KR100984334B1 - Manufacturing method of ornamental panel - Google Patents

Abstract

The present invention relates to a method for manufacturing a decorative panel and a panel manufactured therefrom, wherein after cutting a sheet material formed by surface processing into a plurality of cells through a drawing step, a cell sorting step, an arrangement step, a cutting step and an assembly step, The present invention relates to a method for manufacturing a decorative panel and to a panel manufactured therefrom, which are rotated in a direction and decorated so as to look different according to the surrounding environment or the direction of the viewer.

Art, decoration, attachment, manufacturing

Description

MANUFACTURING METHOD OF ORNAMENTAL PANEL}

The present invention relates to a method for manufacturing a decorative panel, and more particularly, as a decoration of a new sculptural painting highlighting the advantages of painting and sculpture through a combination of painting and sculpture, which can be used for decoration in various fields such as art or architecture. It relates to a method for producing a panel.

In general, decorative panels are installed on the walls to decorate the interior of a store, a home, an office, and the like to have a beautiful appearance.

Such decorative panels have various forms, such as paintings, photographs, and sculptures installed on the panels, which can be used not only in the interior industry but also in the art world based on the ability of the creators to hold exhibitions.

The decorative panel according to the prior art is manufactured by hand, which is difficult to make detailed drawings, difficult to cut precisely, not only wastes materials, but also makes it difficult to manufacture the same panel from a single pattern, and it is impossible to mass-produce, thus lowering productivity. There is this.

In addition, the prior art is difficult to produce a variety of expression effects because there is no difference in the expression effect of the panel according to the surrounding environment or viewing angle, it is not easy to use universal.

The prior art has a fixed image that does not change according to the installation environment because there is no element of interactive presence that accommodates the external environment.

In addition, the prior art has a difficulty in conveying the feelings of the two expression methods at the same time as it is focused on painting or sculpture.

Therefore, the manufacturing method of the decorative panel according to the present invention has been devised in view of this point, it is possible to reduce the material cost as well as to reduce the material cost by enabling detailed drawings by working with a computer It is an object to improve the productivity by enabling the production of a large number of the same panel as a design, and to enable mass production to automate the production of a plurality of panels in a short time.

In addition, the present invention enables to apply a plurality of materials to a single panel, and to produce a variety of expression effects by varying the expression effect of the panel according to the surrounding environment or viewing angle, art, interior industry, exterior industry, etc. It aims to be able to use universally regardless of indoor and outdoor spaces.

An object of the present invention is to reflect the surrounding environment to make it compatible with the surrounding environment.

In addition, the present invention can deliver a feeling of painting and sculpture at the same time, the production of a decorative panel that can emphasize the feeling of painting using a planar material, or to emphasize the feeling of the sculpture using a three-dimensional material. The purpose is to provide a method.

The above object is a drawing step of creating a drawing, dividing the drawing into a plurality of cells, a cell classification step of individually assigning properties corresponding to the cells, classifying the same attributes among the cells by layer, and Arranging step of moving or rotating the cells of the layer to match the grain direction of the plate, cutting step of cutting the plate in the shape of the cell arranged in the layer and assembling step of assembling the plate to the support plate as the pattern It is achieved by providing a method for producing a decorative panel.

The cutting may include converting the layer into computer code, inputting data, at least one of dyeing, painting, coating, corrosion, scratching, or sanding to highlight the surface effect individually according to the properties imparted to the cell. It is preferable to include the step of processing the surface of the plate material with any one and cutting the plate material in the shape of the cell by the data input to the computer.

In addition, the support plate is preferably processed to the surface by at least one of dyeing, painting, coating, corrosion, scratching or sanding.

In addition, the plate is preferably assembled to at least one of an adhesive, screwing, welding or nails to the support plate.

In addition, the plate is provided with a fitting groove on the bottom surface, the support plate is provided with an insertion groove so as to be symmetrical to the fitting groove of the plate material to insert the core member into the fitting groove and the insertion groove at the same time to fix the plate to the support plate It is desirable to.

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The above object is a drawing step of creating a pattern, a cell classification step of dividing the drawing into a plurality of cells, and individually assigning an attribute corresponding to the cell, each of the cells so that the grain direction of the sheet and the property of the cell coincide Arrangement step of arranging in one layer by moving or rotating the cutting, Cutting step of cutting the plate material in the cell shape arranged in the layer and Fabrication of a decorative panel comprising an assembly step of assembling the plate material to the support plate according to the pattern By providing a method.

The cutting may include converting the layer into computer code, inputting data, at least one of dyeing, painting, coating, corrosion, scratching, or sanding to highlight the surface effect individually according to the properties imparted to the cell. It is preferable to include the step of processing the surface of the plate material with any one and cutting the plate material into the cell shape by the data input to the computer.

In addition, the plate is provided with a fitting groove on the bottom surface, the support plate is provided with an insertion groove so as to be symmetrical to the fitting groove of the plate material to insert the core member into the fitting groove and the insertion groove at the same time to fix the plate to the support plate It is desirable to.

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As described above, the method for manufacturing a decorative panel according to the present invention can be a detailed design by computer work, accurate cutting can reduce the material cost, as well as a plurality of the same panel in one design It can be manufactured and automated, which enables mass production to manufacture a large number of panels in a short time, thereby improving productivity.

In addition, the present invention can apply a plurality of materials to a single panel, and because the expression effect of the panel is changed according to the surrounding environment or viewing angle, it is possible to produce a variety of expression effects, such as in the art world, interior industry, exterior industry, It can be used universally regardless of the external space.

According to the present invention, it is possible to use a material that reflects the surrounding environment, so that the image of the surrounding environment has an effect of overlapping, thereby being environmentally friendly.

In addition, the present invention can convey the feeling of painting and sculpture at the same time, it is possible to emphasize the feeling of painting using a planar material, or to emphasize the feeling of the sculpture using a three-dimensional material.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of a method for manufacturing a decorative panel according to the present invention.

In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout the specification.

1 is a flow chart of a method of manufacturing a decorative panel according to an embodiment of the present invention.

As shown in Figure 1, the manufacturing method of the decorative panel according to an embodiment of the present invention is a design step (S10), cell sorting step (S20), arrangement step (S30), cutting step (S40) and assembly step ( S50).

2 is a view showing a design step (S10) in the method of manufacturing a decorative panel according to an embodiment of the present invention.

As shown in FIG. 2, the drawing step S10 is a step of drawing a shape to be expressed, and then manually drawing the data into a computer, or drawing directly onto a computer through a software drawing a drawing 5. have.

3 is a view illustrating a cell classification step S20 in the method of manufacturing a decorative panel according to an embodiment of the present invention.

As shown in FIG. 3, the cell classification step S20 is a step of dividing the drawing 5 illustrated in the drawing step S10 into a plurality of cells 10.

In the cell classification step S20, coordinates of the vertices in the drawing 5 are input, and the guide lines connecting the respective vertices are divided into a plurality of cells 10 separated by the guide lines.

If there is no vertex in the drawing (5), after arranging arbitrary points and inputting guide lines connecting the respective points and divided into a plurality of cells 10 separated by the guide lines.

In addition, in the cell classification step (S20), the individual attributes are assigned to each of the divided cells (10).

Here, the individual properties indicate how the cells 10 are arranged along the grain direction and how the surface of the cells 10 are to be processed so as to produce different expression effects according to the directions in which the cells 10 look. .

In the cell sorting step (S20), when the computer is used, the drawing 5 can be easily coordinated, the property is given to the cell 10, and it is convenient to classify the cells 10 having the same property during operation.

4 is a view showing the arrangement step (S30) in the method for manufacturing a decorative panel according to an embodiment of the present invention.

As shown in FIG. 4, the arranging step S30 classifies the same attributes among the layers 10 sorted by the layer 20 among the cells 10 classified in the cell sorting step S20, and determines the attributes of the cells 10 and the grain direction of the sheet. This is a step of moving or rotating the cells of each layer 20 to coincide.

Here, the plate means a material in which grains are formed on the surface among various kinds of raw materials.

In this detailed description, the surface of the plate is polished to form a grain, and the stainless plate 30 on which the surface is reflected will be described as an example.

Since the stainless steel plate 30 has a grain formed on the surface, the direction and degree of reflection of light due to the bending of the grain are different, and thus the degree of surface effect is varied according to the viewing direction, and the surrounding objects are reflected and reflected.

Of course, in addition to the stainless steel plate 30 to produce a variety of expression effects, it is possible to apply a variety of metal, non-metal plate and various colors of acrylic plate, transparent acrylic plate, glass, wood and the like.

For example, when the property of the cell 10 is in the vertical direction, the cells 10 having the same property are collected to form one layer 20, and then the layer 20 is formed to match the grain direction of the stainless plate 30. Move or rotate the cells 10.

In addition, when the property of the cell 10 is in the horizontal direction, cells 10 having the same property are collected to form one layer 20, and then the cells of the layer 20 may be matched to the grain direction of the stainless plate 30. 10) move or rotate them.

That is, in the arrangement step S30, the layers 20 are formed as much as the type of the property, and the cells 10 of each layer 20 are moved or rotated to match the grain direction of the stainless plate 30.

In addition, the stainless plate 30 is also provided with the number of layers 20, it is preferable that one stainless plate 30 to take one layer 20.

The cells 10 are preferably arranged to be spaced apart from each other in order to consider the cutting error when arranged in the layer 20, and to protect the work surface and increase the efficiency of the work.

5 is a flowchart of a cutting step in the method of manufacturing a decorative panel according to an embodiment of the present invention, Figure 6 is a view showing a step of cutting in the manufacturing method of a decorative panel according to an embodiment of the present invention.

5 to 6, the cutting step S40 is a step of cutting the stainless plate 30 to match the shape of the cell 10 arranged in the layer 20.

Cutting step S40 is largely composed of a step (S42) for inputting data, a step (S44) for processing the surface, a step (S46) for cutting.

First, the step of inputting data (S42) is to cut the computer by converting the layer 20 into computer code so that the computer cutting device 50 can be used for accurate cutting when cutting the stainless plate 30 in the shape of the cell 10 Entering data into the device 50 is performed.

The step of processing the surface (S44) is a step of processing at least any one of dyeing, painting, coating, corrosion, scratching or sanding the surface of the stainless plate 30 when the expression power is insufficient only by the surface texture of the stainless plate 30 to be.

Of course, when using a material that is naturally formed, such as wood when using a plate can be applied without processing to preserve the unique texture of the wood.

When the surface is processed for each layer 20 in the step S44 of processing the surface, more various surface effects can be produced according to the viewing angle.

In addition, the cutting step S46 is a step of cutting the stainless plate 30 in the shape of the cell 10 arranged in the layer 20 according to the data input to the computer cutting device 50.

Cutting (S46) is preferably to use a computer cutting device 50 equipped with a laser beam 52 for accurate cutting, it is also possible to use a variety of cutting methods, such as waterjet, saw blade cutting, CNC machining.

Cutting step (S46) by using a computer cutting device 50 equipped with a laser beam 52 to evenly cut the cut surface of the stainless steel plate 30 to prevent the assembly is not possible to deviate from each other.

The order of the step S44 and the step S46 of cutting the surface may be reversed, and the surface may be processed for each cell 10.

7 is a view showing an assembling step in the method of manufacturing a decorative panel according to an embodiment of the present invention, Figure 8 is a decorative panel manufactured by the method of manufacturing a decorative panel according to an embodiment of the present invention. 9 is a cross-sectional view of FIG. 8.

As shown in Figure 7 to 9, the assembling step (S50) is a step of assembling each of the stainless plate 30 cut in the cutting step (S40) to the support plate 40.

First, the support plate 40 is a plate to which each of the stainless plate 30 is assembled, may be all covered by the stainless plate 30, the space between the blank, the space between the stainless plate 30 or the stainless plate 30 It may also be seen outward by the holes formed.

The support plate 40 preferably processes the surface with at least one of dyeing, painting, coating, corrosion, scratching or sanding for aesthetic effect.

Here, the support plate 40 not only serves to support the plate, but also serves to additionally overlap or different effects from the plate.

In addition, since the support plate 40 can be used by being replaced by a plate, it is possible to double the effect to be expressed by overlapping the plates of the same material, various expressions using various effects generated between the plates of different materials The effect can be expressed.

The stainless plate 30 cut in the shape of the cell 10 in the cutting step S40 is fixed to the support plate 40 by bonding with silicon, epoxy or adhesive.

The stainless plate 30 cut in the shape of the cell 10 in the cutting step S40 is fixed to the support plate 40 by bonding with an adhesive such as silicon or epoxy.

Alternatively, the stainless plate 30 may be screwed or welded to the support plate 40, or may be fixed by nailing.

Or, in order to facilitate the removal of the stainless plate 30 is provided with a fitting groove 12 in the bottom surface of the stainless plate 30, the upper surface of the support plate 40 in the fitting groove 12 of the stainless plate 30 The insertion groove 42 is provided to be symmetrical.

And, it is preferable to include a core member 60 is inserted into the fitting groove 12 and the insertion groove 42 at the same time to fix the stainless plate 30 to the support plate 40.

The core member 60 is forcibly fitted into the fitting groove 12 and the insertion groove 42 to be fixed and facilitates detachment of the stainless plate 30 because it is provided to be detachable.

Here, when the plate of a transparent or translucent material such as glass is used instead of the stainless plate 30, the core member 60 can be a decoration to represent a spot pattern.

In addition, when the support plate 40 is made of a transparent or translucent material, the stainless plate 30 may be assembled on the rear side in addition to the front side of the support plate 40, and the support plate 40 may be inserted into and fixed to the support plate 40.

The decorative panel manufactured by the method described above is transmitted from the stainless steel plate 30 by the surface texture of the stainless steel plate 30 according to the position and viewing direction of each cell 10 because the cells 10 have different properties. The expressive effect is different, and various productions are possible.

In addition, since the decorative panel may transmit light when acrylic plate or color glass is used instead of the stainless plate 30, the lighting panel may be used even in a dark place when the lighting device is provided between the acrylic plate or the color glass and the support plate. But it can double the expressive effect.

At this time, when the plate and the support plate 40 or the plate and the plate overlap by using a transparent or translucent material, the brightness of the illumination can be adjusted.

In addition, the decorative panel is preferably provided with a hook member on the back of the support plate 40 so as to hang on the wall surface.

Hereinafter, the operation of the method of manufacturing a decorative panel according to an embodiment of the present invention will be described with reference to the accompanying drawings.

First, as shown in FIG. 2, the operator designs a content to be expressed and performs a design step S10 of creating a design 5 using computer software.

In the drawing (5) will be described by using a stainless plate 30 to represent the buildings of the city, and by forming the upper surface of the support plate 40 using a luminous material so that the windows of the building shines colored. .

The design 5 not only expresses the detailed contents by using the computer software but also enables the sophisticated work in the subsequent work.

As shown in FIG. 3, the operator coordinates each vertex in the drawn drawing 5 and connects the vertices to divide the plurality of cells into a plurality of cells 10.

The design 5 enables computer work by coordinates of the vertices, and the cell 10 can be divided into the dimensions intended in the first design 5 so that the work can be precisely performed.

In the cell classification step S20, attributes corresponding to each of the divided cells 10 are individually assigned.

In addition, since there may be cells 10 to be surface-treated separately among the cells 10 having the same property, it is also good to number each cell 10.

For example, in the cell classification step S20, when a texture should be formed in the horizontal direction with the support plate 40, each of the cells 10 having the same property is given a '↔' mark, and the support plate 40 and In the case of forming a texture in the vertical direction, '10' marks are given to the cells 10 having the same property.

In addition, when it is necessary to form a grain pattern in a diagonal direction with the support plate 40, the '10' or '속성' mark is given to the cells 10 having the same property.

In addition, when the surface of the cell 10 needs to be processed separately or other materials other than the stainless plate 30, 'pa-yu' (blue glass), 'no-ah' (yellow acrylic), 'copper-part' It is also good to give an attribute by using an expression method such as (copper corrosion).

As shown in FIG. 4, in the arranging step S30, the cells 10 having the same property are divided into layers 20 to form and classify the layers 20.

Only one cell 10 having one property is classified in one layer 30, and each cell 10 is arranged to move or rotate to match the grain direction of the stainless plate 30.

For example, in the case of the layer 20 in which the cells 10 having the '↔' marks are gathered, the grain direction to be expressed in the cell 10 and the grain direction of the stainless plate 30 are rotated to be horizontal.

In addition, in the case of the layer 20 in which the cells 10 assigned with the '↕' are gathered, the grain direction to be expressed in the cell 10 and the grain direction of the stainless plate 30 are rotated to be perpendicular.

Then, each cell 10 is moved at regular intervals to minimize the margin, thereby reducing the requirement of the stainless plate 30.

At this time, in the arrangement step (S30), the margins are minimized when the cell 10 is arranged, but when the cell 10 is cut in the cutting step (S40), the cells 10 are damaged so as not to be damaged or interfere with the work. It is desirable to space apart enough.

As described above, the cells 10 of each layer 20 are moved or rotated so that the grain pattern of the stainless plate 30 and the grain direction of the surface of the cell 10 to be expressed coincide with each other.

5 to 6, in the cutting step S40, a computer cutting device 50 is used to precisely cut each cell 10.

Since the computer cutting device 50 needs a digitalized value, each layer 20 needs to be inputted with data to be converted into computer code (S42).

Of course, each layer 20 may be added to make a separate layer 20 to correspond to the state of the material of the plate for efficiency and then converted to fit the computer cutting device 50.

At this time, when using the software associated with the computer cutting device 50 from the design step (S10) through the cell sorting step (S20), the arrangement step (S30) is automatically converted into a computer code, so you can enter data separately no need.

In the step S44 of processing the surface, the surface of the stainless plate 30 is processed to correspond to an attribute other than the directionality of the texture.

In the step S44 of processing the surface, if the layer 20 is required to be coated, the cells 10 are coated separately through a coating process, and a texture having a more severe curvature than the texture unique to the stainless plate 30 is required. If you add sanding.

In addition, in the step S44 of processing the surface is subjected to a variety of processes according to the properties given to the cell 10, if it is difficult to represent the stainless plate 30 may be replaced with another kind of material.

In the cutting step S40, when the input of data is completed, the computer cutting device 50 passes the step S46 of cutting the stainless plate 30 in the shape of the cell 10 for each layer 20.

The computer cutting device 50 cuts the stainless steel plate 30 in the shape of the cell 10 as the laser beam 52 flows up, down, left, and right and cuts the fine parts. When assembled to 40, the seam is smoothed to give a better appearance.

In addition, the computer cutting device 50 reduces the error, thereby reducing the use of unnecessary stainless steel plate 30 to reduce the material cost, and prevents the case that it is impossible to assemble because the size between the stainless steel plate 30 does not match each other, Avoid unnecessary reprocessing

By using a computer from the drawing step S10 to the cutting step S40, a plurality of identical panels can be manufactured in one drawing 5, and detailed and sophisticated work can be performed as well as material cost reduction and automation. Mass production is also possible.

As shown in FIG. 7, in the assembling step S50, the stainless plate 30 cut through the cutting step S40 is assembled to the support plate 40.

The stainless plate 30 is fixed to the support plate 40 using an adhesive in accordance with the first draft 5.

Of course, the stainless plate 30 may be fixed by using an adhesive such as silicone or epoxy, and may be fixed by screwing, nailing, welding, or the like.

Preferably, the shim member 60 may be inserted into and fixed to the stainless plate 30 and the support plate 40 to be detachably provided with the fitting groove 12 and the insertion groove 42, respectively.

In particular, when using a material heavier than the stainless steel plate 30, it is preferable to assemble to the support plate 40 by the above-described method for solid assembly.

In addition, by using the stainless steel plate 30 superimposed, the expression effect excellent in three-dimensional effect can be produced.

In addition, when using a plate of a transparent or translucent material instead of the stainless plate 30, the plate placed in the rear may be substituted for the support plate 40.

In addition, in order to cover the assembly line between the stainless plate 30 and the support plate 40, it is preferable to have a frame around the support plate 40 or to install a molding to enhance the appearance.

Assembly step (S50) can also be automated with a device that can be assembled automatically, such as design step (S10) to cutting step (S40).

The decorative panel manufactured by the above-described method can produce a variety of expression effects because the reflection angle or degree of light is changed by the texture of the stainless plate 30 according to the viewing angle can be a work of art, indoors, It can be used universally in various places by decorating the exterior space to make the exterior beautiful.

In addition, the texture of the support plate 40 is expressed through the window formed through the stainless plate 30.

Therefore, color glass may be attached to the portion of the support plate 40 without painting, so that the paint plate may have a different effect from the painting.

At this time, when the glass is attached to the support plate 40, since the thickness is different from the stainless plate 30, it is preferable to insert a supplement to the bottom of the stainless plate 30 to match the thickness with the color glass.

Here, when the lighting device is installed in the lower part of the glass attached to the glass, the color of the glass is further deepened by the lighting, and the visibility is excellent, thereby not only increasing the expression effect but also decorating in a dark place.

In addition, the decorative panel is preferably covered with a transparent material such as glass in order to protect the stainless plate (30).

In addition, the decorative panel can convey the feeling of painting and sculpture at the same time, can emphasize the feeling of painting using a flat material, or can emphasize the feeling of sculpture using a three-dimensional material protruding from the support plate.

The decorative panel may be embedded in the wall, and may also function as an interior interior wall of the building, and may be provided in plural to decorate the surface of the three-dimensional sculpture by being installed in three dimensions.

The decorative panel may be decorated by directly attaching the stainless plate 30 to the interior, exterior walls, furniture, and various objects without the support plate 40.

Hereinafter, with reference to the accompanying drawings will be described another embodiment of the manufacturing method of the decorative panel according to the present invention.

10 is a flow chart of a method for manufacturing a decorative panel according to another embodiment of the present invention.

As shown in Figure 10, the manufacturing method of the decorative panel according to another embodiment of the present invention is a design step (S110), cell sorting step (S120), arrangement step (S130), cutting step (S140) and assembly step ( S150) is large.

Design step (S110), cell sorting step (S120), assembling step (S150) is similar to the manufacturing method of the decorative panel in one embodiment, so a detailed description thereof will be omitted.

11 is a view showing the arrangement step (S130) in the method of manufacturing a decorative panel according to another embodiment of the present invention.

As shown in FIG. 11, the arranging step S130 is not provided with a plurality of layers 20, unlike the arranging step S30 in one embodiment, and the properties of the cell 110 and the stainless plate 130 are shown. Each cell 110 is moved or rotated so that the grain directions coincide with each other and arranged in one layer 120.

In the arranging step S130, all the cells 110 may be arranged in one layer 120.

In the arranging step S130, after arranging the large cells 110 among the cells 110 in a line, the small cells 110 are arranged between the large cells 110 to minimize the margin of the layer 120. .

At this time, in the arranging step (S130), the margins are minimized when the cell 110 is arranged, but when the cell 110 is cut in the cutting step (S140), the cell 110 is damaged so that the cell 110 is not damaged or interfered with the work. It is desirable to space apart enough.

Alternatively, the large cells 10 may be arranged in groups of the large cells 10 and the small cells 10 in groups of the small cells 10.

In addition, in the case where processing such as painting or corrosion is required for a separate surface effect after the cutting step (S146), when the cells 110 are collected and arranged in one place in the layer 120 according to each direction, the work efficiency is improved. Is increased.

At this time, when the property of the cell 110 is the vertical direction, the cell 110 is arranged to match the grain direction of the stainless plate 130, and if the property of the cell 110 is the horizontal direction, the stainless plate 130 Rotate the cell 110 to match the grain direction.

Minimize the margin by arranging all cells 110 in one layer 120, and only one stainless plate 130 is required, thereby reducing the requirement of the stainless plate 130 to be cut, and also reducing the working time. You can do it.

12 is a flow chart of the cutting step (S140) in the method of manufacturing a decorative panel according to another embodiment of the present invention.

As shown in FIG. 12, the cutting step (S140) is a step of inputting data by converting the layer 120 into a computer code (S142), and dyeing and painting to highlight the surface effect of the stainless plate 130. To process the surface by at least one of coating, corrosion, scratching or sanding (S144), and cutting the stainless plate 130 in the shape of the cell 110 by the data input to the computer (S146).

13 is a view showing a step (S146) for cutting in the manufacturing method of the decorative panel according to another embodiment of the present invention.

As shown in FIG. 13, since only the stainless plate 130 corresponding to one layer 120 is cut in the cutting step S146, the cutting step of the exemplary embodiment in which the plurality of stainless plate 130 is to be replaced while being cut. Compared to S40, the working time can be shortened and productivity can be improved.

Hereinafter, the operation of the method for manufacturing a decorative panel according to another embodiment of the present invention will be described with reference to the accompanying drawings.

Since the design step (S110) and the cell classification step (S120) are similar to those described above in an embodiment of the present invention, a detailed description thereof will be omitted.

The cells 110 divided through the cell classification step S120 as described in the drawing step S110 are arranged in one layer 120 in the arranging step S130.

As shown in FIG. 11, the arranging step S130 assumes that the grain direction of the stainless plate 130 is horizontal, and arranges one layer 120 to match the stainless plate 130 to be cut.

In addition, in the arranging step S130, each cell 110 is rotated and arranged according to the attributes individually given to the arranged layers 120.

In the arrangement step S130, the large cells 110 are preferentially arranged when the cells 110 are arranged, and then the small cells 110 are arranged between the large cells 110 to minimize the layer 120 margin. .

For example, the cells 110 to which '↔' is given are arranged in the layer 120 without rotation when the grain direction of the stainless plate 130 is horizontal.

In addition, the cells 110 to which the mark '↕' is assigned are arranged in the layer 120 by rotating 90 degrees when the grain direction of the stainless plate 130 becomes horizontal.

As described above, each of the cells 110 is rotated and arranged in the layer 120 so that the grain pattern and the grain direction of the stainless plate 130 are matched.

As shown in FIG. 12, in the cutting step S140, the stainless plate 130 is cut in the shape of the cells 110 arranged in one layer 120.

Cutting step (S140) is a step of inputting data by converting the layer 120 into a computer code (S142), and staining, painting, coating, corrosion, scratching or sanding to highlight the surface effect of the stainless plate 130 The surface is processed to at least one of the steps (S144) and the step of cutting the stainless plate 130 in the shape of the cell 110 by the data input to the computer (S146).

At this time, since the cells 110 are arranged in one layer 120 by mixing a large and a small one, the margin is minimized and the portion cut away from the stainless plate 130 is reduced, thereby reducing the requirement of the stainless plate 130. Material cost can be reduced.

In the assembling step (S150), as shown in FIG. 9, the stainless plate 130 is assembled to the support plate 140 by inserting the core member 60 into the fitting groove 12 and the insertion groove 42. To finish the work.

As described above, the method of manufacturing a decorative panel according to one embodiment of the present invention and other embodiments can be a detailed design by a computer operation, can be precisely cut to reduce the material cost as well as one It is possible to manufacture a plurality of the same panel by the design, it is possible to mass-produce a large number of panels in a short time can be automated to improve productivity.

In addition, the present invention can apply a plurality of materials to a single panel, and because the expression effect of the panel is changed according to the surrounding environment or viewing angle, it is possible to produce a variety of expression effects, such as in the art world, interior industry, exterior industry, It can be used universally regardless of the external space.

The present invention can be manufactured in an environmentally friendly manner by superimposing an image with the surrounding environment using a material reflected by the surrounding environment.

In addition, the present invention can convey the feeling of painting and sculpture at the same time, it is possible to emphasize the feeling of painting using a planar material, or to emphasize the feeling of sculpture using a three-dimensional material protruding.

Although the present invention has been described with reference to the embodiments illustrated in the drawings, it is merely exemplary, and various modifications and equivalent other embodiments are possible from those skilled in the art. I will understand. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

1 is a flow chart of a method of manufacturing a decorative panel according to an embodiment of the present invention.

2 is a view showing a design step in the method of manufacturing a decorative panel according to an embodiment of the present invention.

3 is a diagram illustrating a cell classification step in the method of manufacturing a decorative panel according to an embodiment of the present invention.

4 is a view showing an arrangement step in the method of manufacturing a decorative panel according to an embodiment of the present invention.

Figure 5 is a flow chart of the cutting step in the manufacturing method of the decorative panel according to an embodiment of the present invention.

6 is a view showing a step of cutting in the manufacturing method of the decorative panel according to an embodiment of the present invention.

7 is a view showing an assembling step in the method of manufacturing a decorative panel according to an embodiment of the present invention.

8 is a view showing a decorative panel manufactured by the method for manufacturing a decorative panel according to an embodiment of the present invention.

9 is a cross-sectional view of FIG. 8.

10 is a flow chart of a method for manufacturing a decorative panel according to another embodiment of the present invention.

11 is a diagram illustrating an arrangement step in a method of manufacturing a decorative panel according to another embodiment of the present invention.

12 is a flowchart of a cutting step in the method of manufacturing a decorative panel according to another embodiment of the present invention.

13 is a view showing a step of cutting in the manufacturing method of the decorative panel according to another embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

S10: design step S20: cell classification step

S30: arrangement step S40: cutting step

S50: assembly step S110: design step

S120: Cell classification step S130: Array step

S140: Cutting Step S150: Assembly Step

Claims (10)

A drawing step of creating a drawing; A cell classification step of dividing the pattern into a plurality of cells and individually assigning attributes corresponding to the cells; Arranging the same attributes among the cells by layer, and moving or rotating the cells of the layer so that the attributes of the cells and the grain direction of the sheet match; A cutting step of cutting the plate into the cell shape arranged in the layer; And Method of manufacturing a decorative panel, characterized in that it comprises an assembly step of assembling the plate to the support plate as the pattern. The method of claim 1, The cutting may include converting the layer into computer code and inputting data; Machining the surface of the plate with at least one of dyeing, painting, coating, corrosion, scratching or sanding to highlight the surface effect individually according to the properties imparted to the cell; And And cutting the plate into the cell shape by the data input to the computer. The method of claim 1, The support plate is a method of manufacturing a decorative panel, characterized in that the surface is processed by at least one of dyeing, painting, coating, corrosion, scratching or sanding. The method of claim 1, The plate material is a method of manufacturing a decorative panel, characterized in that assembled to at least one of an adhesive, screwing, welding or nail to the support plate. delete The method according to claim 1 or 2, The plate is provided with a fitting groove on the bottom surface, and the support plate is provided with an insertion groove so as to be symmetrical to the fitting groove of the plate to insert the core member in the fitting groove and the insertion groove at the same time to fix the plate to the support plate The manufacturing method of the decorative panel characterized by the above-mentioned. A drawing step of creating a drawing; A cell classification step of dividing the pattern into a plurality of cells and individually assigning attributes corresponding to the cells; Arranging the cells in a single layer by moving or rotating the cells so that the properties of the cells coincide with the grain direction of the sheet; A cutting step of cutting the plate into the cell shape arranged in the layer; And Method of manufacturing a decorative panel, characterized in that it comprises an assembly step of assembling the plate to the support plate as the pattern. The method of claim 7, wherein The cutting may include converting the layer into computer code and inputting data; Machining the surface of the plate with at least one of dyeing, painting, coating, corrosion, scratching or sanding to highlight the surface effect individually according to the properties imparted to the cell; And And cutting the plate into the cell shape by data input to the computer. delete 9. The method according to claim 7 or 8, The plate is provided with a fitting groove on the bottom surface, and the support plate is provided with an insertion groove so as to be symmetrical to the fitting groove of the plate to insert the core member in the fitting groove and the insertion groove at the same time to fix the plate to the support plate The manufacturing method of the decorative panel characterized by the above-mentioned.

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