JPH11131362A - Apparatus for processing pattern data of clothes and recording medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide both an apparatus for processing pattern data of clothes capable of automatically calculating the maximum number of superimposed fabrics in preparation of the clothes by utilizing various pattern data and readily judging whether or not the clothes can be sewed with an own sewing apparatus when information about the thickness for each fabric is obtained and a recording medium. SOLUTION: This apparatus for processing pattern data of clothes is capable of calculating the maximum number of superimposed fabrics when preparing the clothes based on the number of superimposed fabrics, the shape of a pattern for preparing the clothes, sewing information and a pattern data such as a triangular shape of a seam margin stored in a memory region 3C or 6C for conditions of the changed number of fabrics by CPU1, thereby automatically calculating the maximum number of superimposed fabrics in the preparation of the clothes by utilizing various pattern data and readily judging whether or not the clothes can be sewed with an own sewing apparatus when information about the thickness for each fabric is obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a clothing pattern data processing apparatus for processing pattern data such as a pattern shape, sewing information, and a seam allowance for fabricating clothing. The present invention relates to a clothing pattern data processing apparatus for calculating the number of sheets and a computer-readable recording medium storing a clothing pattern data processing program.

[0002]

2. Description of the Related Art Conventionally, in a pattern data processing apparatus for clothes of this type, first, for clothes to be produced, pattern data such as a pattern shape corresponding to a pattern, sewing information of cloth, and a square shape of a seam allowance are obtained. make,
Fabrication of clothes based on the created pattern data is widely used.

Hereinafter, pattern data of a conventional pattern data processing apparatus will be described in detail with reference to the drawings, taking a wrap tight skirt (hereinafter simply referred to as a skirt) as an example.

FIG. 13 is a schematic view showing a completed skirt of the related art, and FIG. 14 is an explanatory diagram for explaining a pattern shape and a part code which are one of the pattern data corresponding to the pattern of the skirt. . In FIG. 13, one end face of the skirt 50 that appears on the outside is
At the left front of the wearer, the hook is fixed to the cloth inside by a hook or a snap (not shown), and the other end face on the inside (not shown) is hooked or snapped by a hook (not shown) at a location other than the left front. It is fixed to the outer fabric.

In FIG. 14, a pattern shape corresponding to the pattern of the skirt 50 includes a right front skirt pattern 52,
Left front skirt pattern 54 and rear skirt pattern 5
6, a right front look pattern 58, a left front look pattern 60, and a rear look pattern 62, and the skirt 50 is manufactured by sewing these patterns. The part codes such as WL, SL, and D1A given to each pattern are as follows:
Shows the sewing position when each pattern is sewn. For example, a line connecting the part codes WL and SL of the left front skirt pattern 54 is sewn to a line connecting the part codes WL and SL of the rear skirt pattern 56. You. Here, for convenience, "W" of the part code "WL"
Means "waist" and "S" in part code "SL"
Means a skirt, and "D" in "D1A" means darts.

As described above, clothing is manufactured by sewing each pattern while adjusting the part codes.
Since the outline of the sewing line is not clear, it is necessary to clarify the outline. In view of this, a component point number, which is one of the pattern data, is assigned to the position where the region code is attached and the line segment connecting the region codes to each other to clarify the outline of the line to be sewn.

FIG. 15 is an explanatory diagram for explaining a conventional point number, and FIG. 16 is an explanatory diagram for explaining pattern data of a pattern shape including the point number. FIG.
5, the constituent point numbers are P points such as P0 and P1, N1
And three types of numbers, such as N points such as IP2 and I points such as IP2, are attached to predetermined positions of each pattern. The pattern data of the pattern shape is based on these constituent point numbers, and a set of an outer line along the outer shape of the pattern and an inner line inside the outer line is provided for each pattern in a state shown in FIG. It is stored in a storage area provided in the device. For example, the pattern data of the pattern shape of the right front skirt pattern 52 is composed of one outer line and two inner lines of an inner line 1 and an inner line 2 as shown in FIG.

[0008] The “BREAK” used here is
"CURVE" means a curved passing point, and "NOTCH" means a predetermined point located on a line connecting P point, N point and I point in order. Means the point.

Also, "BREAK" and "CURVE"
() At the end of the line indicates the position of the constituent point number. For example, (XP0, YP0) describes the position of the break point P0 based on the XY coordinate system. That is, the coordinate value of P0 is such that the X coordinate is XP
0, indicating that the Y coordinate is YP0.

[0010] Further, for example, P1 and LN1 described at the end of the "NOTCH" line, for example, described in the line of the point N1, indicate the position of the point N1 and are located at a distance LN1 from the point P1. This indicates that N1 exists.

Next, stitching information and stitch angle shape, which are one of the pattern data, will be described.

FIG. 17 is an explanatory view for explaining pattern data of conventional sewing information, and FIG. 18 is an explanatory view for explaining conventional sewing substitute angle pattern data.
FIG. 19 is an explanatory diagram for explaining a conventional sewing margin angle shape.

First, as shown in FIG. 17, the pattern data of the stitching information indicates the correspondence between the constituent point numbers and the part codes, and the corresponding state of each pattern is stored in the storage area of the apparatus. ing. For example, the position of the part code WM in the right front skirt pattern 52 (pattern name A) corresponds to the position of the constituent point number P0, and the position of the part code WFC corresponds to the position of the constituent point number P1.

Further, the pattern data of the sewing margin angle shape is as follows.
As shown in FIG. 18, for each pattern, the width of the seam allowance of the component point number and the type of square shape are stored in the storage area of the apparatus. For example, the lines from P0 to P8 in the right front skirt pattern 52 (pattern name A) indicate that they are located 1 cm (100 means 1 cm) inside from the end face of the pattern. Further, the angular shape of the angle P0 means the angular shape D in FIG.

Using the pattern data described above,
When fabrics of each pattern are sewn together to produce clothes, as shown in FIG. 20, seam allowances and darts processing portions at joints of the patterns appear, and these portions are further processed to finish the clothes. Was.

[0016]

However, in the above-mentioned pattern data processing apparatus, since the respective patterns are sewn many times, the number of overlapping fabrics to be sewn differs depending on the location of the clothes, and the thick fabric is used in a portion where the number of overlapping fabrics is large. When used, there is a problem that sewing cannot be performed depending on the performance of the sewing device.

Therefore, when fabrics having a predetermined thickness are selected in fabricating clothes, it is very important to know the maximum number of fabrics to be overlapped in the clothes in view of the performance of the sewing apparatus. .

For example, focusing on the waistline portion where the skirt 50 is stitched, the right front skirt pattern 52, the left front skirt pattern 54, and the rear skirt pattern 56 constituting the skirt portion include:
There are sewn darts D1A, D2A, D3A and D4A, which are subjected to a so-called dart process in which they are sewn and then fall down as shown in FIG.
On the defeated side, the number of overlapping fabrics is three. Also,
In the side line portions, the right front skirt pattern 52, the rear skirt pattern 56, and the left front skirt pattern 54
And the back skirt pattern 58 are sewn together, and a seam allowance process is performed. Therefore, the folded seam allowances are overlapped near the side, and the number of overlaps becomes two. However, in the calculation of the number of overlaps, the skilled worker performing the sewing calculates the number of stitches at each sewing position in consideration of the sewing process. There was a problem.

The present invention has been made in order to solve the above-mentioned problem, and it is possible to automatically calculate the maximum number of cloths to be made in the production of clothes using the various pattern data. When the thickness information per piece of fabric is obtained, a clothing pattern data processing device and a clothing pattern data processing program which can easily determine whether or not the clothing can be sewn by the sewing device owned by the user are recorded. It is an object of the present invention to provide a computer-readable recording medium.

[0020]

In order to achieve this object, a garment pattern data processing apparatus according to claim 1 of the present invention provides a garment pattern data processing apparatus, a pattern shape for sewing garments, stitching information, and a seam allowance. For those which process pattern data such as shapes, in particular, the number of overlapping sheets storing means for storing the number of overlapping sheets of cloth according to the sewing method, the number of overlapping sheets stored in the number of overlapping sheets storing means and the pattern data. And a maximum number-of-overlaps calculating means for calculating a maximum number of overlaps of the cloth at the time of producing the garment based on the above.

In the clothing pattern data processing apparatus according to the first aspect of the present invention, the maximum number-of-overlapping-sheets calculating means includes a number of overlapping sheets stored in the number-of-overlapping-sheets storing means and a pattern for producing the clothes. Based on the shape of the fabric, the sewing information, and the pattern data such as the angular shape of the seam allowance, the maximum number of fabrics to be overlapped when fabricating clothes is calculated. The maximum number of sheets can be automatically calculated, and when thickness information per piece of fabric is obtained, it is possible to easily determine whether or not the garment can be sewn by the sewing device owned by the user.

The clothing pattern data processing device according to a second aspect of the present invention provides a sewing pattern data processing apparatus, wherein the sewing order determining unit determines the sewing order of the clothes based on the pattern data, and the sewing order determined by the sewing order determining unit. And updating means for updating the maximum number of sheets of fabric based on the number of sheets.

The clothing pattern data processing apparatus according to claim 2, wherein the sewing order determining means comprises:
Since the sewing order of the clothes is determined based on the pattern data, and the maximum number of overlapping sheets updating means updates the maximum number of overlapping cloths based on the sewing order determined by the sewing order determining means,
Even when the type or design of clothing changes, the maximum number of layers of fabric in the production of clothing can be automatically calculated, and if the thickness information per piece of fabric is obtained, the sewing It is possible to easily determine whether or not the clothes can be sewn by the device.

A computer-readable recording medium in which the clothing pattern data processing program according to the third aspect of the present invention is recorded stores pattern data such as a shape of a pattern for fabricating the clothing, sewing information, and a square shape of a sewing allowance. For the object to be processed, in particular, when manufacturing the clothes, based on the number of layers and the pattern data stored in the number-of-layers storage means for storing the number of layers of fabric according to the sewing method, It is characterized by having a maximum overlapping number calculation program for calculating the maximum number of dough layers.

A computer-readable recording medium storing the clothing pattern data processing program according to claim 3 having the above configuration, wherein the computer reads the recording medium and executes each of the programs so that the maximum is obtained. The program for calculating the number of overlaps is based on the number of overlaps stored in the number-of-overlaps storage means and the pattern data for fabricating the garment, the stitching information, and the pattern data such as the angular shape of the seam allowance. Since the maximum number of dough layers is calculated, various pattern data can be used to automatically calculate the maximum number of dough layers in fabricating clothes, and the thickness information per piece of cloth is obtained. In this case, it is possible to easily determine whether or not the garment can be sewn by the sewing device owned by the user.

A computer-readable recording medium having recorded thereon a clothing pattern data processing program according to a fourth aspect of the present invention provides a sewing order determining program for determining a sewing order of the clothing based on the pattern data, And a program for updating the maximum number of sheets of the cloth based on the sewing order determined by the order determination program.

A computer-readable recording medium recording the clothing pattern data processing program according to claim 4 having the above configuration, wherein the computer reads the recording medium and executes each of the programs to maximize The sewing order determination program
The sewing order of the clothes is determined based on the pattern data, and the program for updating the maximum number of sheets updates the maximum number of sheets of the cloth based on the sewing order determined by the program for determining the sewing order. In this case, the maximum number of fabrics to be wrapped in the production of the garment can be automatically calculated, and when the thickness information per fabric is obtained, it is determined whether or not the garment can be sewn by the sewing device in possession. It can be easily determined.

[0028]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram of a clothing pattern data processing apparatus according to an embodiment of the present invention. In FIG. 1, a clothing pattern data processing device according to an embodiment of the present invention includes a CPU 1 for controlling the entire device, a ROM 2 for storing a program for controlling the entire device, and a pattern shape for producing clothing. Sewing information,
A RAM 3 for storing various data such as pattern data such as a square of a seam allowance, a mouse 4 for inputting pattern information to the CPU and instructions necessary for processing, a keyboard 5, and contents stored in the RAM 3. It is composed of a hard disk 6 for storing with a large capacity, a display 7 for displaying operation instructions, the number of overlaps, and the like, and a digitizer 8 for inputting a pattern shape.

The RAM 3 includes a program area 3A for detecting the number of overlapping stitches used when executing a program for calculating the number of cloths to be overlapped in the production of clothes, the shape of the pattern for producing the clothing, stitching information, and the corner of the seam allowance. A pattern data storage area 3B for storing pattern data such as a shape, a number change condition data storage area 3C which is a number-of-overlapping-number storage means for storing the number of layers of cloth according to a sewing method, and sewing for producing clothes. A sewing order data storage area 3D for storing the result of determining the order, and a sewing processing reflection cloth overlapping number storage area 3E for storing the maximum number of cloths to be overlapped when fabricating clothes.

Similarly to the RAM 3, the hard disk 6 also has a pattern data storage area 6B for storing pattern data such as the shape of a pattern for fabricating clothes, sewing information, and a square shape of a seam allowance. A number-change condition data storage area 6C, which is a number-of-overlaps storage means for storing the number of layers of fabric, and a sewing-order data storage area 6 for storing the result of determining the sewing order for producing clothes.
D, and a sewing process reflecting fabric overlap number storage area 6E for storing the maximum number of fabric overlaps when fabricating clothes.

Number change condition data storage areas 3C and 6C
Stores the number of cloths to be sewn in accordance with the sewing method. For example, as shown in FIG. 12, when the sewing mode is dart, the number of sewn cloths before sewing is two times the number of sewn cloths.
The number of stitches after sewing is three times the number of fabrics to be sewn. In the case of simple stitching, the number of stitches before sewing is the sum of the number of fabrics to be stitched, and the number of stitches after sewing is twice the sum of the fabrics to be stitched. further,
In the case of finishing the end, the number of stitches before sewing is three times the number of fabrics to be sewn, and the number of sewings after sewing is also three times the number of fabrics to be sewn.
Double.

Next, pattern data processing of the clothing pattern data processing apparatus according to the present embodiment configured as described above will be described with reference to the skirt 50 of FIG. 13 as an example.

FIG. 2 is a flowchart showing the flow of the process of detecting the number of overlapped stitches in this embodiment. In FIG. 2, first, the user of the apparatus inputs "wrap tight skirt" as a design name (step 1401,
Hereinafter, a step is described as S. The same applies to other steps, and the corresponding pattern data is read into the memory (S140).
2), a check is started for each pattern (S140)
3) A sewing order detection process for one part for detecting the sewing order for each pattern is executed (S1404).

The processing for detecting the sewing order of one part will be described below.

FIG. 3 is a flowchart showing the flow of the sewing order detecting process for one pattern in this embodiment. In this process, first, the corner code D set on the first P0 is obtained from the sewing margin angle shape data (S
1501). This is not a code indicating a dart part (S1502: No), and the seam allowance width of the part starting from the dart part is also set (S1504: Yes), so that a line detection starting from the corner P0 is detected. The processing is executed (S1506).

FIG. 4 is a flowchart showing the flow of the line detection process in the present embodiment. In FIG.
First, looking at the next corner code, H set in P4-P6
(S1601), since this is a dart code (S16
02: Yes), disregarding the next corner code, that is, P8
The C set above is obtained (S1601). Since this is not a dart (S1602: No), a line P0-P8 is obtained using this as the end point of the line (S1603). Returning to FIG. 3, it is confirmed on the sewing margin angle shape data that there is a sewing margin width setting for a portion ending at P0 (S1507), and the corner code D of P0 is checked.
Although it is a sewing margin code indicating that the previous line is sewn first (S1508), since the previous line has not been set yet (S1512, that is, S1701 in FIG. 5,
1702) The previous line is detected by the same processing as P0-P8 (S1703), the detected P20-P0 is set at the end of the sewing order data (S1704), and the previously detected P0-P8 is continued. (S1705, return here to FIG. 3, S1513).

The corner code set after P0 is P
This is a code indicating the dart of H set for 4-P6 (S1502). Therefore, P4-P6 is set at the head of the sewing order data (S1503). Then, when the processing is shifted to the next corner code, the C set in P8 is set.
However, since this is not a dart (S1502), a line P8-P12 starting from here is detected (S150).
6). Here, C indicates that the next line is sewn before the previous line (S1508, 1509).
The previous line data is searched from the sewing order data (S151
0) P8-P12 is set before P0-P8 (S1)
511).

Next, the set corner code is P12
Although the above D is not dart (S1502),
Similarly to the above, the line P12-P16 starting from here is detected, and since the corner code indicates that the previous line is first, the data whose end point is P12, that is, P8-P12 is detected from the sewing order data. Then, P12-P16 are set.

Since the next corner code on P16 is B which does not specify the sewing order, the next corner code is P1 next to the previous line P12-P16.
6-P18 is set. The corner code of the next corner P18 is D
, The previous line has priority, but the line starting from P18 has no sewing margin set. That is, since the line starting from here is not sewn to another, the processing is skipped to the next corner code. The next is C set on P20, but the line starting from this is already set in the sewing order data, and the sewing margin angle code check for pattern A has been completed (S151).
5).

Here, returning to FIG. 2, a part code set for each sewing part set in the sewing order data is checked (S1405). First, since the first sewing position P4-P6 is dart, no further data is required.

Next, since ME and WM are set on P20-P0, ME-WM is set in the sewing order data. Hereinafter, similarly, WR-S is added to P8-P12.
R is set to SR-SM in P12-P15. With respect to the next P16-P18, SM, SFC, and SM are set in order including the point P17 therebetween, so that SM-SFC-SM is set in the sewing order data. Thus, the sewing order data for the right front skirt pattern 52 (hereinafter, referred to as pattern A) is obtained. Less than,
Similarly, the sewing order data is set for the remaining five patterns (S1406).

Next, the sewing order through all the patterns is checked (S1407).

FIG. 6 is a flowchart showing the flow of the sewing order detection process for all the patterns in this embodiment.
In FIG. 6, first, the sewing order data for the pattern A is referred to (S1801), and the sewing is performed in the pattern. That is, the sewing position data that does not use other patterns in the sewing is set in the entire sewing order data (S
1802, hereinafter in FIG. 7). The first sewing position of the pattern A is a dart D1 (S1901, 1902),
Since this is processed in the pattern A (S
1903), the data of D1, A (P4-P6) is set as the sewing location data in the entire sewing order data (S1).
1904). The sewing position in the next pattern A is ME
−WM (S1901, 1902), which is a portion to be sewn to another pattern (S190, S1901).
3), the check on pattern A is suspended (FIG. 6)
Then, in the loop from S1801 to S1803), the sewing order of the next left front skirt pattern 54 (hereinafter referred to as pattern B) is checked.

The pattern B is processed in exactly the same manner as the pattern A, so that the sewing position data
2, B (P4-P6) is added to the entire sewing order data, and since the next ME1-WM1 is a place to be sewn to another pattern, it is temporarily reserved and the operation proceeds to the check of the next pattern C. For the back skirt pattern 56 (hereinafter, referred to as pattern C), after adding the sewing location data of the dart D4 and D4, C (P22-P24) to the overall sewing order data, the dart D3, which is the next sewing location, is added.
Is also sewn only in the pattern C, D3 and C (P16-P18) are similarly added to the entire sewing order data, but the next WR-SR is sewn to another pattern. Therefore, the process proceeds to the next pattern check.

Hereinafter, the right front facing pattern 58 (hereinafter referred to as pattern D), the left front facing pattern 60 (hereinafter referred to as pattern E), and the rear facing pattern 62 (hereinafter referred to as pattern F) are all the first. Since the sewn part is a part that can be sewn with other patterns,
Nothing is added to the entire sewing order data,
Checks for all patterns are completed (S18).
03).

Next, a pattern A is first obtained as a pattern having a sewing position which has not been set yet in the entire sewing order data (S1804, 1805). The first unset sewing position is ME-WM (S1806, S180).
7) When the partner pattern to be sewn is searched from the sewing order data (FIG. 9) for each pattern, it is pattern D (S1808), which is the first sewing position for pattern D, that is, the overall sewing order. It can be seen that this is the first data not set in the data (S1809).

Therefore, the data of this sewing position, ME-W
M, A (P20-P0) and D (P9-P0) are added to the entire sewing order data (S1810). Here, for the patterns A and D having the currently set sewing positions, if there are any sewing positions in the sewing order data that do not require other patterns, they are respectively added to the entire sewing order data. No sewing is set here because the sewing position is a portion to be sewn with another pattern (S1811, 1812, and returns to FIG. 6 through the processing of FIG. 7 respectively).

Since the next sewing position of the ME-WM of the pattern A that has just been set is the WR-SR (S1806,
1807), the target pattern is similarly searched (S1).
1808), sewing location data WR-SR, A (P8-P
12), C (P0-P4) is added to the entire sewing order data (S1809, 1810), and the target patterns A and C do not need other patterns in the sewing order data. When it is checked whether or not there is a portion (S1811, hereinafter, refer to FIG. 7), first, the pattern A
The next sewing point is SR-SM (S1901,
1902), there is no other stitching pattern (S1903).
SM and A (P12-P16) are also added to the entire sewing order data (S1904), and the next SM-SFC is also a part to be sewn in the pattern A (S190).
1, 1902, 1903), and the sewing location data SM-
SFC, A (P16-P18) are also added to the entire sewing order data (S1904).

The next WM-WFC is added in the same manner. However, the next portion WM- (D1) -WR is a portion to be sewn to another pattern (return from S1903 to FIG. 6). Looking at the stitched portion (S1812, to FIG. 19), since the SL-WL is a portion to be stitched with another pattern, both the pattern A and the pattern C are moved to the next stitched portion instead of the portion to be sewn alone (S1806). ).

The next sewing position in pattern A is WM
-(D1)-WR (S1807), which is sewn to the pattern D (S1808), but the place WR-MR to be sewn first in the sewing order data of the pattern D has not yet been set in the entire sewing order data. (S180
9). Therefore, the processing of the pattern A is suspended, and the process proceeds to the check of the next left front skirt pattern 54 (S1).
804, 1805). Thereafter, the same processing is continued until there is no pattern with a stitched portion that is not set in the entire stitched portion, and the sewing order data through all the patterns as shown in FIG. 10 is obtained.

Next, the sewing order data obtained through all the patterns obtained as described above is checked in order (S1408), and the number of fabric layers is sequentially updated (S1409, hereinafter to FIG. 8).

First, since the first sewing position D1 is a dart, the number of stitches is multiplied by 2 for the current number and 3 for the new number after sewing from the number change condition data in FIG. (S2001). Since the sewing position D1 has not yet been set at the overlap point or the change position of the cloth overlap number update data in FIG. 11 (S2002, 2003), the current number is set to 1 and the above-described 2 and 3 are added to it. Using the values obtained by the respective multiplications, the data of the changed portion D1, the number of sewn pieces 2, and the new number of pieces 3 are set in the cloth overlap number update data (S2007,
Hereinafter, it returns to FIG. 2). Hereinafter, similarly, the sewing order data through all the patterns can be sequentially checked as D2, D4, and D3, and the data can be set in the cloth overlap number update data.

The next sewing position ME-WM is as follows (hereinafter, FIG. 8)
Since the stitching is performed, both the number of stitches and the number of new sheets need only be multiplied by 2 based on the number-of-sheets change condition data (S2001). Since this stitched portion has not yet been set in the fabric overlap number update data (S2002, 2003), , The changed part ME-WM, the number of stitches 2, and the number of new sheets 2 are set (S2007, returning to FIG. 2). Next WR
-SR also undergoes the same processing, and the changed part WR-SR, the number of stitches 2, and the number of new sheets 2 are set in the cloth overlap number update data.

At this point, the process proceeds to the next sewing position SR-SM (to FIG. 20). Since this does not have a sewing target and is not a dart, it corresponds to the “end of end” of the number changing condition data. , The new number is multiplied by 3 (S2001). This sewing position is not set at the duplication point of the cloth overlap number update data (S20).
02), looking at the changed part data, it overlaps at the point of SR of the already set sewing point of WR-SR (S2003). For this SR, the pattern A and the point code P are obtained from the sewing order data (FIG. 10).
12, the sewing allowance data of the pattern data (FIG. 1)
Referring to the sewing margin angle shape D from 8) (S2004),
Since the seam allowance angle shape D indicates that the seam is sewn once from the square shape data shown in FIG. 19 and then sewn from another direction (S2005), the seam allowance of the WR-SR sewn earlier is changed to the SR -It turns out that the sewing margin of SM is folded in three and sewn.

Accordingly, since the new number of WR-SR is 2, it is multiplied by 3 to obtain 6 sheets, so that the overlapping point SR, the number of sewn 6 and the new number 6 are set in the cloth overlapping number update data ( S2006).

Then, the SR obtained with the current number of sheets as one
The data of -SM, the changed part SR-SM, the number of stitches 3, and the number of new sheets 3 are also set in the cloth overlap number update data (S20
07, hereinafter, returning to FIG. 2). Hereinafter, similarly, when the number of stitches is sequentially detected for the sewing order data through all the patterns and set in the cloth overlap number update data, the data of FIG. 11 is obtained. It is detected that the number is six (S1411).

By the above-described processing, the maximum number of sewn fabrics when sewing a wrap tight skirt was detected.

Note that the processing of S1411 in the present embodiment functions as the maximum number of overlapping sheets calculating means or the maximum number of overlapping sheets calculating program, and the processing of S1404 to S1407 functions as the sewing order determining means or the sewing order determining program. The process functions as the maximum number of sheets update unit or the maximum number of sheets update program.

In this embodiment, the sewing positions of each pattern are checked in order without creating the sewing order data.
Based on the region code and the presence or absence of the sewing target obtained by the sewing data search, the corresponding number change condition can be obtained to obtain the number of stitches.

Further, in the clothing pattern data processing apparatus of the present embodiment, a maximum stacking number calculation program, a sewing order determining program, and a maximum stacking number updating program are stored in the ROM in advance. The invention is not necessarily limited to this. For example, a program in which these programs are stored in a floppy disk, CD-ROM, or the like can be read by a reading device, installed, and operated. In addition, a program can be read and operated from an external information processing device using a wired or wireless line. In this case, the floppy disk, the CD-ROM, or the memory of the external information processing apparatus that stores the program constitutes the recording medium of the present invention.

[0062]

As is apparent from the above description, according to the clothing pattern data processing apparatus of the first aspect of the present invention, the maximum number of overlapping sheets calculating means includes the number of overlapping sheets stored in the number of overlapping sheets storing means. Based on the number of sheets and the pattern shape for fabricating the clothes, the sewing information, and the pattern data such as the square shape of the seam allowance, the maximum number of fabrics to be overlapped when fabricating the clothes is calculated. By using this function, the maximum number of fabrics to be wrapped in the production of clothes can be automatically calculated, and when the thickness information per fabric is obtained, it is determined whether or not the garment can be sewn by the sewing device owned by the garment. It can be easily determined.

Further, according to the clothing pattern data processing device of the present invention, the sewing order determining means determines the sewing order of the clothes based on the pattern data, and the maximum overlapping number updating means determines the sewing order. Since the maximum number of fabric layers is updated based on the sewing order determined by the means, even when the type or design of the clothing changes, the maximum number of fabric layers in the production of the clothing can be automatically calculated. When the thickness information per piece of fabric is obtained, it can be easily determined whether or not the garment can be sewn by the sewing device owned by the user.

According to a computer-readable recording medium recording the clothing pattern data processing program according to the third aspect, the computer reads the recording medium and executes each program.
The program for calculating the maximum number of overlapping sheets is used when fabricating clothes based on the number of overlapping layers stored in the number of overlapping sheets storage means and pattern data such as a shape of a pattern for fabricating the clothes, stitching information, and a square shape of a seam allowance. Calculates the maximum number of layers of cloth in the above, so it is possible to automatically calculate the maximum number of layers of cloth in the production of clothes using various pattern data and obtain thickness information per layer of cloth. In such a case, it is possible to easily determine whether or not the garment can be sewn by the sewing device owned by the user. In addition, the program is stored on a floppy disk or CD.
-It can also be provided by recording from a variety of recording media such as a ROM on a recording medium suitable for a clothing pattern data processing device.

Further, according to the computer-readable recording medium recording the clothing pattern data processing program according to the fourth aspect, the computer reads the recording medium and executes each program to execute the sewing order. The determination program determines the sewing order of the clothes based on the pattern data, and the maximum number of sheets update program updates the maximum number of sheets of the cloth based on the sewing order determined by the sewing order determination program. Even if the design has changed, the maximum number of fabrics to be wrapped in the production of clothing can be automatically calculated, and when the thickness information per fabric is obtained, the clothing that can be sewn by the sewing device owned by the customer can be obtained. Can be easily determined. Further, the program can be provided by being recorded from a variety of recording media such as a floppy disk and a CD-ROM on a recording medium suitable for a clothing pattern data processing device.

[Brief description of the drawings]

FIG. 1 is a block diagram of a clothing pattern data processing device according to an embodiment of the present invention.

FIG. 2 is a flowchart illustrating a flow of a process of detecting the number of overlapping stitches according to the present embodiment.

FIG. 3 is a flowchart showing a flow of a sewing order detection process for one pattern in the present embodiment.

FIG. 4 is a flowchart illustrating a flow of a line detection process according to the present embodiment.

FIG. 5 is a flowchart showing a flow of a previous line data position acquisition process in the present embodiment.

FIG. 6 is a flowchart illustrating a flow of a sewing order detection process for all patterns in the present embodiment.

FIG. 7 is a flowchart illustrating a flow of a sewing order data creation process of a sewing location in a pattern according to the present embodiment.

FIG. 8 is a flowchart showing the flow of a fabric overlap number updating process according to the embodiment.

FIG. 9 is an explanatory diagram illustrating sewing order data of each pattern according to the present embodiment.

FIG. 10 is an explanatory diagram illustrating all-pattern sewing order data in the present embodiment.

FIG. 11 is an explanatory diagram for explaining update data of the number of overlapped fabrics in the present embodiment.

FIG. 12 is an explanatory diagram illustrating number-of-sheets change condition data in the present embodiment.

FIG. 13 is a schematic view showing a completed wrap tight skirt.

FIG. 14 is an explanatory diagram illustrating a conventional part code.

FIG. 15 is an explanatory diagram illustrating a conventional configuration point number.

FIG. 16 is an explanatory diagram illustrating pattern data of a conventional pattern shape.

FIG. 17 is an explanatory diagram for explaining pattern data of conventional stitching information.

FIG. 18 is an explanatory diagram for explaining conventional sewing margin angle pattern data.

FIG. 19 is an explanatory view illustrating a conventional sewing margin angle shape.

FIG. 20 is an explanatory diagram illustrating a state in which a waistline and a hem of a conventional wrap tight skirt are stitched.

[Explanation of symbols]

 1 CPU 3 RAM 3A Overlap stitch number detection program area 3C, 6C Number change condition data storage area 6 Hard disk

Claims (4)

[Claims] 1. A shape of a pattern for producing clothes,
In a clothing pattern data processing apparatus for processing pattern data such as stitching information and a square shape of a seam allowance, an overlapping number storage means for storing an overlapping number of cloths according to a sewing method; A clothing pattern data processing apparatus comprising: a maximum number of overlapping sheets calculating means for calculating a maximum number of overlapping layers of the cloth when manufacturing the clothes based on the number of overlapping layers and the pattern data. 2. A sewing order determining means for determining a sewing order of the clothes based on the pattern data, and a maximum number of sheets for updating the maximum number of cloths based on the sewing order determined by the sewing order determining means. The clothing pattern data processing apparatus according to claim 1, further comprising an updating unit. 3. The shape of a pattern for producing clothes,
In a computer-readable recording medium storing a pattern data processing program of clothing for processing sewing data and pattern data such as a square shape of a seam allowance, stored in a number-of-laps storage means for storing the number of layers of cloth according to a sewing method. A clothing pattern data processing program, comprising: a maximum overlapping number calculation program for calculating a maximum number of overlapping layers of the cloth at the time of producing the garment based on the overlapped number and the pattern data. A computer-readable recording medium that has been recorded. 4. A sewing order determining program for determining a sewing order of the clothes based on the pattern data, and a maximum number of sheets for updating the maximum number of sheets of the cloth based on the sewing order determined by the sewing order determining program. 4. A computer-readable recording medium recording a clothing pattern data processing program according to claim 3, further comprising an update program.