perform electrostatic powder coating similar to that in the first and second embodiments for each work 1 in the limited coating space 40 inside the base tank 41. In addition, the energy consumption required for coating is remarkably small, and there is an advantage that powder coating can be reliably performed even on a three-dimensional workpiece.
[0014]
【The invention's effect】
As described above, according to the present invention, a limited space surrounding the work is formed for each work to be transported, and a cloud in which the powder paint floats is generated in the space, and subsequently A batch-type novel powder coating system capable of electrostatic powder coating by applying a high voltage to a workpiece is provided.
According to the present invention, in the above-described batch type powder coating system, electrostatic powder coating can be performed in a cloud in which the powder coating is floating even on a three-dimensional workpiece having irregularities. Moreover, the effect that less energy consumption is required for painting can be obtained.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing an overall configuration of a powder coating system according to a first embodiment of the present invention.
FIG. 2 is a top view of a dome lid and its surrounding members used in the powder coating system shown in FIG.
3 is a diagram showing a cross section taken along line AA of FIG. 2 with respect to the dome lid and its peripheral members shown in FIG. 2;
4 is a diagram showing a cross section taken along line BB of FIG. 2 with respect to the dome lid and its peripheral members shown in FIG. 2;
FIG. 5 is a top view of the dome lid and its surrounding members shown in FIG. 2 as viewed from above.
6 is a view showing a cross section taken along the line CC of FIG. 5 with respect to the dome lid and its peripheral members shown in FIG. 5;
7 is a diagram showing in detail an electrode frame inside the dome lid with respect to the dome lid and its peripheral members shown in FIG. 2;
FIG. 8 is a diagram showing in detail the configuration of the paint blowing device for the dome lid and its surrounding members shown in FIG. 2;
FIG. 9 is a time chart showing an operation procedure of the powder coating system according to the first embodiment.
FIG. 10 is a view showing a modified example 1 of the dome lid and its surrounding members used in the powder coating system of the first embodiment in the same cross section as in FIG. 3;
FIG. 11 is a view showing a modified example 2 of the dome lid and its surrounding members used in the powder coating system of the first embodiment in the same cross section as in FIG. 3;
FIG. 12 is a schematic diagram showing an overall configuration of a powder coating system of Example 2.
13 is a top view of a dome lid and its surrounding members used in the powder coating system shown in FIG. 12. FIG.
14 is a diagram showing a cross section taken along line DD of FIG. 12 with respect to the dome lid and its peripheral members shown in FIG. 12;
FIG. 15 showsReference exampleIt is the schematic which shows the whole structure of the powder coating system.
16 is a view of the base tank shown in FIG. 15 as viewed from above along the line EE of FIG. 15, and shows the configuration of the electrode frame in detail.
FIG. 17 is a view of the base tank shown in FIG. 15 as viewed from above along the line FF in FIG. 15, and is a view showing in detail the configuration of the paint spraying device.
FIG. 18 is a diagram showing in detail the configuration of the air suction device for the base tank and surrounding members shown in FIG. 15;
[Explanation of symbols]
1 Work
2 Base floor
3 Dome lid
4 painting space
5 Lid member
6 Electrode frame
7 electrodes
8 Space inside the filter wall
9 Space between the filter wall and the inner surface of the dome lid
10 Filter wall
11 Lid moving device
12 Inside the dome lid
13 joint
14 Paint blowing device
15 outlet
16 Powder paint supply device
17 Air supply source
22 First air suction device
23 Second air suction device
24 Suction duct
25 Suction duct
26 Powder paint recovery equipment
29 Voltage application device
31 base floor
32 Dome lid
33 Lid moving device
34 Slit forming wall
35 Air suction device
36 Suction duct
40 painting space
41 Base tank
42 Ceiling material
43 Work conveying device
45 Hanger
46 Air suction device
47 Suction duct
48 outlet
50 Suction fan
P Workpiece transport direction

Claims (3)

A coating system that creates a cloud of floating powder paint in a limited space surrounding the work and performs electrostatic powder coating.
A base floor,
A workpiece carrying device that conveys the workpiece to a painting position above the base floor, stops the workpiece, and sends the workpiece from the painting position after the painting is completed;
A dome lid that is formed of an integral lid or a plurality of lid members and that can be covered and covered as a whole; and
An electrode-attached frame, the electrode frame fixed to the inside of the dome lid;
A device for moving the dome lid forward and backward with respect to the workpiece at the painting position, covering the workpiece with the dome lid, and the substantially closed coating surrounding the workpiece with the dome lid and the base floor. A lid moving device capable of forming a space;
An apparatus for supplying a fluid mixture of powder paint and air, wherein the paint fluid is provided at a lower portion of the paint space,
An air suction device that sucks air in the coating space upward, and floats the powder coating material blown out from the outlet in the coating space like a cloud;
A voltage application device for applying a high voltage between the electrode inside the dome lid and the workpiece at the coating position to apply a powder paint floating in the coating space to the workpiece. A powder coating system. A first air suction device that stretches a filter wall between the inner surface of the dome lid and the electrode frame over the entire inner surface, and sucks air in a space between the filter wall and the inner surface of the dome lid. And a second air suction device for sucking air in the coating space inside the filter wall. An air suction device that stretches a slit-forming wall across the entire inner surface between the inner surface of the dome lid and the electrode frame, and sucks air in a space between the slit-forming wall and the inner surface of the dome lid The powder coating system according to claim 1, comprising:

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