KR0135274B1 - Forming method of patterned coating - Google Patents

Abstract

None.

Description

Form coating film formation method

1 is a rear view of the object to be painted using the method according to the present invention from the back.

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a front view of the surface of the object to be painted.

4 is a cross-sectional view similar to FIG. 2 showing another example of the coating method.

5 is a front view in which a part of the assembly using the magnet pieces of the left and right multipoles is omitted.

6 is a perspective view of an assembly using a magnet piece of two circumferential poles.

7 is a front view showing a modification of the assembly using the magnet pieces of the circumferential two poles.

8 is a front view showing still another modified example of the aggregate using the magnet pieces of the circumferential dipole.

9 is a perspective view of an assembly using a magnet piece of a columnar dipole and a columnar multipole.

10 is a perspective view of an assembly using a U-shaped magnet piece and a rod-shaped magnet piece.

11 is a front view showing a shape formed on an object to be coated by a conventional technique.

12 is a front view showing a method of assembling the magnet.

* Explanation of symbols for main parts of the drawings

10, 40: coating 20, 42: coating powder containing magnetic powder

24: shapes 11, 51, 61, 71, 81: magnet pieces

15, 55, 63, 75, 85: aggregate 30: adhesive tape

M: magnetic field

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to a method of imparting a shape to a surface to be coated, and more particularly to a method of forming a shape of various characters, figures, and the like on a painted surface with different color tones from surroundings.

As a method of giving a shape formed by various letters, figures, etc. to a part of the coated surface, the whole coated surface is painted in a ground color, and then a part of the coated surface is coated with a separate paint, a coloring sheet or a colored tape The attached method, the method of processing unevenness | corrugation on a to-be-painted object, and monochromatic painting and shading are used. However, in these methods, the operation of attaching the masking tape requires excessive time in order to repeat the cumbersome operation, makes layers unsightly in the shape portion, and the coloring tape or the coloring sheet is easily peeled off, There is a problem such that the shade is not expressed in a clear shape by the nature of the light hitting.

In Japanese Patent Application Laid-Open No. 63-175670, a method of forming a coating film is formed by forming a liquid coating film containing a powder-forming magnetic material on the surface of an object to be coated or a colored coating film, while the coating film is in a fluid state. It describes in the method of forming a shape by applying a magnetic force to the magnetic material of the part made into. According to this method, the shape according to the shape and size of the magnet is revealed because the orientation of the magnetic material of the portion of the powder-like magnetic material uniformly dispersed throughout the coating film is different from that of other portions. have.

However, when the coating was actually performed using this method, it was found that no clear shape was obtained according to the shape of the magnet. This will be described with reference to the accompanying drawings. For example, as shown in FIG. 12, two bar magnets 91 and 92 are intersected in a T-shape, and as shown in FIG. Approaching the paint film surface 93, a portion of the magnetic material moves in the paint film to generate color tone portions 95, 96, 97, and 98 that are different from the surroundings, but they fall short of forming a sharp T-shaped outline. This is because the orientation of the magnetic material can be changed by moving the magnetic material in the strong magnetic portions at both ends of the bar magnet, but the orientation of the magnetic material does not change and the shape cannot be formed because the magnetic force is weak in the middle portion. In other words, it was proved that only the acting magnet was obtained to obtain the desired shape (a distinctive contour not acting on the magnet).

An object of the present invention is to provide a method in which the conventional method of forming a shape by acting a magnet can be improved to form a clear shape.

It is another object of the present invention to provide a method which makes it possible to form a shape in any shape without being limited by the shape of the magnet itself.

In the first aspect of the present invention, a plurality of separate pieces of magnets are arranged in close proximity to each other so as not to contact each other to form a scattering point-shaped aggregate, and the position is determined by approaching the back side of the object to be painted. Next, a coating film containing a magnetic powder is coated on the object to be coated to form a coating film, and then, the coating film is cured to form a shape coating film in which a shape corresponding to the injection point shape appears on the coating film surface. do.

According to this method, since the paint containing the magnetic powder is coated on the object to be coated with the magnetic force lines formed between a plurality of separate magnet operations constituting the aggregate, the magnetic powder moves along the magnetic lines in the process of being applied. As the coating film loses fluidity, its moving speed becomes slow, and when it is completely cured, it is fixed at that position. Accordingly, the magnetic powder is oriented in accordance with the direction of the magnetic lines of force, and a shape corresponding to the dispersion point-shaped aggregate formed of a plurality of magnet pieces is formed. However, this shape does not necessarily correspond to the shape of the magnet, and since the direction of the magnetic force line is changed by changing the direction of the magnet piece, a special action effect that can realize a subtle color change different from the shape of the magnet is obtained.

As a magnet operation, many things with various characteristics and shapes, such as a metal magnet, a ferrite magnet, a sintered magnet, and a sintered magnet, can be used, and after shape | molding these into small separated shapes and combining them, using adhesive tape or a support member, You can construct an aggregate.

In addition, the shape of the magnet piece can be freely selected in addition to a small quadrilateral or a circular shape, such as a triangular shape and a polygonal shape, and a combination of these forms an arbitrary shape.

In the present invention, when one magnet piece has two or more N-poles and S-poles (multi-poles), the aggregates constituting one line are two or more magnet pieces, Preferably about 3 or more is preferable, but when there is only one N pole and one S pole (two poles) in one magnet piece, the aggregate constituting one line depends on the configuration and length of the line, but three As mentioned above, Preferably, it consists of five or more magnet pieces.

As a particularly suitable example, if each magnet piece is composed of a square or a circle magnetized so that the magnetic poles are positioned at both ends, the adjacent magnet pieces are fixed to be positioned in the direction in which their N and S poles are adjacent to each other. Strong lines of magnetic force are generated between the magnets so that the shape is formed more clearly. Alternatively, the magnet pieces may be composed of rod magnets or U-shaped magnets magnetized so that the magnetic poles are positioned at both ends, and the adjacent magnet pieces may be positioned in a direction in which the N and S poles are close to each other. These magnets may be electromagnets.

In the second state, in the second state, a plurality of separated pieces of magnets are provided in close proximity to each other so as to form a dispersion point-like aggregate, and a coating containing magnetic powder is coated on the workpiece. A coating film is formed, and the aggregate approaches the coating film while the coating film is in a flow state, and then the coating film is cured to provide a shape corresponding to the dispersion point shape on the coating film surface.

In this state, the assembly is prepared in advance with a magnetic force line formed between a plurality of separated magnet pieces, and after the coating film is kept in a flow state after coating a paint containing magnetic powder on the object to be coated, the assembly is moved. Approaching the surface or backside of the coating film, the magnetic powder in the coating film in the flow state starts to move along the magnetic force line, and as the coating film loses fluidity, its moving speed is slowed down and is completely fixed at that position. . Therefore, the magnetic powder is oriented according to the direction of the magnetic lines of force, and a shape corresponding to the aggregate of the dispersion point shape formed of a plurality of magnet pieces is formed.

The magnetic powder to be contained in the coating may be a powder material which can be contained in the coating while being able to move or change its orientation depending on the magnetization action such as stainless powder, iron powder, Fe ₃ O ₄ coated mica powder or the like. Among these materials, Fe ₃ O ₄ coated mica powders are known as pigments in paints, and thus, those which are susceptible to the magnetization effect can be used among powder materials blended as pigments in ordinary paints and the like.

As the paint, as long as it is formed in a liquid state, that is, in a fluid state, and then hardened by a suitable means such as baking or drying, a conventional paint can be used. As the paint, in addition to the magnetic powder, a pigment, a colorant, a curing agent, a solvent, and other conventional components are contained. The content of the magnetic powder to the paint may be such that a clear shape appears when subjected to the magnetizing action, and specifically, it is preferable to contain the magnetic powder of 0.1% or more of the paint.

The paint is used in addition to the baking paint that is cured by baking after coating. In addition, after coating only one layer of the coating material containing the magnetic powder, or the base coating containing the magnetic powder, the base coating after coating the surface without curing the base coating without coating the base coating The coating of the 2 coating / baking type | mold, etc. which freely apply | coats a clear paint to the surface, and hardens a base paint and a clear paint after that, is used freely. As long as the coating film is formed at least in a state in which the magnetic powder-containing coating layer is apparently visible, the method is also applied to the method of forming a coating film having any coating step. For example, when a variety of ordinary colored undercoat or intermediate coating paints are applied to the base of a magnetic powder-containing paint, the coloring of the lower coating layer is partially seen due to the movement or orientation of the magnetic powder. It can be concealed and float the shape shape well. In addition, the magnetic powder-containing paint layer may be protected by coating a substantially transparent upper coating paint or the like on the magnetic powder-containing paint so as not to conceal the magnetic powder-containing paint.

As the to-be-coated object to be apply | coated, it is preferable to form with synthetic resin, rubber | gum, ceramic, or nonmagnetic material, such as aluminum, and nonmagnetic material. This is because when the object to be coated is adhered to the aggregate formed by the magnetic pieces on the back side of the coating surface to give magnetization effect to the magnetic powder-containing paint, the coating itself is susceptible to magnetization action. This is because the entire face is uniformly magnetized so that the magnetization action cannot be imparted only to the shape portion of the aggregate. However, since the magnetization of the aggregate on the painted surface varies depending on the strength of the magnetic force of the magnet pieces and the thickness of the workpiece, any material having only a certain degree of magneticity as the material of the workpiece can be used when the thickness thereof is thin. In particular, in the case where the aggregate is coated and provided close to the surface side of the coating film which maintains fluidity, the influence of the magnetism of the object to be coated is small.

In the case where the magnet piece is adhered to the back side of the object to be approached to the magnetic powder-containing coating layer, the thinner the object is, the better the magnetization effect is caused by the magnet piece. Therefore, in this method, it is desirable to set the strength of the magnetic force of the magnet piece in accordance with the thickness of the object to be painted.

When the aggregate of the magnet pieces is kept close to the surface of the magnetic powder-containing paint layer from the surface side of the workpiece, the influence of the material and the thickness of the workpiece does not occur. In this case, however, the holding means for the aggregate is required, and it is necessary to prevent the curing step by baking or heat drying of the painted surface.

In the process of hardening the paint by baking, normal condition, or the like in which the aggregate of the magnet pieces is brought close to the painted surface, it is preferable to keep the aggregate so as not to move until the magnetic powder of the paint loses fluidity and is fixed. However, if the tapes for sticking and holding the aggregate of the magnet pieces to the workpiece are melted and adhered by heat, it is cumbersome to remove them, and the magnet pieces themselves are deteriorated by heat. If the magnet assembly is removed when the solvent is flushed off by dissipation or heating and the fluidity of the already coated film is lost, the shape is already formed, and thus the above problems can be solved and practical.

After the magnetic powder of the paint is fixed in a state in which the desired shape is formed and the cured coating film is formed, the object to be coated remains in the shape even when the aggregate of the magnet pieces is removed from the object to be coated. The object to be coated may be used as a product as it is, or a suitable finish may be applied to the coated surface again.

The method of forming a shape coating film according to the present invention is applicable to the case of forming a shape shape having a constant repeating pattern on the entire coating surface, in addition to attaching a shape shape different from the circumference to only a part of the coating surface, such as various characters or figures. There is a number.

Other features and advantages of the present invention will become apparent from the following description with reference to the embodiment of FIGS. 1 to 10 of the accompanying drawings.

FIG. 1 shows the back surface of the object to be coated 10, in which a plurality of separated pieces of magnets 11 are installed in close proximity to each other according to the present invention so as not to contact each other to form a dispersion point shape. Is attached by the adhesive tape 30.

Each of the magnet pieces 11 is formed of a thin plate of a rectangular shape having magnetic poles of the N side and the S pole at both ends, and adjacent magnetic pieces are positioned so that the N pole and the S pole are close to each other to generate a strong magnetic force line. have.

2 shows the positional relationship between the object to be coated 10 and the magnet piece 11 in cross section, and the magnet piece 11 is in close contact with the rear surface of the object to be coated 10.

3 shows a state in which the object to be coated 10 is seen from the front side, and as described above, the paint 20 containing magnetic powder on the object 10 to which the assembly 15 of the magnetic pieces is closely adhered and fixed. ), The magnetic powder in the paint in the flow state is moved in the coating film in the direction of the magnetic force line of the aggregate 15, and as a result, the changed portion 24 is colored on the coating film. This shape is an L-shaped continuous shape and corresponds to the dispersion point shape formed by the aggregate 15 of the magnet pieces 11, but does not correspond completely to the dispersion point shape.

Subsequently, when the coating film is cured by curing the coating film, the L-shaped shape is fixed, and the peripheral edge portion thereof appears on the coating film surface in a clear shape without blurring. This shape appears as a change in color tone on the surface of the coating film, but does not cause irregularities on the surface, and does not cause a layer on the peripheral edge portion of the shape as in the prior art. In this way, a predetermined shape is revealed in the coating film, and this shape is not easily extinguished, and the shadow does not change due to the change of light.

4 shows another example of the coating method, and the present invention is applied to the intermediate coating paint layer 41 formed by baking the intermediate coating paint after proper pretreatment on the surface of the coating 40. This is an example. After the magnet piece 11 is brought into close contact with the back surface in the same manner as in the above-described embodiment, after the layer 42 containing magnetic powder is coated on the intermediate coating layer 41, the appearance according to the present invention appears. A clear paint layer 43 is applied to the surface to form a clear paint layer 43, and after setting, the magnet piece aggregate is removed, and then the layers 42 and 43 are simultaneously baked and cured. In such a case, since there is an intermediate chart paint layer, it is preferable to provide a strong magnet piece so that the magnetic lines of force do not weaken.

FIG. 5 is a close-up view of magnetic pieces 51 and 52, which are called left and right multi-poles, in which a plurality of N-poles and S-poles are alternately installed to form an aggregate 55, thereby forming a wide I-shaped shape on a workpiece. It is an example of formation. Adjacent magnet pieces 51 and 52 are alternately provided in opposite directions so that the N pole and the S pole approach and face each other. According to such an installation, since the magnetic force lines M are aligned along the longitudinal direction of the aggregate 55, a wide I-shaped shape appears.

FIG. 6 shows an assembly 63 formed by closely installing magnet pieces 61 and 62 called circumferential two poles in which the N pole and the S pole are located on the left and right sides of the circumferential body. This is an example of forming a shape. Adjacent magnet pieces 61 and 62 are aligned so that their north pole and south pole approach and face each other. The aggregate 63 has the shape of a point of dispersion of the points in which the circumference is decreased, but the magnetic force lines pass near the center of each circumference, and a continuous C-shaped shape appears on the object to be coated.

FIG. 7 shows a variation of FIG. 6, in which the magnet pieces 64 and 65 of two circumferential poles in which the N pole and the S pole are located are arranged adjacent to the left and right sides of the circumference to form the aggregate 66 and the bow shape is formed. It is an example to form. Magnet pieces 64 and 65 adjacent to each other are installed such that their N and S poles are alternately adjacent to each other located on the left and right. The aggregate 66 has a dot-shaped dispersion point shape in which the circumferences are aligned, but the lines of magnetic force pass near the sides of each circumference, and a continuous bow appears on the workpiece.

FIG. 8 shows a modification of FIG. 7, and the aggregate 69 is formed by closely installing magnet pieces 67 and 68 of two circumferential poles on which the N pole and the S pole are located on the left and right sides of the circumference. Magnet pieces 67 and 68 are provided so that their N poles and S poles are adjacent to each other. Since the repulsive force acts between adjacent magnetic poles, the magnetic force line M is weakened and dispersed, but a weak magnetic force line is formed between the N pole and the S pole in the crossing direction, and may exert a magnetic force on the magnetic powder in the coating film. . The aggregate 69 has a dot-shaped dispersion point shape in which the circumferences are aligned, but the magnetic force lines pass zigzag around the center of each circumference, and an almost continuous bow appears on the workpiece.

FIG. 9 shows magnet pieces 61 and 62 of two circumferential poles in which the N poles and the S poles are located on the left and right sides of the cylinder, and a magnet of the circumferential pole in which the N poles and the S poles alternately exist in front, rear, left and right of the cylinder. The assembly 75 is formed by combining the pieces 71 and 72, and an H-shaped shape is formed on the object to be painted. The magnet pieces 71 and 72 of the circumferential multipole are provided so that the N pole and the S pole of adjacent magnet pieces approach and face the S pole or the N pole, respectively. Even in this case, a continuous H-shaped shape appears instead of a dot shape on the workpiece.

FIG. 10 shows an example in which an aggregate 85 is formed by combining U-shaped magnet pieces 81 and 82 and rod-shaped magnet pieces 83 and 84 to form a lattice shape on the object to be coated 10. to be. N or S poles appear at the end of each magnet alone, so if they are alternately placed so that their polarities are opposite to the magnets adjacent to the front, rear, left, and right sides, a magnetic force line M extending in the shape of a lattice is obtained, which is not a stepping bridge. The lattice shape is revealed on the workpiece 10.

Whether the polarity of each magnet piece is the N pole or the S pole can be easily determined by bringing the needle of the compass close, so that it is not difficult to determine the position of the magnet piece. Each piece of magnet can be fixed using adhesive tape or thick paper, and can be easily replaced after use, so that the workpiece is not injured.

As described in detail above, according to the present invention, a vivid shape can be formed on the coating film by using a plurality of separated pieces of magnets, so that the shape is permanent and free from unevenness, peeling off or erasing. It becomes the shape that is. This shape is not limited to the shape of the magnet itself, and can form a shape of any shape. The non-magnetic material and diamagnetic material are preferable as the object to be coated. However, even if the ferromagnetic material is thin, the technical effect is remarkable.

Claims (6)

A plurality of separated pieces of magnets are placed in close contact with each other so as to form a dispersion point-like aggregate, the aggregate is positioned by approaching the back side of the workpiece, and a coating containing magnetic powder on the workpiece is placed. A coating film is formed by forming a coating film, and hardening the coating film so that the shape corresponding to the dispersion point shape is exposed on the coating film surface. A plurality of separated magnet pieces are installed in close proximity to each other so as not to contact each other to form a dispersion point-shaped aggregate, and a coating containing magnetic powder is coated on the workpiece to form a coating film, and the coating film is in a flow state. And the aggregate is brought close to the coating film, and the coating film is cured so that the shape corresponding to the dispersion point shape is exposed on the coating film surface. The magnet pieces of claim 1, wherein the magnet pieces are formed in a quadrilateral shape or a circle magnetized so that the magnetic poles are located at both ends. The magnet pieces adjacent to each other are positioned in a direction in which their N and S poles are close to each other. Form coating film forming method characterized in that. The magnet pieces of claim 1, wherein each of the magnet pieces is formed of a magnet or a magnet magnetized so that magnetic poles are positioned at both ends thereof, and adjacent magnet pieces are positioned in a direction in which their N and S poles are adjacent to each other. Form coating film forming method characterized by the above-mentioned. The magnet pieces of claim 2, wherein each of the magnet pieces is formed in a quadrangular shape or a circle magnetized so that magnetic poles are positioned at both ends of the magnetic poles, and adjacent magnet pieces are positioned in a direction in which their N and S poles are close to each other. Form coating film forming method characterized in that. 3. The magnet pieces according to claim 2, wherein each of the magnet pieces is formed of a magnet or a magnet magnetized so that magnetic poles are positioned at both ends, and adjacent magnet pieces are positioned in a direction in which their N and S poles are close to each other. Form coating film forming method characterized by the above-mentioned.

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