JP2694639B2 - Numerical control unit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a numerical control device,
The present invention relates to a numerical control device that controls a plurality of controlled axes. [Prior art] Numerical control devices that instruct the position of a tool with respect to a workpiece by numerical information have advantages such as improved productivity, labor saving, and thorough management, and are applied to various machine tools and widely used. Have been. FIG. 2 shows an example of a conventional numerical controller. In this figure, the control unit (50) includes a central processing unit (hereinafter referred to as "CPU") (52), and also a data input / output unit (54) and a signal input / output unit (56). And a display device interface (hereinafter, simply referred to as "display interface") (66). A display device (68) is connected to the display interface (66). The control unit (50) further includes an arithmetic unit (58) and a storage unit (6
0) and the drive unit (62) are connected to each other, and the drive unit (6
2), a servo motor group (64) is connected. Of these, the data input / output unit (54) is for inputting / outputting processing data, particularly a processing program, from / to an external data input / output device (not shown), and the signal input / output unit (56) This is for inputting and outputting control data such as start and stop. Further, the display device (68) displays the current position of the controlled object, the diagnosis result, the alarm, etc., if necessary. In this display device, an input device such as a keyboard is provided as necessary to input programs and data. Next, the storage section (60) is provided with a data area (60A) and a program area (60B). The processing data and the processing program input from the data input / output unit (54) are stored in the data area (60A), and the control data input from the signal input / output unit (56) is stored in the program area (60B). It has become so. Next, the calculation unit (58) performs calculations necessary for controlling the servomotor group (64) and the spindle. For example, when a drive command is given at a vector speed, the decomposition speed in the coordinate axis direction is , An arithmetic process such as interpolation for obtaining a moving distance for a predetermined time is performed. Next, the drive unit (62) corresponds to the fact that the servo motor group (64) is composed of three servo motors, a servo motor (64A), a servo motor (64B), and a servo motor (64C). And three drive circuits (62A), (62B), (62
C). Note that the servo motor group (64) actually corresponds to a servo motor of a three-axis driving portion of a machine tool such as a lathe or a drilling machine. Next, the operation of the above device will be described. Data necessary for performing processing control is input from an external device by a data input / output unit (54) and a signal input / output unit (56). These data are stored in the data area (60A) and the program area (60B) of the storage unit (60) by the control unit (50). Next, the control unit (50) sets the program area storage unit (60
Based on the programs and data stored in B), the calculation unit (58) performs the above-described interpolation and other calculations from the data and programs stored in the data area storage unit (60A), and is necessary for the drive unit (62). Performs various drive commands. As a result, the servo motor group (64) is driven, and required processing is executed according to the input data. Then, during operation, display data is output from the control section (50) to the display device (68) via the display interface (66), and the various displays described above are performed. As described above, the servo motor (64A), the servo motor (64B), and the servo motor (64) of the servo motor group (64)
C) is not driven independently, but is driven as a whole as a whole. [Problems to be Solved by the Invention] By the way, in the above-described conventional numerical control device, the whole is operated by the control program stored in the program area (60B) of the storage unit (60), and the driving unit The servo motor (64A), servo motor (64B), and servo motor (64C) connected to (62) cannot be driven independently. For example, a servo motor (64A) is used for drill movement of a drilling machine, and a servo motor (64B) and a servo motor (64A) are used.
C) cannot be used for lathes. Therefore, it is necessary to provide a numerical controller as shown in FIG. 2 for each machine. Therefore, when numerical control of many machines is performed, a large amount of equipment is required, which is disadvantageous in terms of cost. The present invention has been made in view of the above point, and an object of the present invention is to provide a numerical control device that can numerically control a plurality of machines efficiently and is advantageous in cost. [Means for Solving Problems] According to the present invention, an arithmetic unit performs necessary arithmetic operations based on control data input from a signal input / output unit and a control program and a machining program stored in a storage unit. , In the numerical control device that gives a necessary control command to the drive unit to be controlled by the control unit and also performs the necessary display on the display unit, independently of the data input / output unit that inputs / outputs the machining data and the machining program. A plurality of signal input / output units capable of inputting / outputting control data, a plurality of driving units capable of independently driving a control target, a plurality of control programs capable of being independently executed, and independently A plurality of display units capable of displaying data related to a control target are provided in one numerical control device, and the plurality of signal input / output units, the plurality of drive units, and the plurality of control programs are provided. A system control means for forming a system having an arbitrary number of axes by arbitrarily combining the plurality of display units is provided. [Operation] In the present invention, the data input / output unit, the signal input / output unit, the drive unit, the control program, the display unit, and the system control unit are mainly configured. Here, the signal input / output unit, the drive unit, the control program, and the display unit are each provided in plural in one numerical control device. The signal input / output units can independently input and output control data. The driving units can independently drive the control target. The control programs can be executed independently of each other. The display unit can independently display the controlled object. Further, the system control means forms a system having an arbitrary number of axes by arbitrarily combining the plurality of signal input / output units, drive units, control programs, and display units. That is, in the present invention, a single numerical controller is provided with a plurality of signal input / output units, drive units, control programs, and display units, and each of these units is provided with at least one of the above units by the system control means. They are grouped into systems with an arbitrary number of axes. Therefore, integrated control and display processing is performed for each system having an arbitrary number of axes configured for each group. Here, the control program refers to a program for analyzing and executing a machining program, for example, a program written in a computer language such as C language or assembler language, or a program that can be executed on a CPU. It was done. The machining program is a program for machining the workpiece, and is described in the so-called NC programming language. The calculation unit performs an interpolation calculation between the control targets combined with the system by the system control unit. That is, the calculation unit performs the interpolation calculation between the control targets in an arbitrary group. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 shows an embodiment of a numerical controller according to the present invention. In the figure, a data input / output unit (14) is connected to a control unit (12) including a CPU (10). The data input / output unit (14) corresponds to the data input / output unit (54) in FIG. 2 and exchanges a machining program and other machining data with an external data input / output device (not shown). is there. Here, the machining program to be input is a program for machining a workpiece, and is described in a so-called NC programming language. Next, a signal input / output device (16) is connected to the control unit (12). This signal input / output device (16) has a signal input / output unit (16
A), (16B) and (16C). That is, each of the signal input / output units (16A), (16B), and (16C) has the same function as the signal input / output unit (56) of FIG. The control unit (12) also includes a display interface unit (4
6) is connected. This display interface section (4
6) is capable of inputting / outputting display data independently,
The display interface (46A), (46B), (46C). That is, the display interface (46
Each of A), (46B), and (46C) has the same function as the display interface (66) of FIG. Then, these display interfaces (46A), (46B), (46C) have display sections (48A), (4
8B) and (48C) are connected respectively. Next, an arithmetic unit (18) is connected to the control unit (12). The calculation unit (18) performs the above-described interpolation and other calculations. Next, the storage unit (20) is connected to the control unit (12). This storage section (20) has a program area (20
A), (20B) and (20C). These program areas (20A), (20B), and (20C) store control programs that can operate independently. That is, the control programs stored in the program areas (20A), (20B), and (20C) have the same functions as the programs stored in the program area (60B) in FIG. Can be run independently. Here, the control program is a program for analyzing and executing a machining program, for example, a program written in a computer language such as C language or assembler language, or a format executable on a CPU. It is a thing. Further, the storage section (20) is provided with a data area (20D). Similar to the data area (60A) of FIG. 2, this data area (20D) stores machining data and machining programs, but in addition, the system control means is programmed and stored. Next, the control unit (12) includes the drive units (22), (24),
(26) are connected to each other. These drives (22),
(24) and (26) can operate independently, and the second
Each has the same function as that of the driving section (62) in the figure. However, only one axis can be controlled. Next, servo motors (28), (30), and (32) are connected to the driving units (22), (24), and (26), respectively. The servomotors (28), (30), and (32) are not necessarily of the same machine, but may be of two or more types of machines, and can operate independently. Next, the system control means stored in the data area (20D) will be described. The execution of the system control means is performed by the control unit (12). As shown in FIG. 3, first, refer to the data input from the data input / output unit (14) and the signal input / output unit (16), and the control programs stored in the program areas (20A) to (20C). Then, which control program is to be operated is determined (see steps SA, SB and SC). Next, a control program to be operated and a signal input / output unit (16A) for inputting and outputting control data used for the control program
Or (16C) is determined (see step SD). Next, the correspondence between the control program to be operated and the display units (48A) to (48C) on which the display is performed is determined (see step SE). Further, the correspondence between the control program and the drive units (22) to (26) to be operated is determined (see step SF). In this way, the system control means has the signal input / output sections (16A) to (16C), the program areas (20A) to (20C), the drive sections (22) to (26), according to the contents of the required control operation. It has a function of dividing at least one display section (48A) to (48C) into an arbitrary group having an arbitrary number of axes. Next, the overall operation of the above embodiment will be described by taking various cases as examples. First, referring to FIG. 4, a one-axis machine (34),
A case where (36) and (38) are controlled independently will be described. In the signal input / output section (16A), the machine (34)
Control data D (34) is input / output, and the signal input / output unit (16
In B), the control data D (36) of the machine (36) is input / output, and the control data D (38) of the machine (38) is input / output in the signal input / output unit (16C). Further, the display unit (48A) displays the machine (34), the display unit (48B) displays the machine (36), and the display unit (48C) displays the machine (38). Shall be performed. Then, in the program area (20A) or (20C),
It is assumed that control programs for the machines (34) to (38) are stored respectively. In this case, the signal input / output section (16A), the program area (20A), the display section (48A), and the drive section (22) are systematized by the system control means of the data area (20D) described above. The signal input / output unit (16B), the program area (20B), the display unit (48B), and the drive unit (24) are systematized, and the signal input / output unit (16C) and the program area (20C) are arranged. And the display unit (48C) and the drive unit (26) are systematized. The machines (34) to (38) are based on the control data respectively input from the signal input / output units (16A) to (16C) and the control programs stored in the program areas (20A) to (20C). Are controlled independently. That is, a start operation, a stop operation, and the like are performed independently. At this time, the control unit (12) performs so-called task control. In addition, the necessary display data is input to the display units (48A) to (48C) via the display interfaces (46A) to (46C), and the display processing is executed independently for each system. . As described above, in this example, the entire device functions as three independent numerical control devices. Next, a case where the machine (40) having two servomotors and the machine (42) having one servomotor are controlled independently will be described with reference to FIG. In FIG. 5, the signal input / output unit (16A)
Input / output of control data D (40) corresponding to
It is assumed that the signal input / output unit (16C) inputs / outputs control data D (42) corresponding to the machine (42). The display section (48C) displays and inputs data corresponding to the machine (40), and the display section (48A) displays the machine (4
The data corresponding to 2) shall be displayed and entered. Further, it is assumed that a control program for operating the machine (40) is stored in the program area (20B), and a control program for operating the machine (42) is stored in the program area (20C). In this case, as shown in FIG. 5, the signal input / output unit (16A) is controlled by the system control means of the data area (20D).
, The program area (20B), the display section (48C), the drive sections (22) and (24) are systematized, the signal input / output section (16C), the program area (20C), and the display section ( 48
A) and the drive unit (26) are systematized. The machine (40) is controlled by a control program stored in the program area (20B), and the machine (42) is controlled by a control program stored in the program area (20C). In the control of the machine (40), two servo motors are targeted.
An interpolation operation is performed. As described above, in this example, the whole operates as two independent numerical control devices. Next, still another operation mode of the present embodiment will be described with reference to FIG. The figure shows an example in which the machine (44) has three servomotors. In this case, a signal input / output unit (16B) through which control data D (44) is input / output,
The program area (20
A), a display section (48B) for inputting and displaying data corresponding to the machine (44), and drive sections (22) to (26) are systematized. In this example, the same one-system control as in the apparatus shown in FIG. 2 is performed. Note that the present invention is not limited to the above embodiment. For example, in the above embodiment, up to three independent systems can be constructed. However, two systems may be constructed, or more systems may be constructed. [Effects of the Invention] As described above, according to the present invention, the system control unit includes a plurality of signal input / output units provided in a single numerical control device, a plurality of drive units, and a plurality of different units. Since the control program and the plurality of display units are arbitrarily combined to form a system having an arbitrary number of axes, there is an effect that each of the plurality of units can be efficiently numerically controlled and the cost is also advantageous.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a circuit block diagram showing one embodiment of the present invention, and FIG.
FIG. 1 is a circuit block diagram showing a conventional numerical control device, FIG. 3 is an explanatory diagram for explaining the function of a system control means, and FIGS. 4 to 6 are explanatory diagrams showing an operation mode of the embodiment of FIG. is there. In the figure, (12) is a control unit, (16) is a signal input / output device, (18) is an arithmetic unit, (20) is a storage unit, (20A), (20
(B) and (20C) are the program area, (20D) is the data area, (22), (24) and (26) are the drive units, (28) and (3)
0) and (32) are servomotors, (46) is a display interface unit, and (48) is a display unit group. Note that the same reference numerals in each drawing indicate the same or corresponding parts.

Claims (1)

(57) [Claims] Based on the control data input from the signal input / output unit, the control program and the machining program stored in the storage unit, the arithmetic unit performs the necessary arithmetic operation, and the control unit transmits the control command necessary for the controlled drive unit. In addition to the above, in a numerical control device that performs necessary display on the display unit, a data input / output unit for inputting / outputting machining data and machining programs, and a plurality of signal input / output units that can independently input / output control data A plurality of drive units capable of independently driving the control target, a plurality of control programs each independently executable, and a plurality of display units capable of independently displaying data regarding the control target, It is provided in one numerical control device, and the plurality of signal input / output units, the plurality of driving units, the plurality of control programs, and the plurality of display units are arbitrarily combined and assigned. Numerical control apparatus characterized in that a system control means for forming a number of systems of axes. 2. 2. The numerical control device according to claim 1, wherein the calculation unit performs an interpolation calculation between control targets combined by the system control unit.