JPH09108934A - Arrangement of raw material and cutting-out method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily perform arrangement work such as calculation of arrangement by collecting raw materials on the basis of its positional relationship after the positional relationship between mutual raw materials is determined by positioning a raw material in a crossing part between a rightward rising oblique line and a rightward lowering oblique line. SOLUTION: A raw material (a) is positioned in a crossing part (1, 5) between a rightward rising oblique line k1 on the leftward end and a rightward lowering oblique line n5 in the fifth from the left. The other raw material is not positioned in the rightward rising oblique line k1 and the rightward lowering oblique line n5. In this way, the whole raw materials (a to h) are arranged. When arrangement of the whole raw materials (a to h) is finished in this way, the vertical and lateral relationship between the raw materials is determined by using this arrangement determining diagram. When the raw materials (a to h) are collected on the basis of this positional relationship, the size necessary to arrange the raw materials (a to h) can be confirmed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for arranging a plurality of materials on a substrate or a container and a method for cutting a plurality of materials from the substrate.

[0002]

2. Description of the Related Art A method of arranging and cutting out materials of this kind is, for example, a step of layout designing a semiconductor integrated circuit or a printed wiring board, and cutting out a plurality of members of various sizes from a flat base material such as a steel plate or a cloth. It is used in processes.

By the way, in arranging and cutting out materials, if a substrate as small as possible can be used, the manufacturing cost can be reduced and the performance of the product in which the materials are arranged can be improved.

Therefore, a method of deciding the material arrangement in the conventional material arrangement and cutting method will be described with reference to FIG. FIG. 6 is an explanatory diagram for explaining a method of determining the arrangement of the materials, (a) is a diagram showing a state in which the materials are dispersed,
(B) is a diagram showing a state where the materials are gathered together.

FIG. 6 (a) shows materials mi of various sizes. Assuming a rectangular base material K having an area slightly larger than the total area of the material mi, the outer edge of the base material K, that is, a rectangular frame W is drawn as shown in FIG. 6B. Then, it is necessary to fit all the materials mi into the frame W so as not to overlap each other.

There are various methods for this fitting, but as a typical example, first, the largest material mi is fitted into the frame W, and then the second largest material mi.
There is a method of fitting in order of large material mi, such as fitting. There is no problem if all the materials mi fit in, but if they do not fit, change the arrangement of the materials mi and refit. In this way, if trial and error is not possible and fitting is impossible, a slightly larger frame W is prepared and the process is performed again. In this way, the smallest frame W in which all the material mi can be fitted is searched for.

[0007]

By the way, FIG. 6 (b)
In, when the positions of the materials mi are changed, if the materials mi whose positions are to be exchanged (for example, the materials m7 and m8) are approximately the same size, even if the positions of the materials mi are changed. ,
Other materials mi (materials other than materials m7 and m8) do not need to be repositioned. Therefore, it is possible to manage how the arrangement is changed even if the arrangement is repeatedly changed. However, if the materials mi (the material m7 and the material m9) whose positions are to be exchanged have significantly different sizes,
When the material mi changes its position, the positions of other material mi also need to be changed significantly. Therefore, when the arrangement change is repeated, it becomes difficult to manage how the arrangement of the material mi is changed. As a result, it is difficult to systematically search for the smallest frame W.

Further, even in the other proposed methods, it is difficult to systematically perform, and enormous calculation is required.

The present invention has been made to solve the above problems, and provides a method for arranging and cutting out a material that systematically searches for a minimum area where a material can be arranged. Has an aim. Further, it is a secondary object to provide a method of arranging and cutting out a material that can find the minimum area where a material can be arranged with a small amount of calculation.

[0010]

In order to achieve the above-mentioned object, a method of arranging materials according to the present invention comprises arranging a plurality of substantially rectangular materials (a to h) of arbitrary size, and First of
It is composed of steps from the 12th step. 1) The first step of drawing upward diagonal lines (k) that do not intersect each other by the number (M) of the materials. 2) A second step of drawing diagonal lines (n) that descend to the right and do not intersect each other by the number of the materials. 3) A third step of arranging each material at the intersection so that the diagonal lines rising to the right and the diagonal lines descending to the right intersect each other, and one material is positioned at each diagonal.

4) The other materials located on the right side of the downward-sloping diagonal line where the arbitrary material is located and on the right side of the upward-sloping diagonal line where the arbitrary material is located are the above-mentioned arbitrary The fourth step is to define it so that it is located on the right side of the material. 5) Similarly, the other materials located to the left of the downward-sloping diagonal line where the arbitrary material is located and to the left of the upward-sloping diagonal line where the arbitrary material is located are:
A fifth step of defining the arbitrary material so that it is located on the left side. 6) The other material that is located above the downward-sloping diagonal line where the arbitrary material is located and above the upward-sloping diagonal line where the arbitrary material is located is the optional material. A sixth step, which is defined as being located on the upper side with respect to. 7) Similarly, another material positioned below the downward-sloping diagonal line where the arbitrary material is located and below the upward-sloping diagonal line where this material is located. Is
A seventh step of defining the arbitrary material so as to be located on the lower side.

8) An eighth step in which the four steps from the fourth step to the seventh step are repeated with another material to determine the vertical or horizontal relationship between all the materials. 9) A ninth step in which one of the left and right sides is defined as a vertical base line side, and the side of the material having no other material on the vertical base line side on the vertical base line side is positioned on the vertical base line (P). 10) A tenth step in which one of the upper and lower sides is defined as the horizontal baseline side, and the horizontal baseline side of the material having no other material on the horizontal baseline side is positioned at the horizontal baseline (T).

11) For the material located on the vertical baseline,
An eleventh step of packing other materials on the vertical base line side so as not to overlap, based on the definitions of the fourth step and the fifth step. 12) A twelfth step of filling the material located on the horizontal baseline with the horizontal baseline side so as not to overlap other materials, based on the definitions of the sixth step and the seventh step.

Further, the arrangement of the raw materials in the third step may be changed and the steps from the fourth step to the twelfth step may be repeated again.

Although there are a plurality of materials, a part of the material is replaced with a rectangular space (S) having an arbitrary size, and the first to twelfth steps are performed in the same manner as described above. May be performed.

Further, instead of the material, a material cutting pattern may be arranged and the material may be cut out based on this cutting pattern.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Next, an embodiment of a method for arranging and cutting out materials according to the present invention will be described with reference to FIGS. FIG. 1 is a layout determining graphic used in the layout and cutting method of the material in the present invention. FIG. 2 is a diagram showing a state in which materials are arranged based on the arrangement determining graphic of FIG. FIG. 3 is a diagram in the middle of collecting the materials.
FIG. 4 is a diagram showing a state where the materials are gathered together.

A plurality of rectangular materials a to h of arbitrary size
Are arranged on a substantially rectangular substrate. For that purpose, first, an arrangement determining graphic as shown in FIG. 1 is drawn. FIG.
In this case, the number M of the materials a to h is eight. Then, as the first step, the number M of the raw materials, that is, eight slanting lines k having an inclination angle of 45 ° and rising to the right are drawn. Then, as a second step, the number M of the raw materials, that is, eight slanting lines n with a slanting angle of −45 ° are drawn so as to intersect with the slanting lines k rising to the right. Then, 8 × 8, that is, 64 intersecting points, that is, intersecting portions between the diagonal line k rising to the right and the diagonal line n falling to the right are formed.

Next, as a third step, the respective materials are arranged at the intersections so that one material is located on each of the oblique line k rising to the right and the oblique line n descending to the right. That is, in FIG. 1, the material a is the leftmost upward-sloping diagonal line k1.
It is located at the intersection (1,5) with the fifth downward-sloping diagonal line n5 from the left. No other material is located on the slanting line k1 rising to the right and the slanting line n5 descending to the right. In this way, all the materials a to h are arranged. This arrangement may be performed appropriately, but it is also possible to estimate the arrangement that is likely to be arranged in the minimum area, or to arrange by using a random number table with a computer.

When all the materials a to h have been arranged in this way, the layout determining graphic is used to determine the vertical and horizontal relationship between the materials. This determination method will be described for the material f.

The material f is located at (5,3), that is, at the intersection of the oblique line k5 rising to the right and the oblique line n3 descending to the right.
The two-dimensional space is divided into four spaces on the left, right, top and bottom by a diagonal line k5 that rises to the right and a diagonal line n3 that descends to the right.

Then, other materials d and g existing on the right side
Is defined so as to be located on the right side of the material f (fourth step). Similarly, other materials e on the left side
Is defined so as to be located on the left side of the material f (fifth step). Further, similarly, the other materials a, b, c existing on the upper side are defined so as to be positioned on the upper side with respect to the material f (sixth step). Further, similarly, the other material h existing on the lower side is defined so as to be positioned on the lower side with respect to the material f (seventh step).

By this work, the vertical or horizontal relationship between the arbitrary material f and other materials is defined. This operation is performed on another material until the vertical or horizontal relationship between all the materials is determined (8th step). That is, if the number of materials is M, it is necessary to perform M-1 materials. When this work is completed, the arrangement relationship as shown in FIG. 2 is obtained.

Then, in FIG. 3, one of the left and right sides is defined as the vertical baseline side. For example, the left side is the vertical baseline side. Then, the left sides of the materials a, b, and e having no other material on the left side are positioned on the vertical base line P (ninth step).

Similarly, either the upper side or the lower side is defined as the horizontal baseline side. For example, the lower side is the horizontal baseline side. Then, the lower sides of the materials e and h having no other material on the lower side are positioned on the horizontal base line T (tenth step).

The material a located on the vertical base line P,
Based on the definitions of the fourth step and the fifth step, b and e are filled with other materials on the vertical base line side, that is, on the left side so as not to overlap (the eleventh step).

Similarly, with respect to the materials e and h located on the horizontal base line T, based on the definitions of the sixth step and the seventh step, the other materials are placed on the horizontal base line side, that is, on the lower side so as not to overlap. Pack (12th step).

When the materials a to h are collected in this manner, the materials a to h are collected as shown in FIG. Then, the size required to arrange the materials a to h is known. Therefore, if a base material or a container larger than the found size is prepared, the material is arranged in the base material or the container, The material can be cut out (step 13). When cutting out a material, not the material but a material cutting pattern is arranged, and the material is cut out based on this cutting pattern.

By the way, if this size is not satisfactory and the base material is desired to be made smaller, the arrangement of the materials in FIG. 1 may be changed. Then, the work may be finished when a base material having a satisfactory size can be obtained. Of course, all arrangements can be considered. It is possible to change the arrangement randomly, or it is possible to estimate the arrangement that is likely to be improved by comparing the changed state and the changed state.

By the way, in order to arrange a space S for screwing or the like on the base material on which the material is placed or to load it in a case such as a video, the shape of the base material is not rectangular but its periphery is chipped. You may want to shape it. In such a case, it is necessary to arrange the space S in the central portion or the periphery of the base material K.

Therefore, the space in which the rectangular space S is located is treated in the same manner as the space in which the rectangular materials a to h are located, and instead of the materials a to h, one or more spaces S are arranged in the layout determining graphic. Place it at the intersection. Then, as in the case of the materials a to h, the fourth step to the twelfth step are performed.
As a result, it is possible to obtain an arrangement or the like having a substantially “D” shape shown in FIG.

The embodiment of the present invention has been described above in detail.
The present invention is not limited to the above embodiment,
Within the gist of the present invention described in the claims,
Various changes can be made. Modification examples of the present invention are exemplified below. (1) In the embodiment, the number M of the materials a to h is eight, but this number M can of course be changed.
It is possible to use 4 or 36.

(2) Although the orientation of the material is not changed in the embodiment, it is also possible to change the orientation of the material in the vertical and horizontal directions. (3) In the embodiment, the upward-sloping diagonal line k is drawn at an inclination angle of 45 °. However, if the upward-sloping diagonal line k does not intersect with each other and is upward-sloping, the inclination angle is appropriate. It can be changed. For example, it is also possible to draw a diagonal line k that rises to the right at 35 °. Similarly, a diagonal line n descending to the right
The inclination angle of can also be changed appropriately.

(4) The target material or base material is not particularly limited. However, a layout design process for a semiconductor integrated circuit or a printed wiring board, which uses a circuit element as a material and a circuit board as a base material, is most suitable as an application field. Also,
It is also suitable when packing articles as raw materials into containers or cutting out a plurality of raw materials of various sizes from a flat base material such as cloth or iron plate.

(5) It is not necessary to actually form the layout determining graphic on paper or the like, but it is also possible to form it in a virtual space created by an electronic computer or the like. (6) The steps do not necessarily have to be performed in the order described. For example, the first step, the second step, the fourth step to the seventh step
The steps and the like can be performed in reverse order or simultaneously. (7) In the embodiment, the material is rectangular, but the material itself does not necessarily have to be rectangular as long as the space secured for placing the material is rectangular.

[0036]

According to the present invention, the materials are positioned at the intersections of the oblique lines rising to the right and the oblique lines descending to the right, and after determining the positional relationship between the materials, based on the positional relationship,
The materials are gathered together. Therefore, since the materials are simply packed and arranged based on the determined positional relationship, the arrangement work such as the arrangement calculation can be easily performed.

If the obtained arrangement is not satisfactory, it can be dealt with only by changing the intersection where the materials are arranged. Since the number of the intersecting portions is only the square of the number M of materials, that is, M ² , there is a simple management of the arrangement of the materials, and the arrangement of the materials can be systematically changed.

Further, since a part of the material is replaced with a rectangular space having an arbitrary size, a space can be formed around or inside the arranged material. As a result, a space for screwing, a notch, etc. can be formed in the base material on which the material is arranged.

When a material cutout pattern is arranged instead of the material, the material can be cut out based on this cutout pattern.

[Brief description of the drawings]

FIG. 1 is a layout determining graphic used in a layout and cutting method of a material according to the present invention.

FIG. 2 is a diagram showing a state in which materials are arranged based on the arrangement determining graphic of FIG.

FIG. 3 is a diagram in the middle of gathering materials.

FIG. 4 is a view showing a state in which materials are gathered together.

FIG. 5 is an arrangement diagram when arranging spaces.

FIG. 6 is an explanatory diagram for explaining a method of determining the arrangement of materials, FIG. 6A is a diagram showing a state in which materials are dispersed,
(B) is a diagram showing a state where the materials are gathered together.

[Explanation of symbols]

 a to h material k diagonal line rising to the right n diagonal line descending to the right P vertical baseline S space T horizontal baseline

Claims (6)

[Claims] 1. A method of arranging a plurality of substantially rectangular materials of arbitrary size, the first step of drawing upward diagonal lines that do not intersect each other by the number of the materials, and the number of the materials. Only, a second step of drawing diagonal lines to the right that do not intersect with each other, and the diagonal lines rising to the right and the diagonal lines descending to the right intersect each other, and one material is positioned in each diagonal, The third step of arranging each material at the intersection, and to the right of the downward-sloping diagonal line where any material is located, and to the right of the upward-sloping diagonal line where this material is located. The other materials are defined in the same manner as the fourth step, which is defined so as to be located on the right side with respect to the arbitrary material, in the same manner, on the left side of the downward-sloping diagonal line where the arbitrary material is located, and , The diagonal line to the right where this material is located The other material located also on the left side is defined as a fifth step which is defined so as to be located on the left side with respect to the arbitrary material, and the upper side of the downward-sloping diagonal line where the arbitrary material is located. And, the other material located above the diagonal line to the right where this material is located is defined in the same manner as the sixth step in which it is defined to be located above the arbitrary material. And the other material located below the diagonal line to the right where the arbitrary material is located and below the upward diagonal line to which this material is located is 7th step which is defined so as to be positioned on the lower side with respect to the material, and 4 steps from the 4th step to the 7th step are repeated with another material, and the vertical or horizontal direction between all the materials Eighth step of determining the relationship, and either the left or right side as the vertical baseline side Therefore, the side of the vertical baseline side of the material that does not have any other material on the vertical baseline side is located at the vertical baseline, and the ninth step is defined as one of the upper and lower sides, which is the horizontal baseline side. Based on the definition of the above-mentioned 4th process and 5th process for the material located on the vertical base line, the 10th process for positioning the side on the horizontal base line side of the material that does not have other materials on the horizontal base line. , 11th step of packing other materials on the vertical baseline side so that they do not overlap, and for materials located on the horizontal baseline, do not overlap other materials based on the definitions of the 6th and 7th steps above. And a twelfth step of filling the horizontal base line side. 2. The method for arranging a material according to claim 1, wherein the arrangement of the material in the third step is changed and the steps from the fourth step to the twelfth step are repeated again. 3. A material arrangement method for arranging a plurality of spaces, each of which has a substantially rectangular material of an arbitrary size, and a space, each of which has a rectangular space of an arbitrary size. The first step is to draw diagonal lines to the right that do not intersect each other, and the second step is to draw diagonal lines to the right that do not intersect each other by the total number of spaces, and the diagonal line that rises to the right and the diagonal lines that descend to the right The third step of arranging each space at the intersection so that one space is located at each of the diagonal lines intersecting each other, and on the right side of the diagonal line descending to the right where any space is located. And, as in the fourth step in which the other space located on the right side of the diagonal line to the right where this space is located is defined to be located on the right side with respect to the arbitrary space, And the other space located on the left side of the downward-sloping diagonal line where the arbitrary space is located and on the left side of the upward-sloping diagonal line where the arbitrary space is located is the arbitrary space. And a fifth step of defining it so as to be located on the left side with respect to the above, and above the oblique line rising to the right where the arbitrary space is located and above the oblique line rising to the right where this space is located. Also, the other space located on the upper side is defined in the same manner as the sixth step in which it is defined to be located on the upper side with respect to the arbitrary space. Also, the other space located on the lower side and below the diagonal line to the right where this space is located is defined to be located on the lower side with respect to the arbitrary space. Process, The fourth step from the fourth step to the seventh step is repeated in another space to determine an up-down or left-right relationship between all the spaces, and one of the left and right sides is the vertical baseline side. And the vertical baseline side of the space having no other space on the vertical baseline side, the ninth step of positioning the side on the vertical baseline, and one of the upper and lower sides is defined as the horizontal baseline side, the horizontal baseline Based on the definition of the above-mentioned 4th process and 5th process for the space located on the vertical baseline, the 10th process for positioning the side on the horizontal baseline side of the space that has no other space on the side to the horizontal baseline. Then, based on the definitions of the 6th and 7th steps above, the 11th step of filling the other spaces into the vertical baseline side so that they do not overlap and the space located on the horizontal baseline do not overlap with other spaces. like A method of arranging a material, which comprises a twelfth step of packing to a horizontal baseline side. 4. The method of arranging a material according to claim 3, wherein the arrangement of the spaces in the third step is changed and the steps from the fourth step to the twelfth step are repeated again. 5. A method of cutting out a material for cutting out a plurality of substantially rectangular-shaped materials of arbitrary size, the first step of drawing upward diagonal lines that do not intersect each other by the number of the materials to be cut out, and The second step of drawing downward sloping diagonal lines that do not intersect each other by a number, and the upward sloping diagonal lines and the downward sloping diagonal lines intersect each other, and one material cutting pattern is located in each diagonal line. As described above, the third step of arranging each material cutting pattern at the intersection, and the right side of the diagonal line to the right where the arbitrary material cutting pattern is located, and the right where this material cutting pattern is located The other material cutting pattern located on the right side of the rising diagonal line is defined to be located on the right side of the arbitrary material cutting pattern.
In the same manner as the step, it is located to the left of the diagonal line to the right where the arbitrary material cutting pattern is located, and to the left of the diagonal line to the right where this material cutting pattern is located. The other material cutting pattern is defined as a fifth step which is defined so as to be located on the left side with respect to the arbitrary material cutting pattern, and above the diagonal line descending to the right where the arbitrary material cutting pattern is located. And, the other material cutting pattern located above the diagonal line to the right where this material cutting pattern is located is defined so as to be located above the arbitrary material cutting pattern. In the same manner as the process, the material cutting pattern is below the diagonal line to the right where the arbitrary material cutting pattern is located, and The seventh step of defining the other material cutting pattern located below the diagonal line rising to the right and located below the arbitrary material cutting pattern; Repeating the four steps from step 7 to step 7 with another material cutting pattern, the eighth step to determine the vertical or horizontal relationship between all material cutting patterns, and either the left or right side of the vertical baseline Side, and the vertical baseline side of the material cutting pattern that does not have another material cutting pattern on the vertical baseline side is positioned at the vertical baseline, the ninth step, and one of the upper and lower sides is the horizontal baseline side. The 10th step of positioning the side of the material cutting pattern on the horizontal baseline side that does not have another material cutting pattern on the horizontal baseline side on the horizontal baseline, and the element positioned on the vertical baseline. For the cutout pattern, based on the definitions of the 4th and 5th steps above, for the 11th step of packing other material cutout patterns on the vertical baseline side so that they do not overlap, and for the material cutout pattern located on the horizontal baseline Then, based on the definitions of the sixth step and the seventh step, the twelfth step of filling the other material cutting patterns on the horizontal base line side so as not to overlap, and the material cutting arranged by the eleventh step and the twelfth step. A method of cutting out a material, comprising: a thirteenth step of cutting out the material based on a pattern. 6. The material cutting method according to claim 5, wherein the arrangement of the material cutting pattern in the third step is changed, and the steps from the fourth step to the twelfth step are repeated again.