JPH06202721A - Numerical control information generating device - Google Patents

Abstract

PURPOSE:To enable even an unskilled operator to easily generate NC information by displaying selectable element shapes and numerical values corresponding to them on a display picture and using element shapes, which correspond to numerical information inputted from a numerical input device, for generation of numerical control information. CONSTITUTION:A numerical control information generating device is provided with a keyboard 1 for information input, and it is provided with keys for figures, four operations in arithmetic, the comma, parentheses, etc. A symbol keyboard 2 is provided with not only symbol keys for expression of graphics described on a design drawing but also an IN key for data storage in a memory, etc. A work indicating keyboard 3 is provided with a work feed key, etc. A column where the item name of input data will be entered is provided in the upper part of a graphic display screen of a CRT, and a column where inputted data and graphics are preset to be displayed is provided in the center. An input information display column through which the operator exchanges information with this device is provided in the lowest stage.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a numerical control information generating apparatus, and more particularly to a numerical control information generating apparatus capable of generating numerical control information without undergoing advanced training.

[0002]

2. Description of the Related Art A drawing of a work piece is given, and in order for a machine tool using a numerical control device (hereinafter abbreviated as an NC device) to cut the work piece according to the drawing, various kinds of data can be input to the NC device. NC machining information is required, but it is a very important issue for improving the productivity of NC machine tools that anyone can easily and quickly create such NC machining information. Normally, the processing information of the NC machine tool is pre-punched on a paper tape called NC tape. NC tapes are either manually calculated or made using an electronic calculator. In the former method, for example, in the case of numerical control of contour control, if it is a simple two-dimensional shape, the drawing is first divided into blocks of line segments and arcs, and various information is line by line for each block. Create a process sheet by putting it together in the table and tap the key of the puncher to make an NC tape according to this process sheet. The latter creation method uses an input language for automatic programming, creates a part program for each workpiece, inputs this to a computer NC information creation device using an appropriate medium, and based on this input data, NC The information creation device automatically creates the NC tape.

[0003]

Even if NC machining information is obtained by manual calculation and an NC tape is produced, or an NC tape is produced by an automatic programming method by describing a machining procedure in an input language, NC machining is performed at a factory. Creating an NC tape is not so easy because not only does the person operating the machine have to learn new things, but also it takes a lot of work to create a process sheet or a part program. Therefore, there is a strong demand for an NC processing procedure input method and processing method that can be easily and quickly and accurately done by anyone, but such a new method has not yet been realized.

Accordingly, one object of the present invention is NC
An object of the present invention is to provide a device that allows even an unskilled person to easily create information.

Another object of the present invention is to provide an apparatus capable of easily creating NC information without using a special language for NC information.

Another object of the present invention is to provide an NC tape producing apparatus capable of producing NC information faster than ever before.

[0007]

To achieve the above object, according to the present invention, a graphic display device capable of displaying characters, symbols and graphics and a data input device capable of inputting at least numerical values and graphic symbols are provided. It has a device for creating numerical control information, displays selectable material shapes and corresponding numerical values on the display screen, and creates the numerical control information for the material shape corresponding to the numerical information input from the numerical input device. A numerical control information creation device for use is provided. Further, according to the present invention, a graphic display device capable of displaying characters, symbols, and graphics and a data input device capable of inputting at least numerical values and graphic symbols are provided, and a device for creating numerical control information is provided.
The contour of the machined part is drawn in the contour of the material shape drawn on the display screen, and when machining the part, the contour of the machined part and the contour of the material shape are divided by line segments along the boundaries of multiple machining areas. Provided is a numerical control information creation device which is used to input information and create numerical control information. Further, according to the present invention, a graphic display device capable of displaying characters, symbols, and graphics, a data input device capable of inputting at least numerical values and graphic symbols, and a device for creating numerical control information are provided on a display screen of the graphic display device. There is provided a numerical control information creating device for displaying a figure showing a working area and data items necessary for calculation of a working process and sequentially inputting the data using a data input device to create numerical control information.

[0008]

EXAMPLES The present invention will be clarified. First, when NC processing data is created using the apparatus of the present invention, NC data necessary for processing is divided into the following main items, and each of these main items is divided. In accordance with a certain rule, processing data is input to the NC information creating apparatus, and based on these input data, predetermined arithmetic operations and editing operations are performed in the NC information creating apparatus to create an NC tape.

Main Item (1) Selection of Coordinate System This shows in which quadrant from the first quadrant to the fourth quadrant the object to be projected, that is, the processed article, is projected, that is, the design drawing is First angle method Shows whether or not it is expressed by the third angle method and inputs this data. (2) Input of figure This specifies the outline of the processed article expressed in the design drawing with a drawing symbol or the like, and inputs this data.

(3) Input of material shape and size This is to input the data of the shape of the material used for processing and the size of the main part. (4) Input of component dimensions Input the data of the finished dimensions of each part of the processed article.

(5) Designation of rough machining area When cutting a workpiece from a material by cutting, rough cutting is performed from the surface of the material to a certain area for cutting the machining time and the like, but the data of the area to be rough cut Enter. If there are a plurality of regions to be rough cut due to the relationship between the material, the shape of the workpiece, and the shape of the tool used, the respective data for these regions are input.

(6) Designation of machining origin At the start of machining, it is necessary to decide where to start the tool. It is necessary to determine the machining origin position as the start position of this tool. Therefore, the machining origin position is set in advance and this data is input. (7) Selection of tools to be used When one machine tool has multiple tools such as a turret lathe and a machining center, various tools must be selected according to the machining part and the tools suitable for each machining location must be used. I won't. Therefore, depending on the workpiece,
The data as to what kind of tool is used and in what order is important in the machining process, so these data are input.

(8) Designation of tool information to be used In addition to the unique shape and size of each tool used for cutting, when these tools are mounted on a tool holder or holder, from the tool mounting center point to the cutting edge. There are various kinds of tool information such as the distance, and unless these pieces of information are given for each tool to be used, the actual machining information cannot be obtained. Therefore, it is necessary to input these data.

(9) Designation of Machining Steps Various machining such as surface roughing, inner surface roughing, drilling, surface finishing, and thread cutting are performed before one part is cut out from a raw material to obtain a finished product. Therefore, it is necessary to input information about what kind of processing is performed in which part for all the parts. (10) Processing of Machining Process After designating a machining process, information necessary for processing of the machining process is added, and a tool path is calculated from these information.
Therefore, in the present invention, various processing data in all processing steps are input.

The method of inputting data does not use any special language for programming as in the conventional method, and the terms and figures that can be deciphered by an engineer who can write or understand a design drawing are displayed on the display surface. In addition, it prompts for necessary data input using commonly used character symbols, whereas the operator uses the normal numbers, characters, and symbols to generate the necessary data numerical control information creation device (hereinafter abbreviated as this device).
To enter. The inquiry and the response to the inquiry are performed for each of the above-mentioned main items and in a fixed order within each of the main items. However, if the operator finishes inputting one information and presses a button for proceeding the process. , These progressions will definitely take place in a certain order.

When all the data regarding the parts machining are input, the NC information for forming the parts according to the given design drawing is created in the present apparatus based on the input data. If the result of the tool path calculation process is sent to the interpolating device, the present invention becomes a numerical control information creation device that can be placed in the numerical controller, and the result of the tool path calculation process is a paper tape in the NC tape format. If you punch in the NC tape automatic creation device or NC
It becomes a numerical control information device creation device that can be placed in an automatic programming device.

FIG. 1 is a perspective view showing a numerical control information generating apparatus, and a keyboard portion for inputting information is provided in the lower part. Reference numeral 1 is an input keyboard. As shown in FIG. 2, the input keyboard 1 is provided with numbers, addition / subtraction / multiplication / division
Keys such as commas and parentheses are provided. 2 is a symbol keyboard. As shown in FIG. 3, the symbol keyboard 2 is provided with not only symbol keys used for expressing the figures shown on the design drawing but also an IN key for storing data in the memory. Reference numeral 3 denotes a work instruction keyboard, which is provided with work feed keys and the like as shown in FIG. Reference numeral 4 is a graphic display screen using a CRT.
At the top of the graphic display screen 4, there is a field for describing the item name of the input data, and at the center is a field for indicating the input data or graphic or for calling and displaying preset data. In addition, an input information display column is provided at the bottom of the table so that the operator can exchange information with this device. In Fig. 1, 5 is a bubble punching machine
A terminal for sending data to an NC information output device such as a cassette or a cassette magnetic tape, and 6 is a terminal for sending data to an NC interpolator.

By using the apparatus as described above, not only a normal engineer can easily and accurately make an NC tape without using a special language, but the production time is faster than before. effective.

A device for inputting data into this device generally uses a keyboard as described above, but it is also possible to input data using a data input device using a land tablet, A voice input device may be used instead. In this case, figure input is much easier than with a keyboard. A keyboard may be used to input data such as numerical values, and a land tablet or a voice input device may be used to input only graphics.

In order to facilitate understanding of the present invention, the apparatus of the present invention will be described below by taking an example of creating numerical control information regarding turning.

(1) Selection of coordinate shape When the "start" work instruction key of the work instruction keyboard shown in FIG. 4 is pressed, the coordinate display is selected on the graphic display screen 4 of FIG. 1 as shown in FIG. Is displayed.
In the case of turning, depending on how to write the design drawing, the first quadrant,
Since it is described in any one of the four types of coordinate forms of the second quadrant, the third quadrant, and the fourth quadrant, the graphic display screen 4 shows a diagram showing each coordinate system and the corresponding quadrant. The numbers 1, 2, 3 and 4 are attached and displayed. Further, any one of the coordinate system numbers 1, 2, 3, and 4 set (preset) as the initial value is displayed in the “Genza Inou Houkei:-” column. Further, an input information display column 51 is provided at the bottom,
“Zayoyokei =” is displayed and waits for input from the operator. The operator uses the 1 and IN keys or 2 on the input keyboard and the symbol keyboard for inputting the numerical values shown in FIGS.
By pressing the and IN keys or the 3 and IN keys or the 4 and IN keys, the data indicating in which quadrant the drawing drawn on the design drawing is drawn is input to the apparatus. The coordinate system corresponding to the device input by this operation will be used throughout the subsequent data processing. When the preset value is used as it is, it is only necessary to press the IN key.

When the coordinate system selecting operation is completed in this way, the latest coordinate system number selected by the above-mentioned operation and input to this device is displayed in the "Genza Inosa Hiyokei" column. become.

Instead of listing the display screens, it is also possible to display one coordinate system one by one, inquire about whether the coordinate system is selected, and select one of them.

When all the information necessary for selecting the coordinate system has been input, the next operation is performed. (2) Input of Graphic Next, on the graphic display screen 4, the contents corresponding to the graphic input are displayed as shown in FIG. That is, "Buhin Keijo", which means the task of inputting information on the figure, is displayed at the top. The number of figures that can be entered is not limited to one, but the shapes of multiple parts can be entered and the information can be stored in memory, so the code numbers and shapes corresponding to each part are symbolized in the next column. The indicated display portion (referred to as a registered figure display field 63) appears on several lines to several tens lines, and the code number selected from the above code numbers and the corresponding symbol are displayed one line above the bottom column. There is a column in which a graphic is displayed (referred to as a selection information display column 62), and an input information display column 61 is provided at the bottom.
Is displayed.

When no information regarding the shape of a part is entered in the storage device of the present apparatus, the code numbers are simply sequentially added from 001 for each line, and "code =" is displayed in the input information display field 61. Only there.

In such a state, for example, when a figure on the design drawing as shown in FIG. 7 is input to the code field 001, first the input key shown in FIG. 2 is pressed 0, 0, 1 to enter the code. As a result, 001 appears in the input information display field 61, and subsequently, when the symbol key IN shown in FIG. 3 is pressed, the designation information of the code number 001 is input to the apparatus, and the selection information display field 62 in FIG. Simultaneously with the display of "001 =", the input information display field 61 switches to the display of "Keiyo =", and the operator is prompted to input a machining shape request key from the shape symbol input keyboard. Here, the operator corresponds to the straight line 7.1 while looking at the figure shown in FIG.
A key ↓ corresponding to the straight line 7.2, a key corresponding to the straight line 7.3 → a key C corresponding to the chamfering section 7.4, a key ↓ corresponding to the straight line 7.5, a key corresponding to the small arc 7.6 R, straight line 7
When the key ← corresponding to 7 and the key ↓ corresponding to the straight line 7/8 and the key ← corresponding to the straight line 7 and 9 are pressed one after another, the input information display field 61 shows → ↓ → C ↓ as shown in FIG. R ← ↓
← is displayed one after another. Finally, when the symbol key IN is pressed, the graphic symbol information is input to the storage device of this device, and "→ ↓ → C ↓ R ← ↓ ←" is displayed in the code No. 001 column of the illustrated display screen 4. Code number 001
The figure shown in FIG. 7 is registered. At the same time, “→ ↓ → C ↓ R ← ↓ ←” is displayed after “001 =” in the selection information display field 62. Then, the shape displayed in the selection information display field 62 is selected as the current processed shape.

If there are other figures that still need to be input, the above-mentioned operation is repeated to register various figures as shown in FIG. 9, for example. Since the registered graphic information is not erased until it is rewritten, the graphic that appears every time an NC tape is created is not deleted when a new NC tape is created, and is registered in the storage device of this device. It is good to do it.

A case where the graphic information registered in this apparatus is taken out and reused as input information will be described.

In each code number column of the registered figure display column, a set of symbols (shape code) corresponding to the code number and representing the registered figure is displayed and menu-formed. Then, a set of symbols representing a desired graphic to which a graphic is to be input is searched for in each of the fields. When the set of symbols representing the desired graphic is found, the code number is pressed with the input keys shown in FIG. For example, as described above, when the figure registered in the code number 001 is desired to be called, if the input keys 0, 0, 1 are pressed one after another, the code number "001" is displayed in the input information display field 61 as shown in FIG. Will be displayed, and the display of “Code =” will change to “Keiyo =”. At the same time, the selection information display field 62 displays “001 =
→ ↓ → C ↓ R ← ↓ ← ”is displayed. Then, the symbol appearing in this column and the shape of the part drawn on the design drawing are checked, and if there is no error, the IN of the symbol key is pressed. By this operation, the graphic information read in the selection information display field 62 is used as the current machining shape. If you want to call the already registered figure and check its shape and change its contents, press the symbol key of the new shape when "Keiyo =" is displayed in the input information display field 61 in the above operation, and Press IN on the code number "0
The registration contents of "01" are changed and the contents of the selection information display field 62 are also changed. Then, the input information display field 61 displays “code =
Is displayed. After that, when another registered graphic information is changed, the above-described operation is continuously performed.

As shown in FIG. 6, if the code number is three digits and the capacity of the storage device permits, the registration of figures is possible up to 999. If there are 999 items, they cannot be displayed on one screen at all, so either provide a page turning key on the work instruction keyboard or display the page containing the code number when the code number is entered in the input information display field 61. Alternatively, the codes are sequentially sent so that the registration code and the figure code are displayed one after another, and it is possible to search for many codes and figures by using this.

In the above embodiment, the shape and direction of the line segment forming the outline of the figure is displayed by an arrow or a character, but it is actually stored in the storage device by a number and a character. To display this on the graphic display screen 4, use a generator that converts numbers into arrow symbols.
It is displayed with an arrow so that it is easy to see. If the generator is expensive, a table in which arrow symbols are associated with numbers is used as shown in FIG. You don't need a generator, and you don't need a keyboard for drawing figures.

FIG. 11 shows a comparison between the shape code corresponding to the code number represented by numbers and letters and the shape element symbol such as, for example, and corresponds to each shape code for reference. An example of the contour of a part is shown. Moreover, FIG.
2 shows an example in which the shape code corresponding to the code number and the shape code expressed by using the shape element symbol are additionally displayed and displayed on the graphic display screen 4.

Depending on the type of parts to be processed, it is often the case that additional parts such as flanges and bosses are added to a certain basic body shape. In such a case, in the present invention, the shape code of the basic body shape that has already been registered can be added with the shape code of the accessory portion that has already been registered.

[Code =] is displayed in the input information display field 61.
Is displayed. And using the input keyboard,
Specify the code number of the new shape, for example "003", and then IN
Press the key. By this operation, the input information display field 61
Changes to the display of "Keijo =". Then, for example, as shown in FIG. 13, when synthesizing a new shape code in which the accessory shape indicated by the code number “002” is added to the shape indicated by the code number “001”, the input keyboard 1 is When pressing "001 + 002" and pressing the symbol key IN, the shape code or shape element symbol group as shown by the code number "003" in FIG. 13 is input, and the shape is the shape as shown at the right end of FIG. Becomes Such an operation is not limited to the addition of two code numbers, and an addition operation of a plurality of code numbers of three or more is also possible. When all the information necessary for inputting the figure has been input, the next operation is performed.

(3) Input of Material Shape and Size Next, the graphic display screen 4 displays the contents corresponding to the input of the material size as shown in FIG. That is, "Soseisunpou", which means the work of inputting information on the shape and size of the material, is displayed at the top. The material shapes for turning are roughly classified into those with a round bar, with holes, or special shapes. Therefore, the shapes of those materials and the shape numbers 1, 2, and 3 corresponding to them are displayed on the graphic display screen 4. Indicated dimension portions (diameter dimension and length dimension) are indicated by D, D ₀ , and L on each material shape. In the graphic displayed on the graphic display screen 4, the alternate long and short dash line represents the center of rotation. Also, if the shapes and dimensions of some of the materials used in the factory are standardized, it is troublesome to input those shapes and dimensions each time the NC tape is created, so register the initial values. A portion (setting value display portion) 142 that displays the initial values of the already-registered shapes and dimensions so that this can be used as it is.
Is provided on the right side of the graphic display screen 4. Drawing display screen 4
An input information display field 141 is provided at the bottom end of the field, and the inquiry text in this field is displayed as “Sozai type =”.

The operator looks at the graphic display screen 4 and selects the number suitable for the material used by himself / herself.
Numerical values shown in are input from the input keyboard, and then the symbol key IN is pressed to input information. For example, if the material is a round bar, the operator continuously presses 1 and IN, and if the material is a round bar with a hole, continuously presses 2 and IN. If the material is No. 3, 3 and IN are continuously pressed to input the desired material shape into the apparatus. For example, when a round bar with a hole is selected, “Anatsuki Marubow” is displayed on the certified value display portion 142.

When the input of the material shape is completed, the inquiry message in the input information display field 141 changes to "L =", so the operator presses the key of the input keyboard for the numerical value of the material length,
Then, when IN is pressed, the length information is input to the apparatus, the length is displayed on the set value display section 142, and the inquiry text in the input information display field 141 changes to “D =”. The operator inputs the outer diameter of the material. When the operator presses a key on the keyboard and presses IN, the outer diameter information is input to the apparatus, the outer diameter is displayed on the set value display section 142, and the input information display field 141 is displayed. Is changed to "D ₀ =". The operator inputs the inner diameter of the material. Press the key on the keyboard and press IN to input the inner diameter information into this device.
The inner diameter is displayed on the certified value display portion 142, the material size information input operation is completed, and the next operation is performed. If a special material is selected as the material type (when 3 and IN are pressed), the material length and outer diameter information is entered, and then the special material shape information is entered as described above. It is performed in the same way as when inputting the figure of the part, and the dimension of each part is also input, but since the input method is the same as the method of inputting the part dimension described in detail later, it will be explained in detail in that part. To do.

(4) Input of part dimensions When the operation of inputting the shape / dimension information of the material is completed, as shown in FIG. 15, the material shape selected in the already selected coordinate system is displayed on the graphic display screen 4. Is displayed in a dotted line on the portion 153 in a size adapted to the dimension, and the corners are respectively labeled with symbols B1 to B4. In the example shown in FIG. 15, the coordinate system of the first quadrant is used and the material is a round bar with a hole. Further, the shape element symbol group of the machined part which has already been input is also displayed in the portion 152. Then, the operator is queried at the lowermost portion 151 of the graphic display screen 4 about the dimensions of the necessary processed parts, and the operator inputs dimensional values from the input keyboard shown in FIG. 3 in response to the questions.
The question of the required size displayed on the bottom part 151 is
The order of inputting the shape element symbols of the processed parts, that is, the shape elements on the left side of the portion 152, is performed in order. When the operator fills in the required dimensions, the device decodes it and sequentially draws the contour of the machined shape. For example, referring to the shape element symbol → displayed at the left end of the portion 152 in FIG. 15, the lowermost portion 151 is queried “D =”, and in response, “D = 50” is input as shown in FIG. Then, the straight line "a" of "x = 50" is immediately drawn, and the serial number "1" is added to the starting point. This serial number will be used later to indicate which point in the processed shape.
Next, moving to an inquiry about the length of the drawn straight line segment a, at this time, the lowermost part 151 becomes an inquiry of "L =". On the other hand, the operator inputs the dimension value. For example, type 20 from the numeric input keyboard,
If you press the IN key on the symbol keyboard, the line segment a will be 20
Becomes a line segment corresponding to, and a serial number of 2 is added to the end point, the dimension input process to the apparatus regarding the first shape symbol element → ends, and the symbol → at the left end from the graphic display screen 4 disappears.

Next, the process for the shape element symbol ↓ is performed, which is exactly the same as the above for the direction and length for the line segment b. That is, the shape to be processed next is ↓, and a straight line b directed downward from the serial number 2 is drawn on the graphic display screen 4 by this information, as shown in FIG. Inquiry about the length of the drawn straight line “D =”
On the other hand, the operator inputs the dimension value from the input keyboard for inputting the numerical value. For example, when 40 is pressed and IN of the symbol keyboard is pressed, the line segment b becomes a line segment whose end point diameter is 40 as shown in FIG. 18, the end point serial number 3 is added, and the shape element symbol ↓ The dimension input process to the present device regarding the above is finished, and the shape element symbol ↓ disappears from the graphic display screen 4. A straight line c extending from the end point of the line segment b to the right side is drawn as shown in FIG. 18 and the length of the line segment c ′ is determined as shown in FIG. By repeating the above-described operations, the data relating to the part shape drawing in which the dimensions similar to those of the part drawing shown in FIG. 7 are added is processed, and the data is displayed on the graphic display screen 4. A figure as shown in FIG. 20 is drawn, and the input of information on the component dimensions to this device is completed.

When entering a dimension, for example, length 100
mm is divided into 30 mm and 70 mm parts and these 30
mm data and 70 mm data is input, and when the 30 mm data is not described in the design drawing, the key of the input keyboard is continuously pressed as "100-70 =", and the IN key of the symbol keyboard is pressed. When is pressed, data of 30 mm is input to this device. In addition, the four arithmetic operations of addition / subtraction / multiplication / division can be similarly performed to input data.

(5) Designation of rough machining area When the operation of inputting the information of the partial dimension is completed, as shown in FIG.
“Nobunkatsu” is displayed.

In the case of turning processing, the processing area differs depending on the type of processing such as cutting the outer diameter of the material, cutting the inner diameter, or end face processing. Therefore, it is necessary to determine the processing area according to the processing purpose.

When machining the shape of FIG. 20 which has already been input, to divide into three machining regions of the outer diameter machining region S, the inner diameter machining region T and the end face machining region L as shown in FIG. When the person presses the B, 5 =, 5, ↑ and IN keys one after another from the input keyboard for inputting numerical values and the symbol keyboard for inputting shape elements in FIG. 3 and FIG. 5, the device is already drawn on the graphic display screen. In the contour shape of the processed workpiece, a dotted line V is drawn upward from the point number 5, and the intersection of the dotted lines B ₁ and B ₂ is B ₅ . Similarly, when the operator presses the B, 6, =, 6, ↓ and IN keys one after another, the dotted line VW is drawn downward from the point of the number 6, and the dotted lines B ₃ , B ₄ Let the intersection be B ₆ . By newly providing the points B ₅ and B ₆ in this way, the area is divided into the outer diameter processing area S, the inner diameter processing area T, and the end surface processing area L, and at the same time, this information is input to this apparatus. .

Further, when dividing the machining area, the operator first presses the B, 5, =, 4, and IN keys one after another instead of the above operation, and then B, 6, =, 5 , And IN keys are pressed one after another, points B ₅ and B ₆ are obtained as shown in FIG. 22, and another processing area can be designated.

By using the method as described above, the operator can freely designate the machining area, and when all the information necessary for designating the rough machining area is input, the operation shifts to the next operation. .

(6) Designation of Processing Origin Next, as shown in FIG. 23, the graphic display screen 4 displays the contents corresponding to the instruction of the processing origin. In other words, the top row is "Kako Genten" which means the instruction of the processing origin.
Is displayed. Then, in the center of the screen, the work 23.1 and the tool 23.2 are drawn in the selected coordinate system, and the input information display field 23.3 at the bottom shows "Kako Genten (X
₀ ) = ”is displayed, and the operator is requested to input the value of the coordinate value X ₀ of the processing origin. In response to the inquiry, when the operator inputs a value of X ₀ from an input keyboard for inputting a numerical value and inputs IN from a symbolic keyboard for inputting a shape element, this value is input to this device and the input information display field 23. 3 displays "Kako Genten (Z ₀ ) =", and prompts the operator to input the value of Z ₀ . Then, the operator inputs Z ₀ into the apparatus by the same operation as the input operation of the value of X ₀ .

The machining origin position data which has already been registered is displayed in the input information display field 23.4, and if it is desired to use it, the IN of the symbol keyboard is displayed in response to the inquiry.
All you have to do is press.

When all the information necessary for designating the machining origin has been input, the operation moves to the next operation.

(7) Selection of Tool to be Used Next, on the graphic display screen 4, as shown in FIG. 24, the contents relating to the selection of the tool to be used are displayed. In other words, “Kogyu Yuryu” is displayed at the top, and then a list of tool types is displayed as a menu that the operator can select while looking at the screen. When the operator selects a tool to be used, each tool type is given a tool type number so that the operation is easy. Then, “NO =” is displayed in the input information display field 24.1 to prompt the operator to perform the tool type selection operation. In response to the inquiry, when the operator inputs the tool type number with the input keyboard for inputting a numerical value and presses IN with the symbol keyboard for inputting the shape, the information of the selected tool is input into the present device, and the next processing is performed. Moved to operation.

(8) Designation of tool information to be used Next, as shown in FIG. 25, the graphic display screen 4 displays the contents relating to the designation of the tool information to be used. That is, in the uppermost row, a heading of tool information used, such as “Gaikai Sakusaku Koujouhou”, is displayed, and items for specifying the tool, numerical values and figures are displayed. For example, in the tool selection operation, the operator selects a tool for outer diameter cutting in FIG.
NO. Suppose that you have selected the tool “Guy Kei Setsusaku” of No. 2. Based on the input information, the items necessary for the outer diameter cutting tool information, the preset values and the bite shape for easy understanding are displayed on the screen on the graphic display screen as described above. Then, the required data is inquired in the input information display field 25.1 at the bottom of the screen 4, and the operator inputs numerical values one after another in response to the inquiry. In other words, in the input information display field 25.1, "Kougbangou =
In response to the inquiry displayed as “”, the tool number, for example, the tool number “01” is input. The input method is performed by inputting a number using the numeric input keys of the input keyboard and typing the IN key.

By inputting this information, 01 is displayed in the "Koubangou" column of the screen, and the question in the input information display column 25.1 is changed to "Hasakiichi X:". In response to this inquiry, the X method drawn on the right side of the screen is input to this apparatus by the numerical input keys of the input keyboard and the IN key. By this input operation, the value of the blade tip position X is displayed on the screen. Similarly, the tool information is sequentially input to this apparatus in response to the questions in the input information column. If you want to use the preset value for the inquiry, just press the IN key.

When machining one part, not only one tool is used. Generally, several tools are used. When all the necessary data have been input for one tool as described above, the process returns to the screen of FIG. 24 to select the type of tool to be used again. Then, the operation of selecting a tool to be used and inputting necessary information for the tool is repeated as many times as the number of tools to be used. When the input of all the tool information is completed and the display screen 4 returns to the display shown in FIG. 24, the 0 key and the IN key indicating the end are pressed. This operation shifts to the next operation.

(9) Designation of Machining Process and Processing of Machining Process When all the tool information required by the operator is input, the display of the graphic display screen 4 is as shown in FIG. Is changed to. That is, "Kako Tape" is displayed at the top, and then a menu showing the processing details is displayed. Further, when the operator selects a processing step, the processing contents are numbered so as to simplify the operation. Then, in the input information display field 26.1 at the bottom of the screen, "NO =" is displayed in order to prompt the operator to select the machining process. The operator taps the required processing number and the IN key. For example, when the user presses the 3 key and the IN key to select "outer diameter rough machining", the present apparatus starts the process of automatically creating NC information, and the contents of the graphic display screen 4 are shown in FIG. As described above, the contents are changed to the outer diameter rough machining.

According to the process described so far, this apparatus has the material shape and dimensions necessary for creating the NC information, the machining shape and dimensions, the rough machining area, the type and dimension of the tool used, and the coordinate value of the machining origin. Has been entered. This device is shown in FIG.
As shown in FIG. 5, the coordinate axis, the material shape, the processed shape,
The rough machining area and the like are displayed by figures, characters and numerical values, the item names of the information necessary for performing the machining selected in FIG. 26 are displayed at the bottom, and the input information display field 27.1 at the bottom shows one after another. Ask the operator for necessary information. As the data often used in each item, it is also possible to use the data set beforehand by the operator without newly inputting the data.

When the operator finishes inputting the necessary information, this apparatus performs a tool path calculation process and draws a tool path as shown in FIG. 28 on the screen. These obtained data are converted into NC data peculiar to the NC machine tool to be used by the processor program and sent to the tape punching machine through the terminal 5 to make an NC tape or to the pulse distributor through the terminal 6. Sent, N
C Control the machine tool directly.

When the processing is completed, the apparatus returns the procedure to the machining step selection of FIG. 26, and waits for the numerical value input from the operator to create the next machining information.

(10) Input of Shape / Dimension of Special Material When the special material is selected in the material selecting operation and the input of the information of the length and the outer diameter of the material is completed, the graphic display screen 4 is displayed as shown in FIG. The outer diameter of the special material is drawn with a dotted line in the selected quadrant, as shown in FIG. Then, while watching the shape of the special material in the same way as when inputting the figure of the machined part, if you press the symbol key according to the figure, the part 29.1 column at the bottom of the screen →
→ The shape and code like ↓ ← are displayed. Next, when the IN key is typed, "D" is displayed in the input information display field 29.2.
= "Is asked, and when" D = 55 "is input to it, a straight line of X = 55 is drawn and B ₁ is set at the starting point.
Will be numbered. Next, the question is asked about the length of the drawn straight line segment r. At this time, the input information display field 29.1 asks "L =". On the other hand, when the operator inputs the dimension value 30, the line segment r becomes a line segment corresponding to the length 30, and the end point thereof is numbered B ₂ as shown in FIG. 29. The process related to → ends, and the → symbol at the left end of the graphic display screen 4 disappears. After that, the same input operation is repeated to draw the shape of the special material with a solid line within the dotted line representing the outer diameter dimension of the special material, and the input of the data regarding the shape and the size of the special material is completed.

As described above, the present invention has been described with reference to the embodiment of turning, but other NC machining such as milling and wire cut electric discharge machining can be similarly carried out.

FIG. 30 is a block diagram showing the configuration of the numerical control information creation device. In the figure, 100 is a central processing unit on the main side. The central processing unit 100 processes various kinds of data input from the data input device to process the target NC.
It is provided to create information. 101 is a screen information memory. In the screen information memory 101, for example, as shown in FIG. 5, all screens displayed on the display screen 4 for each item, such as screen information for displaying figures and characters necessary for selecting a coordinate system. Information is stored for each screen. 102 is an input data memory. The input data memory 102 stores various data such as numerical values input for the inquiry displayed on the display screen 4. Reference numeral 104 is a control program memory in which a control program is stored, 105 is a processor dedicated to calculation, 106 is a data bus, and 107 is an address bus.

Reference numeral 200 denotes a central processing unit for controlling data processing on the input / output device side, which is considerably smaller than the central processing unit 100. 201 is an initial program loader,
Reference numeral 202 is a memory in which a control program is stored, and 203 is a cassette tape memory, which stores edited numerical control information and the like. Reference numeral 204 is a display control circuit. The display control circuit 204 includes a character generator, a figure generator for generating a signal of a figure to be actually displayed on the display screen, a screen memory for temporarily storing a figure for one screen, and a character for one screen. It includes a screen memory to store. 205 is a CRT display unit. Reference numeral 206 denotes a printer control circuit, 207 denotes a printer, and the CRT display unit 2
The data displayed on 05 can be printed out if desired. A punching machine 208 has a paper tape reader PTR and a paper tape puncher PTP inside. 209 is an XY plotter. 210 is a data bus and 211 is an address bus.

Reference numeral 300 is a keyboard, and 400 is an interface memory that mediates information between the main side and the input / output side. Reference numeral 500 denotes an NC device and 501 denotes the NC device 5.
A machine tool controlled by 00 and a central processing unit 2
With the control of 00, the NC material stored in the cassette tape memory 203 can be used to control the work material 501.

Although not shown in FIG. 30, in addition to the keyboard 300, a land tablet, an information input device such as a voice input device may be installed in parallel.

As shown in FIG. 1, this device is provided separately from the NC device, but since the shape is relatively small, a book attached to the panel 500 as shown in FIG. The device may be fitted into the front plate of the NC device to form a part of the NC device.

[0064]

According to the present invention as in the above embodiments,
A graphic display device capable of displaying characters, symbols, and graphics, and a data input device capable of inputting at least numerical values and graphic symbols, having a device for creating numerical control information, and having a material shape selectable on the display screen and corresponding thereto Numerical values and are displayed, and the material shape corresponding to the numerical information input from the numerical input device is used to create the numerical control information. It is possible to easily create a numerical control machining program in an interactive manner without using a numerical control language.

[Brief description of drawings]

FIG. 1 is a perspective view showing a numerical control information creation device for carrying out the present invention.

FIG. 2 is a front view of an input keyboard.

FIG. 3 is a front view of the symbol keyboard.

FIG. 4 is a front view of a work instruction keyboard.

FIG. 5 is a graphic diagram that appears on a display screen during data input regarding coordinate selection.

FIG. 6 is a graphic diagram that appears on a display screen while inputting data regarding a part shape.

FIG. 7 is a sectional view showing the shape of a component to be processed.

FIG. 8 is another diagrammatic view that appears on the display screen during data input regarding the part shape.

FIG. 9 is another diagrammatic view appearing on the display screen during data input regarding the part shape.

FIG. 10 is a view showing shape element symbols and numbers corresponding thereto in comparison with each other.

FIG. 11 is a diagram showing a shape code stored in a memory in the numerical control information creation device.

FIG. 12 is still another graphic diagram appearing on the display screen during data input regarding the part shape.

FIG. 13 is a diagram for explaining a process of adding registered figures to each other to create a new registered figure.

FIG. 14 is a graphic diagram that appears on the display screen during data input regarding material dimensions.

FIG. 15 is a process diagram illustrating a process of inputting data regarding dimensions of a processed part.

FIG. 20 is a process diagram illustrating a process of inputting data regarding dimensions of a processed part.

FIG. 21 is a diagram showing a figure appearing on the display screen during data input regarding the processing area.

FIG. 22 is another diagrammatic view that appears on the display screen during data input regarding the processing area.

FIG. 23 is a graphic view that appears on the display screen during data input regarding the processing origin.

FIG. 24 is a graphic view that appears on the display screen during data input regarding selection of a tool type.

FIG. 25 is a graphic view that appears on the display screen during data input for specifying the selected tool.

FIG. 26 is a graphic view that appears on the display screen during data input regarding a machining process.

FIG. 27 is a diagrammatic view appearing on a display screen during data input required for processing of a machining process.

FIG. 28 is a graphic view showing a tool path.

FIG. 29 is a graphic diagram that appears on the display screen during data input regarding the dimensions of the special material.

FIG. 30 is a block diagram showing the configuration of a numerical control information creation device.

FIG. 31 is a perspective view showing another embodiment of the numerical control information creation device.

[Explanation of symbols]

 1 ... Input keyboard 2 ... Symbol keyboard 3 ... Work instruction keyboard 4 ... Display screen 5,6 ... Terminal 100 ... Central processing unit 101 ... Screen information memory 102 ... Input data memory 104 ... Control program memory 105 ... Processor 106 ... Data bus 107 ... address bus 200 ... central processing unit 201 ... initial program loader 202 ... memory 203 ... cassette tape memory 204 ... display control circuit 205 ... CRT 206 ... printer control circuit 207 ... printer 208 ... punching machine 210 ... data bus 211 ... address bus 300 … Keyboard 400… Interface memory 500… Panel

─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] June 24, 1993

[Procedure amendment 4]

[Document name to be amended] Statement

[Name of item to be corrected] Brief description of the drawing

[Correction method] Change

[Correction content]

[Brief description of drawings]

FIG. 1 is a perspective view showing a numerical control information creation device for carrying out the present invention.

FIG. 2 is a front view of an input keyboard.

FIG. 3 is a front view of the symbol keyboard.

FIG. 4 is a front view of a work instruction keyboard.

FIG. 5 is a graphic diagram that appears on a display screen during data input regarding coordinate selection.

FIG. 6 is a graphic diagram that appears on a display screen while inputting data regarding a part shape.

FIG. 7 is a sectional view showing the shape of a component to be processed.

FIG. 8 is another diagrammatic view that appears on the display screen during data input regarding the part shape.

FIG. 9 is another diagrammatic view appearing on the display screen during data input regarding the part shape.

FIG. 10 is a view showing shape element symbols and numbers corresponding thereto in comparison with each other.

FIG. 11 is a diagram showing a shape code stored in a memory in the numerical control information creation device.

FIG. 12 is still another graphic diagram appearing on the display screen during data input regarding the part shape.

FIG. 13 is a diagram for explaining a process of adding registered figures to each other to create a new registered figure.

FIG. 14 is a graphic diagram that appears on the display screen during data input regarding material dimensions.

FIG. 15 is a process diagram illustrating a process of inputting data regarding dimensions of a processed part.

FIG. 16 is a process diagram illustrating a process of inputting data regarding dimensions of a processed part.

FIG. 17 is a process diagram illustrating a process of inputting data regarding dimensions of a processed part.

FIG. 18 is a process diagram illustrating a process of inputting data regarding dimensions of a processed part.

FIG. 19 is a process diagram illustrating a process of inputting data regarding dimensions of a processed part.

FIG. 20 is a process diagram illustrating a process of inputting data regarding dimensions of a processed part.

FIG. 21 is a diagram showing a figure appearing on the display screen during data input regarding the processing area.

FIG. 22 is another diagrammatic view that appears on the display screen during data input regarding the processing area.

FIG. 23 is a graphic view that appears on the display screen during data input regarding the processing origin.

FIG. 24 is a graphic view that appears on the display screen during data input regarding selection of a tool type.

FIG. 25 is a graphic view that appears on the display screen during data input for specifying the selected tool.

FIG. 26 is a graphic view that appears on the display screen during data input regarding a machining process.

FIG. 27 is a diagrammatic view appearing on a display screen during data input required for processing of a machining process.

FIG. 28 is a graphic view showing a tool path.

FIG. 29 is a graphic diagram that appears on the display screen during data input regarding the dimensions of the special material.

FIG. 30 is a block diagram showing the configuration of a numerical control information creation device.

FIG. 31 is a perspective view showing another embodiment of the numerical control information creation device.

[Explanation of Codes] 1 ... Input keyboard 2 ... Symbol keyboard 3 ... Work instruction keyboard 4 ... Display screen 5, 6 ... Terminal 100 ... Central processing unit 101 ... Screen information memory 102 ... Input data memory 104 ... Control program memory 105 ... Processor 106 ... Data bus 107 ... Address bus 200 ... Central processing unit 201 ... Initial program loader 202 ... Memory 203 ... Cassette tape memory 204 ... Display control circuit 205 ... CRT 206 ... Printer control circuit 207 ... Printer 208 ... Punching machine 210 ... Data bus 211 ... Address bus 300 ... Keyboard 400 ... Interface memory 500 ... Panel

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Kunio Tanaka, 3-5 Asahigaoka, Hino-shi, Tokyo 1-5 FANUC CORPORATION Product Development Laboratory (72) Takashi Takegahara 3--5, Asahigaoka, Hino-shi, Tokyo 1 Inside FANUC CORPORATION Product Development Laboratory

Claims (7)

[Claims] 1. A material having a graphic display device capable of displaying characters, symbols, and graphics and a data input device capable of inputting at least numerical values and graphic symbols, having a device for creating numerical control information, and having a material selectable on a display screen. A numerical control information creating apparatus characterized by displaying a shape and a numerical value corresponding thereto and using a material shape corresponding to the numerical information input from the numerical input device for creating numerical control information. 2. A graphic display device capable of displaying characters, symbols and graphics, and a data input device capable of inputting at least numerical values and graphic symbols, having a device for creating numerical control information, and inputting from a shape element symbol key. A numerical control information generation device characterized by recognizing the shape of a special material from the shape element information. 3. A material drawn on a display screen, comprising a graphic display device capable of displaying characters, symbols and graphics, a data input device capable of inputting at least numerical values and graphic symbols, and having a device for creating numerical control information. Draw the contour of the machined part within the contour of the shape, and when machining the part, enter the information that divides the contour of the machined part and the contour of the material shape with a line segment along the boundary of multiple machining areas and perform numerical control. A numerical control information creating device characterized by being used for creating information. 4. A specific point on the contours of the material and the machined part is provided with a code for displaying the position, a machining area is defined by connecting these specific points, and the specific point information is used to create numerical control information. An information creating device characterized by the above. 5. A graphic display device capable of displaying characters, symbols, and graphics, a data input device capable of inputting at least numerical values and graphic symbols, and a device for creating numerical control information, and processing contents on a display screen of the graphic display device. 2. A numerical value according to claim 1, wherein a list consisting of the number and the corresponding number is displayed, and the number of the processing content selected from the list is input from the data input device and used to create the numerical control information. Control information creation device. 6. A graphic display device capable of displaying characters, symbols, and graphics, a data input device capable of inputting at least numerical values and graphic symbols, and a device for creating numerical control information. And a data item required for calculation of a machining process are displayed, and the data is sequentially input using a data input device to be used for creating numerical control information. 7. The numerical control information creation according to claim 6, wherein when the necessary data is input and the calculation of the tool path is completed, the tool path is drawn in the machining area of the graphic display device. apparatus.