JPH11295505A - Image printing system for wall material, wall surface decoration method, wall material and recording medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image printing system for a wall material for printing images viewed like moving at the time of viewing them through a lenticular lens on the surface of a tile or the like. SOLUTION: A control circuit 5 selects image data to be an original image based on signals inputted from an input part 1. Also, the control circuit 5 inputs the size of a tile to be a printing object. The control circuit 5 inputs the number of the tiles to be the constituting elements of a wall image for expressing the original image from the input part 1 and the control circuit 5 inputs a printing range in the original image from the input part 1. Then, the control circuit 5 prints the image to be the printing object on the surface of the tile by controlling a tile printer 8 or the like based on the input processings. In this case, the control circuit 5 prints the image viewed like moving or the images viewed stereoscopically through a lenticular lens on the surface of the tile.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wall material on which an image which is switched when viewed through a lenticular lens is printed, an image printing system for a wall material capable of producing the wall material, and a wall decoration method. And a recording medium.

[0002]

2. Description of the Related Art A tile is used as a building wall material which is stretched on a wall or a floor. Generally, colors or images are formed on the surface of the tile.

[0003] As a method of producing a tile on which a color drawing is performed, there is a method in which a liquid pigment is jetted onto the surface of a tile material, fired, and then the surface of the formed tile is polished to finish. A method for forming a clear and precise image on the surface of a tile is disclosed in JP-A-7-12550.
No. 0 or JP-A-7-330473.

[0004]

However, in the conventional method for producing tiles, there is a problem that a planar still image can only be formed on the tile surface and lacks interest.

[0005] In addition, if a moving image can be expressed on a tile, a tile wall or the like that is more enjoyable and has a higher taste can be obtained. However, conventionally, in order to display a moving image, it is necessary to incorporate a complicated and expensive display device separately from the tile on the wall surface, so that the price of the entire wall increases and the installation space of the display device is required.

Conventionally, when some tiles on a tile wall or the like are damaged, there has been a problem that a great deal of labor and cost are required to precisely reproduce only the damaged tiles.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has an image printing system for a wall material capable of producing an interesting building wall material (including a floor material and a ceiling material) such as a tile. It is an object to provide a decoration method and a recording medium.

Further, the present invention provides a wall in which, when a part of a building wall material (such as a tile) in a building wall such as a tile wall is damaged, a part of the building wall material can be easily reproduced. It is an object of the present invention to provide a material image printing system, a wall decoration method, and a recording medium. Another object of the present invention is to provide an architectural wall material such as a tile capable of forming an interesting mural.

[0009]

In order to achieve the above object, an image printing system for a wall material according to a first aspect of the present invention comprises: an original image storing means for storing a plurality of original images for wall decoration; Image processing means for processing the original image stored in the storage means into an image in which a part of each of the plurality of original images is switched when viewed through a lenticular lens; and converting the image processed by the image processing means into an architectural wall. And printing means for printing on the material.

The printing unit enlarges or reduces the image by a method such as an error diffusion method according to the size of the wall material so that the divided image is printed on the entire surface of each wall material.

According to such a configuration, there is provided an image printing system for a wall material capable of forming an architectural wall material on which an image which is switched or moved is formed from a plurality of positions through the lenticular lens. be able to. The original image may be stored in advance, or
It may be input as needed.

The image processing means includes a wall material information input means for inputting a size and / or a shape of the building wall material and the number of building wall materials to be printed or a size of a mural, and the wall material information input means. And the shape and size of the building wall material
Division position calculation means for calculating a division position of an image based on the number of the building wall materials or the size of the mural, and the resolution and aspect ratio of the original image, and dividing the image at the position calculated by the division position calculation means And a print position input unit for inputting the division position where printing is performed. With this configuration, it is easy to divide an image and print only an arbitrary divided image.

[0013] The printing means may include means for causing a code indicating the position of each image divided by the image dividing means to be included in an image to be printed. Images viewed through a lenticular lens cannot usually be recognized as such. For this reason, it is not possible to immediately recognize at which position on the wall the architectural wall material on which the image is printed is to be arranged. Thus, by assigning a code indicating the position of each image, the position can be easily recognized.
This code may be a normal character / number, bar code, two-dimensional code, or the like, or may be an image that can be recognized only when viewed from a specific angle through a lenticular lens. With such a configuration, when a building wall material such as a tile is damaged, it is possible to immediately cope with the reproduction of the damaged wall material.

[0014] For example, the identification information of the plurality of original images to be printed, the size of the wall material, and the number of the wall materials or the size of the mural are added to an identification code to record the print information. Print information recording means, and means for including the identification code in an image to be printed.

The print information and the identification code are associated with each other and recorded in a print information recording means such as a database, and the identification code is printed on a building wall material. By retrieving print information with this identification code, the original image and print conditions can be determined, and the building wall material can be easily reproduced. The identification code may be a normal character / number, a bar code, a two-dimensional code, or the like, or may be an image that can be recognized only when viewed from a specific angle through a lenticular lens.

[0016] For example, the wall material information input means may be one of a shape and a size of the building wall material forming a wall surface on which an image processed by the image processing means is printed and one of a horizontal direction and a vertical direction. The number of wall materials is input, and the division position calculation unit is configured to execute the other of the building wall materials in the horizontal direction or the vertical direction of the wall surface to be printed based on the information input by the wall material information input unit. And a means for calculating the number of images and the division position of the image. According to this configuration, the image can be easily divided.

After the entire mural is synthesized, a portion corresponding to each wall may be cut out and printed on each architectural wall, or a part corresponding to a target wall may be selected from a plurality of original drawings. A portion to be cut may be cut out, synthesized for a lenticular lens, and printed. That is, the procedure for synthesizing the image to be printed on each wall material is arbitrary.

A method of decorating a wall according to a second aspect of the present invention is a method of decorating a wall formed by combining a plurality of wall materials on which an image is printed and on which a lenticular lens is disposed. When viewed through a lenticular lens on each wall material, an image that is switched according to the viewing angle, and is formed by combining images displayed on a plurality of wall materials to form one significant image Images are arranged. According to this method, it is possible to create a building wall material on which an image that appears to move when viewed from a plurality of positions through the lenticular lens is formed.

Further, a wall material according to a third aspect of the present invention is a wall material formed by combining a plurality of wall materials each having an image and a lenticular lens disposed on the surface, and each wall material has When viewed through a lenticular lens, an image that is switched according to the viewing angle and a lenticular lens are arranged, and on each wall material, an image that is combined to form a significant image is arranged.
It is characterized by the following.

When the building wall material having such a configuration is viewed from a plurality of positions, an image on the surface of the building wall material such as the tile appears to move. Therefore, if a mural or the like is constructed by using a building wall material having such a configuration, a fun and highly interesting mural or the like can be obtained.

A recording medium according to a fourth aspect of the present invention comprises:
A computer, an original image storage unit that stores a plurality of original images for wall decoration, an image processing unit that processes the original image stored in the original image storage unit into an image in which the plurality of original images are switched when viewed through a lenticular lens,
An output unit for outputting the image processed by the image processing unit for printing on a building wall material, which can be read by a computer that stores a program for functioning as an output unit.

By executing the program stored in such a recording medium by a computer connected to the printing means for building wall material, a building wall material on which an image as a moving image is printed using a lenticular lens is created. can do. In addition, an image previously captured by a digital camera or the like can be input to a computer and printed on a building wall material as an image that can be viewed as a moving image.

[0023]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An image printing system for a wall material according to an embodiment of the present invention will be described below with reference to the drawings.

The image printing system for a wall material according to the present invention is shown in FIG.
As shown in the figure, the input unit 1, the image input unit 2, the image memory 4, the control circuit 5, the display unit 6, and the frame memory 7
And a tile printer 8.

The input unit 1 inputs various instructions and data.

The image input unit 2 inputs image data for printing on building wall materials such as tiles and supplies the image data to the control circuit 5.

The image memory 4 stores the image data input from the image input unit 2 separately for each of the Y, M, and C color components and functions as a work area for the control circuit 5.

The control circuit 5 comprises an MPU (microprocessor unit), a DSP (digital signal processor), etc., operates according to a predetermined program, and executes image input processing, image synthesis processing, print control, etc., which will be described later. The details of the control operation performed by the control circuit 5 will be described later.

The display unit 6 is composed of a CRT, a liquid crystal display element and the like, and displays a menu screen, an image input by the image input unit 2 and the like under the control of the control circuit 5.

The frame memory 7 stores Y, M, and C of one image printed on the surface of the plurality of tiles 11 shown in FIG.
Are stored. In FIG. 2, one image is printed on the surface of 5 tiles = 5 vertical = 25 tiles 11.

The tile printer 8 prints an image developed in the frame memory 7 under the control of the control circuit 5.

The tile printer 8 includes, for example, a means for electrically neutralizing the surface of the unfired tile, and a means for injecting a liquid pigment comprising an aqueous metal ion solution onto the surface of the neutralized tile by an ink jet nozzle. , Is provided. When the tile 11 is baked after the liquid pigment ejected from the tile printer 8 permeates the tile 11, the pigment develops color and an image emerges.

Next, the operation of the image printing system for a wall material having the above configuration will be described with reference to FIGS.

The creator of the wall operates the input unit 1 to instruct an original image selection process for selecting an original image to be printed on the surface of the tile 11. In response to this instruction, the control circuit 5
A list of a plurality of image data stored in the image memory 4 is displayed. The wall creator selects a plurality of image data (original images) to be printed from the displayed list (step S1). The resolution and aspect ratio of the original image are arbitrary.

Next, the input section 1 is operated to input the shape and size of the tile 11 to be printed (step S).
2). Further, the image (original image) of the image data selected by the original image selection button is divided as shown in FIG. 2 and the number of tiles 11 to be printed is designated in order to display each tile 11 ( Step S3). Control circuit 5
Saves the input shape and size of the tile 11 and the number of tiles 11.

The control circuit 5 calculates the number of tiles 11 in the vertical direction (or the number of tiles in the horizontal direction) from the number of tiles 11 in the horizontal direction (or the number of tiles in the vertical direction), for example, using Equation 1. You may.

[0037]

[Number 1] _{Tn h = h1 / ((w1} / Tn w) * (T h / T w)) here, w1, the number of pixels in the horizontal direction of the original image, h1, the number of pixels in the vertical direction of the original image, T _w is the lateral length of the tile 11, T _h is the vertical length of the tiles 11, Tn _w is transverse the number of tiles 11 to be used to represent the original image, Tn _h
Is the number of tiles 11 used to represent the original image in the vertical direction.

For example, if the number of pixels in the horizontal direction of the original image is 64,
0, the number of pixels in the vertical direction is 480, the size of the tile 11 is 20 cm in width × 15 cm in height, and the number of tiles in the horizontal direction is 5, the number of tiles in the vertical direction (Tn _h ) is Tnh = 4
80 / ((640/5) * (15/20)) = (4 /
3) * 5 * (3/4) = 5 sheets.

Instead of inputting the number of tiles 11, the size of a mural composed of a plurality of tiles 11 as shown in FIG. 2 may be input. In this case, the size of the mural is divided by the size of the tile 11, and the tile 1
The required number of sheets can be calculated.

As shown in FIG. 2, the control circuit 5 combines the original image displayed on the display unit 6 with the tile image and displays it.

Thereafter, a range to be printed is designated from the input unit 1 (step S4). For example, as shown in FIG. 2, the entirety of the original image data is tile codes (X1, Y
25 tiles 1 of tile codes (X5, Y5) from 1)
Assuming that the image is printed on the surface of No. 1, for example, when printing the entire original image, the tile codes (X1, Y1) to (X5, Y5) are designated as the print range. Also, the tile code (X2, Y
2) To print only the ranges of (X3, Y2) and (X4, Y2), specify those tile codes.

Thereafter, the control circuit 5 sends the image data to be printed on each tile 11 to be printed to the frame memory 7 for each of the plurality of original images based on the processing from step S1 to step S4, Are combined (step S5) and printed on the tile 11 (step S6).

The operation of synthesizing and printing the image to be printed will be described.

For example, as shown in FIG. 4, if the coordinates (x, y) of the origin (upper left corner) of the original image are (0, 0), the tile 11 of the tile code (r, c) is: Coordinates ((c-1) * w1 / Tnw, (r-1) * h1 / Tn
h) and coordinates ((c * w1 / Tnw-1, r * h1 / T
nh-1) is a print target image of one tile 11. Here, w1 is the number of pixels of the original image in the horizontal direction, h1 is the number of pixels of the original image in the vertical direction, Tnw
Is the number of tiles 11 used to display the original image (entire) in the horizontal direction, and Tnh is the number of tiles 11 used to display the original image (entire) in the vertical direction.

For example, the tile 11 to be printed is a tile code (2, 2), w1 is 640, h1 is 480,
Assuming that Tnw and Tnh are 5, the coordinates ((2-1) * 6
40/5, (2-1) * 480/5) = (128,9
6) and coordinates ((2 * 640/5, 2 * 480/5) =
(256, 192), and the pixels in the rectangular area indicated by oblique lines in FIG. 4 are to be printed.

The control circuit 5 calculates the area to be printed in the original image as described above, and appropriately enlarges or reduces the image of the area according to the actual size of the tile 11. Then, as shown in FIG. 5, the control circuit 5 slits the enlarged or reduced image according to the characteristics of the lenticular lens 12 attached to the surface of each tile 11 and prints it on the surface of the tile 11 by slitting the image. 13 is drawn.

Here, the moving image using the lenticular lens 12 is an image of each frame constituting the moving image, for example, FIG.
The original images shown in FIGS. 6A to 6C are formed by cutting out the original images into stripes as shown in FIGS. 6D to 6F and arranging them regularly as shown in FIG. You.

Details of the moving image creation processing will be described with reference to FIGS. 7, 8, and 9. As shown in FIG. 7, the image memory 4 includes a set of image data Y1, M1, and C1 of Y, M, and C components of the print target portion of the first original image, and Y, M1, and C1 of the second original image.
It is assumed that a set of image data Y2, M2, and C2 of the M and C components and a set of image data Y3, M3, and C3 of the Y, M, and C components of the third original image are stored.

First, the control circuit 5 sets an initial value 1 to a pointer i indicating a stripe number cut out from the original images Y1 to Y3 in order to create a moving image of the Y color component. Further, an image creation area for the moving image Ya of the Y component is secured in the image memory 4 (FIG. 8, step S21).

The control circuit 5 calculates the i-th striped image Y1 from the image data Y1 stored in the image memory 4.
i is cut out (step S22). This stripe Y1
As shown in FIG. 9A, i is composed of pixels in an area where the X-axis coordinate of the image data Y1 is (inb) to (in) and the Y-axis coordinate is 0 to K. Image to be displayed.

Here, n is the number of pixels corresponding to the diameter of the cylindrical lens of the lenticular lens. If the diameter of the lenticular lens is D inches and the resolution of the image is d dots / inch, it is expressed by D · d. . B is b ≦ n / 3
Which is equivalent to the width of the striped image.
K indicates the size (the number of dots) of the image in the Y-axis direction.

As shown in FIG. 9B, the control circuit 5 converts the striped image into ((i-1) .n + (x) in the X-axis direction of the image Ya formation area on the image memory 4. n
−3 · b) / 6) to ((i−1) · n + (n−3 ·)
b) / 6 + b), that is, from ((n−3b) / 6) to ((n + 3b) / 6), is written (developed) in the area from 0 to K in the Y-axis direction (step S23).

Next, the control circuit 5 cuts out the i-th striped image Y2i from the image data Y2 stored in the image memory 4 (step S24). The cutout position is relatively the same as the cutout position of the i-th stripe of the image Y1, and as shown in FIG. 9A, the X-axis coordinate of the image data Y2 is changed from (in-b) to (in-b). i · n), where the Y-axis coordinates are from 0 to K.

The control circuit 5 determines that the X-axis coordinate in the image Ya formation area is ((i−i)
1) · n + (n−3 · b) / 6 + b + (n−3 · b) /
3) to ((i-1) .n + (n-3.b) / 6 + b +
(N−3 · b) / 3 + b), that is, ((n−b) /
From 2) to ((n + b) / 2), the Y-axis coordinate is 0 to K
(Step S25).

Next, the control circuit 5 controls the i-th striped image Y of the image data Y3 stored in the image memory 4.
3i is cut out (step S26). The cutout position is
It is relatively the same as the cutout position of the i-th striped image of the images Y1 and Y2, and as shown in FIG. 9A, the X-axis coordinate of the image data Y3 is changed from (i-n-b) to (in-b). i · n), where the Y-axis coordinates are from 0 to K.

The control circuit 5 determines that the X-axis coordinate of the image Ya formation area is ((i · n)
− (N−3−b) / 6−b) to ((i−n− (n−3)
Write from b) / 6), that is, from ((5n−3b) / 6) to ((5n + 3b) / 6), in the area where the Y-axis coordinate is from 0 to K (step S27).

Next, the control circuit 5 determines that the value of the pointer i is
It is determined whether or not a predetermined number N of times of striping the striped image of each image has been reached (step S2).
8). If it is determined that the value has not reached, the pointer i is set to 1
Is added (step S29), the process returns to step S22, and the operation of cutting out the next stripe-shaped image from the images Y1, Y2, and Y3 and writing the image in the image creation area is repeated (steps S22 to S28).

When the operation of cutting out and writing the stripe image is repeated N times, an image in which the stripe images of the images Y1 to Y3 are sequentially arranged in the image forming area as shown in FIG. 9B is completed. In step S28, it is determined that the value of the pointer i has reached the reference value N, and the flow is as follows:
Proceed to step S30.

In step S30, the image M1 of the M color component
The same image processing is performed for M3 to M3 to create a moving image Ma of the M color component. Regarding the cutout position of the image from the images M1 to M3 and the write position to the image Ma,
This is the same as the processing for Y1 to Y3 and Ya.

When the moving image Ma of the M color component is completed, the control circuit 5 performs the same image processing on the images C1 to C3 of the C color component to create the moving image Ca of the C color component (step S31). When the moving image Ca of the C color component is completed, the moving image creation processing for one tile ends.

Ya, Ma, C created in the moving image creation process
Each image of a is sent to the frame memory 7 by the control circuit 5.

The control circuit 5 transmits the image data Ya to be printed stored in the frame memory 7 to the tile printer 8.
Are supplied sequentially. The tile printer 8 prints the image data Ya supplied from the frame memory 7 on the surface of the tile 11 using the Y liquid pigment.

When the printing of the image Ya is completed, the control circuit 5 supplies a print color switching control signal to the tile printer 8 and sequentially supplies the image data Ma to be printed stored in the frame memory 7 to the tile printer 8. I do. The tile printer 8 switches the liquid pigment used for printing to M in accordance with the print color switching control signal, and converts the image data Ma supplied from the control circuit 5 using the M liquid pigment onto the surface of the tile 11 already printed. Is printed over the image of Ya.

When the printing of the image Ma is completed, the control circuit 5 supplies a print color switching control signal to the tile printer 8 and sequentially supplies the image data Ca to be printed stored in the frame memory 7 to the tile printer 8. I do. The tile printer 8 switches the liquid pigment used for printing to C in accordance with the print color switching control signal, and converts the image data Ca supplied from the control circuit 5 onto the already printed tile 11 using the C liquid pigment. Printing is performed so as to overlap the images of Ya and Ma, and the printing process is completed.

As a result, the image printing system for a wall material can regularly arrange the striped images cut out from a plurality of original images and print them on the surface of the tile 11 as shown in FIG.

When the lenticular lens 12 is attached on the surface of the tile 11 as shown in FIG. 5, when the tile 11 is viewed from a plurality of positions, the image 13 on the surface of the tile 11 is viewed as a moving image. be able to.

Further, a mural as shown in FIG. 2 can be constructed by using a plurality of tiles 11 on which an image 13 is printed as shown in FIG. 5, and the mural can be viewed as a moving image. Therefore, the image printing system for a wall material can create a building wall material such as an interesting tile.

In addition, the image printing system for a wall material can specify only an arbitrary area of the entire original image and print only the specified area on the tile surface. Therefore, in a mural using a plurality of tiles, when some of the tiles are damaged or the like, only the damaged tiles can be easily reproduced.

The image printing system for a wall material can print an arbitrary original image captured by the image input unit 2 on a tile 11 of an arbitrary size, so that it is suitable for high-mix low-volume production of architectural wall materials. I have.

In the above embodiment, a portion to be printed on one tile 11 is cut out of each original image, and the cut out partial images are cut out into stripes and synthesized. First, the whole of the original image may be cut out in a stripe shape and synthesized, and then a portion to be printed on the tile 11 to be printed may be extracted and printed.

In this case, the control circuit 5 converts the original image with a width corresponding to the diameter of the lenticular lens 12 as described with reference to FIGS. By cutting out and arranging in a stripe shape, the entire print target (composite) image is created, and is developed in the frame memory 7 for each of Y, M, and C. Next, the input unit 1 inputs the size and number of tiles in the vertical and horizontal directions (or the vertical and horizontal sizes of the entire wall surface). The control circuit 5 enlarges or reduces the synthesized image so that the synthesized image is printed on the entire tile 11 (that is, the entire wall surface). Next, an image range (tile position) to be printed is designated, pixel data of a pixel corresponding to this position is read, supplied to the tile printer 8, and printed on the tile 11.

That is, according to the present invention, the original image may be divided into tile-size units, and the corresponding ones of the divided images may be combined for the lenticular lens 12 and printed. The original image (entire) may be synthesized for the lenticular lens 12, and then a portion corresponding to each tile 11 may be extracted and printed.

In the above-described embodiment, tiles are used as the building wall material of the printing object. However, the present invention is not limited to this. It may be.

The building wall material such as a tile or panel to be printed according to the present invention is made of porcelain and has excellent weather resistance, but a resin tile or panel for indoor use may be used as a printing target.

As shown in FIG. 2, the original image is divided into a plurality of
When each of the divided images is printed on the surface of the tile 11 to form a mural, a sign indicating the division position of each of the divided images is set to an angle that is not normally observed (for example, an angle close to the horizontal of the tile). ) May be included in each divided image and printed on the surface of each tile 11 as an image whose sign is visible only when viewed through the lenticular lens 12.

Similarly, an identification code is added to the print information such as the identification information of the original used in the synthesis, the size and shape of each tile, the number of wall materials, or the entire size of the mural, and the print information is stored in a database. And the like, and the identification code (image indicating) is printed on each tile 11.

According to this configuration, when one mural is constructed by using a plurality of tiles 11, if a part of the plurality of tiles 11 constituting the mural is flawed or damaged, the mural is damaged. Reading the identification code from the tile 11, searching the database from this identification code and reading the print information, determining the original image being printed and the printing conditions, and easily reproducing the tile 11; Maintenance of the mural can be facilitated.

Each code or identification code may be a number, a character, a symbol, or the like, or may be a bar code, a two-dimensional code, or the like.

The input unit 1 may be provided with, for example, a digital still camera, and can capture images.
Further, a communication connector or the like may be provided so that image data on a network can be taken in by communication or an image acquired by a digital still camera can be read.

[0080]

As described above, according to the present invention, it is possible to provide an architectural wall material in which an image appears to move when viewed through a lenticular lens, and to print such an architectural wall material. A system, a wall decoration method, and a recording medium can be provided.

[Brief description of the drawings]

FIG. 1 is a diagram showing an image printing system for a wall material according to an embodiment of the present invention.

FIG. 2 is a diagram illustrating an example of an image printed on a surface of a plurality of tiles.

FIG. 3 is a flowchart showing an operation of the image printing system for a wall material shown in FIG. 1;

FIG. 4 is a diagram illustrating an area to be printed in an original image.

5 is a diagram showing a state in which a lenticular lens is superimposed on a tile on which an image has been printed by the wall material image printing system shown in FIG.

FIG. 6 is a diagram for explaining image processing performed in the image printing system for a wall material shown in FIG. 1;

FIG. 7 is a diagram showing an image stored in an image memory.

FIG. 8 is a flowchart illustrating a process performed in the image printing system for a wall material illustrated in FIG. 1;

FIG. 9A is a diagram for printing an image to be a moving image.
FIG. 4 is a diagram for explaining a method of cutting out an original image.
(B) is a figure for explaining the pasting method of the cut-out striped image.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Input part 2 Image input part 4 Image memory 5 Control circuit 6 Display part 7 Frame memory 8 Tile printer 11 Tile 12 Lenticular lens 13 Image

Continued on the front page (51) Int.Cl. ⁶ Identification code FI G03B 35/00 G03B 35/00 A // C04B 41/86 C04B 41/86 N

Claims (8)

[Claims] 1. An original image storage means for storing a plurality of original images for wall decoration, and when an original image stored in the original image storage means is viewed through a lenticular lens, a partial image of each of the plurality of original images is switched. An image processing system for a wall material, comprising: an image processing unit that processes a visible image; and a printing unit that prints the image processed by the image processing unit on a building wall material. 2. The image processing means comprises: wall material information input means for inputting the size and / or shape of the building wall material and the number of building wall materials to be printed or the size of a mural; and the wall material information input means. The input and the shape and size of the building wall material, the number of the building wall material or the size of the mural,
Division position calculation means for calculating a division position of an image based on the resolution and aspect ratio of the original image; image division means for dividing an image at the position calculated by the division position calculation means; and the division position for printing The image printing system for a wall material according to claim 1, further comprising: a printing position input unit that inputs the image data. 3. The wall according to claim 2, wherein said printing means includes means for causing a code indicating a position of each image divided by said image dividing means to be included in an image to be printed. Material image printing system. 4. The printing information comprising the identification information of the plurality of original images to be printed, the size of the wall material, and the number of wall materials or the size of the mural, is attached with an identification code to record the printing information. The image printing system for a wall material according to claim 2, further comprising: a print information recording unit that performs printing; and a unit that includes the identification code in an image to be printed. 5. The building material input means comprises: a shape and a size of the building wall material forming a wall surface on which an image processed by the image processing means is printed; The number of wall materials is input, and the division position calculation unit is configured to execute the other of the building wall materials in the horizontal direction or the vertical direction of the wall surface to be printed based on the information input by the wall material information input unit. The image printing system for a wall material according to any one of claims 2 to 4, further comprising: means for calculating the number of images and a division position of the image. 6. A method of decorating a wall surface formed by combining a plurality of wall members having an image printed on a surface and a lenticular lens disposed thereon, wherein each wall member is passed through a lenticular lens. When viewed, it is an image that looks partly switched according to the viewing angle,
A wall decoration method, comprising: arranging partial images that form one significant image by combining images displayed on a plurality of wall materials. 7. A wall material formed by combining a plurality of wall materials each having an image and a lenticular lens disposed on a surface thereof, wherein each of the wall materials has a shape corresponding to a viewing angle when viewed through a lenticular lens. A decoration using a lenticular lens, characterized in that an image that looks partially switched and a lenticular lens are arranged, and an image that combines to form a significant image is arranged on each wall material. Decorated wall material. 8. An original image storage means for storing a plurality of original images for wall decoration, and when the original image stored in the original image storage means is viewed through a lenticular lens, a partial image of each of the plurality of original images is obtained. Image processing means for processing into an image that can be switched; output means for outputting the image processed by the image processing means for printing on a building wall material; .