JPH08229889A - Panel allocating device - Google Patents

Abstract

PURPOSE: To provide a panel allocating device that can perform panel allocation processing easily in a short time. CONSTITUTION: A first storage part 4 stores data indicating the shape of various panels, and a second storage part 5 stores data indicating the shape of material plates. The numerical data of panels including at least the sorts and number of panels to be cut is inputted to an input part 1. In a main computing part 2, the numerical data of panels is respectively converted into intermediate data indicating the shape of panels on the basis of the data of the first storage part 4, and workhours for cutting the shape, indicated by the intermediate data are computed from the data of the second storage part 5. On the basis of the computed workhours and the priority of cutting machines, the shape indicated by the intermediate data is allocated to the material plates of the second storage part 5 so that the workhours of each cutting machine are equal. An output part 3 outputs the allocated result prepared by the main computing part 2.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a panel allocating device for allocating a panel required for producing a panel.

[0002]

2. Description of the Related Art In the case of producing an outer wall panel of a house as a panel, the outer wall panel is assigned to an outer wall base plate which is a material plate by using, for example, a computer allocating device.
The cutting machine cuts the outer wall panel from the outer wall base plate based on the layout output by the layout device.

On the other hand, the outer wall panel may be composed of only straight lines or may include curved lines. Therefore, a plurality of cutting machines for cutting the outer wall panel from the outer wall base plate are prepared. In this case, for example, when a cutting machine that cuts only a straight line or a cutting machine that can cut a curved line is used, the allocating device sends the allocating result to each line equipped with each cutting machine. Each line cuts the outer wall panel from the outer wall base plate based on the layout received.

Therefore, in order to equalize the load on the line, that is, the work amount, the allocating device considers the constraint condition of the cutting machine. Then, the allocating device calculates the allocation priority by using the evaluation index that the work amount of each line is to be equalized, and allocates from the one having the highest cutting priority. Such an allocating device is disclosed in JP-A-5-35747.

[0005]

By the way, when allocating products, there are restrictions on the equipment and the shape of the products. Therefore, in order to equalize the loads on the lines, the time taken for the products to pass through the line must be taken into consideration. I have to. For this reason, the allocating device has, as data, the working time when the product passes through each line. Then, the allocating device repeatedly calculates the cutting priority based on the work time and the evaluation index described above. As a result, the allocating device requires very complicated processing and time before deciding the allocation.

It is an object of the present invention to provide a panel allocating device which eliminates such drawbacks and which can perform panel allocating processing easily and in a short time.

[0007]

In order to achieve the object, the present invention is to cut a panel of various shapes from a material plate by using a plurality of cutting machines whose work priorities are predetermined. In the panel allocating device for allocating, at least the storage unit for storing the panel shape data indicating the shapes of various panels and the material plate shape data indicating the shape of the material plate, and the type and the number of the panels to be cut. Including the input section for inputting the numerical data of the panel and the numerical data from the input section, based on the panel shape data of the storage section, it is converted into intermediate data indicating the shape of the panel, and the shape indicated by the intermediate data is converted. The work time for cutting is calculated from the material plate shape data in the storage unit, and the work amount of each cutting machine is made equal based on the calculated work time and the priority order of the cutting machines. Comprises a shape indicated by the intermediate data, and the main operation unit to be assigned to the material plate shown material plate shape data storage unit, an output section main operation unit outputs a the assignment result generation.

[0008]

In the present invention, there are various restrictions on the cutting machine for cutting the panel. This restriction includes, for example, cutting only a straight line and cutting a curved line. Based on this constraint, the priorities of the cutting machines are predetermined.

The storage unit stores in advance panel shape data indicating the shapes of various panels and material plate shape data indicating the shape of the material plate.

In this state, when the numerical data of the panel including at least the type and number of panels to be cut is input to the input unit, the main arithmetic unit changes the numerical data of the panel from the input unit to Based on the panel shape data in the storage unit, each is converted into intermediate data indicating the shape of the panel.

After that, the main calculation unit calculates the working time for cutting the shape indicated by the intermediate data from the material plate shape data of the storage unit. Then, the main calculation unit indicates the shape indicated by the intermediate data by the material plate shape data of the storage unit so that the work amount of each cutting machine becomes equal based on the calculated work time and the priority order of the cutting machine. Allocate to the material plate.

The output unit outputs the allocation result created by the main calculation unit. By this allocation, each cutting machine cuts the material plate.

[0013]

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

FIG. 1 is a block diagram showing an embodiment of the present invention. This panel allocating device performs allocation for cutting a housing outer wall panel as a panel from an outer wall base plate which is a material plate.

Further, three cutting machines for cutting the outer wall panel from the outer wall base plate are prepared. Each cutting machine is installed in three lines related to cutting.

The three cutting machines are an X cutting machine, a Y cutting machine and a Z cutting machine.
It is a cutting machine, and these cutting machines have the following restrictions. The X cutting machine is only in the direction of the short side with respect to the outer wall base plate,
Cut the outer wall base plate linearly. The Y cutting machine cuts the outer wall base plate linearly in the short side direction, the long side direction, and the oblique direction with respect to the outer wall base plate. The Z cutting machine cuts the outer wall base plate along a free curve.

As a result, if a curve is included in addition to the straight line,
Must be cut with a Z-cutting machine. If the straight line includes an oblique straight line, it must be cut by a Z-cutting machine or a Y-cutting machine. Any of X, Y, and Z cutting machines may be used if it includes only straight lines parallel to the long and short sides of the outer wall base plate.

The panel allocating device for allocating to these cutting machines includes an input section 1, a main calculation section 2, an output section 3, and a first storage section 4 and a second storage section 5 as storage sections.
With.

The first storage unit 4 stores in advance outer wall panel shape data representing the shape corresponding to the product number of each outer wall panel as panel shape data. Second storage unit 5
Stores in advance outer wall base plate shape data representing the shape of the outer wall base plate as material plate shape data.

The input unit 1 is for inputting order data for a house and the like. The order data input to the input unit 1 is numerical data such as the product number and number of outer wall panels required for a house.

The main calculation unit 2 receives the order data of the product number of the outer wall panel sent from the input unit 1 based on the outer wall panel shape data stored in the first storage unit 4 and then outputs the outer wall intermediate base plate data (intermediate plate). Data). As a result, the product number of the order data is uniquely converted to the outer wall intermediate base plate indicated by the outer wall intermediate base plate data.

After that, the main calculation section 2 allocates the outer wall intermediate plate shown by the outer wall intermediate plate data to the outer wall plate shown by the outer wall plate data. At this time, the main calculation unit 2 calculates the working time when each outer wall intermediate plate passes each line from the outer wall plate shape data stored in the second storage unit 5, respectively. In addition, the main calculation unit 2 determines which of the X, Y, and Z cutting machines is used according to the shape of each outer wall intermediate base plate. Then, the main computing unit 2 sets the outer wall intermediate plate to the outer wall plate of each line so that the calculated work time and the cutting machine to be used equalize the work amount of each line of cutting, for example, the work time. Allocate.

The output unit 3 outputs the allocation result created by the main calculation unit 2 to a display, a printer, a file or the like.

Next, the operation of this embodiment will be described.

The first storage unit 4 stores in advance outer wall panel shape data indicating the shape of the outer wall panel in association with the product number of the outer wall panel. The second storage unit 5 stores in advance outer wall base plate shape data indicating the shapes of various outer wall base plates.

In this state, for example, the product numbers of the four outer wall panels and the required number are input to the input section 1 as order data. When the order data is input, the main calculation unit 2
Converts the part number of the order data into outer wall panel shape data using the first storage unit 4. As a result, the product numbers of the four outer wall panels are the outer wall intermediate base plates 11 to 14 as shown in FIG.
Is converted to. That is, the numerical data of the product number is converted into shape data indicating the shape. The required number of sheets at this time is as follows.

Outer wall intermediate base plate 11: 2 sheets Outer wall intermediate base plate 12: 6 sheets Outer wall intermediate base plate 13: 2 sheets Outer wall intermediate base plate 14: 2 sheets After that, the main calculation unit 2 connects each line to the outer wall intermediate source plate. Plate 11-
The passage time of 14 is calculated by referring to the outer wall base plate data stored in the second storage unit 5.

Further, the following constraint condition, that is, the priority order of the cutting machine, is set in the main arithmetic unit 2.

Priority No. 1 ... Those which can be cut only by the Z cutting machine are cut by the Z cutting machine.

Priority 2 ... If the cutting can only be performed by the Y cutting machine, it is cut by the Y cutting machine.

Priority No. 3 ... What can be cut by the X cutting machine is cut by the X cutting machine.

Then, the main arithmetic unit 2 sets the priority order,
The outer wall intermediate base plates 11 to 11 calculated with reference to the second storage unit 5
The outer wall intermediate base plates 11 to 14 are allocated to the outer wall base plates indicated by the outer wall base plate data of the second storage unit 5 based on the time when 14 passes through each line.

In this allocation, when the abilities of the respective cutting machines are equal, it is desirable that the number of sheets to be cut by the respective cutting machines becomes the same number or a number close thereto, so that the result of the allocation is as shown in FIG. Become. That is, the two outer wall intermediate base plates 14 can be cut only by the Z cutting machine. As a result,
The main calculation unit 2 includes two outer wall base plates 23 that are cut by a Z cutting machine.
Then, the outer wall intermediate base plate 14 is allocated.

The two outer wall intermediate base plates 13 can be cut by both the Y and Z cutting machines. However, since the outer wall intermediate base plate 14 is assigned to the Z cutting machine, the main arithmetic unit 2
Assigns the outer wall intermediate base plate 13 to the two outer wall base plates 22 to be cut by the Y cutting machine.

The two outer wall intermediate base plates 11 can be cut by an X, Y, Z cutting machine. However, the outer wall intermediate base plates 13 and 14 are assigned to the Y and Z cutting machines, respectively.
As a result, the main calculation unit 2 allocates the outer wall intermediate base plate 11 to the two outer wall base plates 21 to be cut by the X cutting machine.

The six outer wall intermediate base plates 12 can be cut by an X, Y, Z cutting machine. Therefore, the main calculation unit 2 allocates the outer wall intermediate base plate 12 to the lower half which is the end allocation portion of the outer wall base plates 21, 22, 23.

The output unit 3 outputs the allocation result of the main calculation unit 2.

Thus, according to this embodiment, X,
Since each of the Y and Z cutting machines has two outer wall base plates to be cut, the load on the cutting machine can be equalized.

In addition, according to this embodiment, the outer wall panel is uniquely converted into the outer wall intermediate plate according to the width, length, pattern, etc. of the outer wall panel, and then the outer wall intermediate plate is taken into consideration while considering the load of each line. Allocate the plate to the outer wall base plate. As a result, since complicated processing is not repeated, the processing can be simplified and the load leveling of the line can be achieved at high speed.

In this embodiment, the outer wall panel for a house is assigned, but the present invention is not limited to this. For example, the invention is as follows: a. Allocation of inner walls of buildings, floors, ceilings, baths, warehouse walls, furniture exteriors, etc. b. Allocation of fabrics and materials such as clothing, ornaments, shoes and umbrellas c. Allocation of printed articles, charts, headings, etc. d. It can be applied to the allocation of manufactured parts and materials.

[0041]

As described above, according to the present invention, when allocating a panel to a material plate, the input numerical data of the panel is converted into intermediate data showing the shape, and thereafter, the cutting machine of each cutting machine is converted. Since the shape indicated by the intermediate data is assigned to the material plate in consideration of the work amount, it is possible to level the load of each cutting machine.

[Brief description of drawings]

FIG. 1 is a block diagram showing one embodiment of the present invention.

FIG. 2 is a diagram showing a shape of an outer wall panel.

FIG. 3 is a diagram showing a state of allocation.

[Explanation of symbols]

 1 Input Section 2 Main Operation Section 3 Output Section 4 First Storage Section 5 Second Storage Section

Claims (1)

[Claims] 1. A panel allocating device for allocating a panel for cutting a panel of various shapes from a material plate by using a plurality of cutting machines whose work priorities are predetermined. Storage unit for storing the panel shape data indicating the shape and the material plate shape data indicating the shape of the material plate, the input unit for inputting the numerical data of the panel including at least the type and the number of the panels to be cut, and the input unit Based on the panel shape data in the storage section, the numerical data from is converted into intermediate data indicating the shape of the panel, and the working time for cutting the shape indicated by the intermediate data is calculated as the material plate shape data in the storage section. Based on the calculated work time and the priority of the cutting machine, the shape indicated by the intermediate data is calculated so that the work amount of each cutting machine becomes equal.
An apparatus for allocating a panel, comprising: a main operation unit for allocating to a material plate indicated by material plate shape data in a storage unit; and an output unit for outputting an allocation result created by the main operation unit.