Patent Abstract:
A numerical controller which allows easy and inexpensive construction or expansion of a control system and flexible construction of a sequential control section for a variety of system structures. The numerical controller has a numerical control section having multiple control systems. Between the numerical control section and a sequential control section, interfaces are provided for the individual control systems of the numerical control section. The control systems are assigned to the interfaces so that the control systems will be each controlled by an intended one of sequence programs (ladders  1  through  3 ) installed in the sequential control section, under which signals are sent and received independently. The numerical control section and the sequential control section send and receive signals through the interfaces to which the control systems are assigned. By changing the assignment, the control system can be reconstructed freely, without adding a new programmable controller.

Full Description:
BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The present invention relates to a numerical controller having a multiple-system numerical control section for controlling multiple systems of operation and a multiple-system sequential control section. 
   2. Description of Related Art 
   In the conventional numerical controller having a multiple-system numerical control section, sequence control is performed by a single-system sequential control section. When a peripheral device such as a workpiece loader or a pallet changer should be attached to a machine tool using the numerical controller of this type, a programmable logic controller (PLC) for sequence-controlling the peripheral device is added to control it. 
   There is known a numerical controller in which a CNC circuit is provided in a CNC board and a sequence control circuit is provided in the numerical controller itself so that a machine tool or the like is numerically-controlled by the CNC circuit and sequence-controlled by the sequence control circuit receiving miscellaneous function signals (M-function, T-function and the like) from the CNC circuit and/or a signal from a machine. In the numerical controller of this type, when a peripheral device should be added to a system without adding another PLC, another programmable control board (PC board) is added to the numerical controller to sequence-control the peripheral device. In this case, the CNC circuit and the sequence control circuit are originally interfaced. By interfacing the sequence control circuit provided in the numerical controller and the added PC board, all necessary parts of the system including the CNC circuit are interfaced each other (see JP 10-3307A). 
   Upgrading a system by adding a new peripheral device or the like to a numerical controller is increasing to meet a demand for automation at a plant or the like. However, in the conventional method, each time a new peripheral device is added to an existing numerical control system to upgrade it, a programmable logic controller (PLC) or a PC board needs to be added. This makes the structure of the system complicated and increases cost. 
   SUMMARY OF THE INVENTION 
   The invention provides a numerical controller which allows easy and inexpensive construction or expansion of a control system and flexible construction of a sequential control section for a variety of system structures. 
   A numerical controller of the present invention comprises: a numerical control section for numerically-controlling one or more systems; a sequential control section for executing a plurality of sequence programs to independently input and output control signals for the systems of said numerical control section; interfaces respectively provided for the control systems of said numerical control section to communicate said numerical control section and said sequential control section; and assigning means for assigning the systems to be controlled according to the sequence programs of said sequential control section to said interfaces. The numerical control section and the sequential control section perform sending and receiving of the control signals though said interfaces in accordance with the assigned systems. 
   Information on the assignment of the systems to be controlled according to the sequence programs of said sequential control section may be stored in nonvolatile storage means provided in said numerical control section. The sequential control section may control a device not controlled by said numerical control section according to a sequence program to which none of the systems is assigned. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIGS. 1   a  and  1   b  are diagrams for giving an outline of the invention, 
       FIG. 2  is a block diagram showing relevant parts of an embodiment of the invention, 
       FIG. 3  is a table showing the meanings of parameter values assigned to parameters in the embodiment, 
       FIG. 4  is a block diagram showing an example of a control system constructed according to the embodiment, 
       FIG. 5  is a table showing how to assign parameter values to parameter numbers to construct the example of the control system, 
       FIG. 6  is a block diagram showing an example of the control system changed according to the embodiment, 
       FIG. 7  is a table showing how to assign parameter values to parameter numbers when the control system is changed, and 
       FIG. 8  is a block diagram showing an example in which an independent device is controlled by a sequential control section in the embodiment. 
   

   DETAILED DESCRIPTION 
   In  FIG. 1   a,  a numerical control section  10  is so arranged that two control systems  1 ,  2  numerically-control two operation systems of a machine  31 , a control system  3  numerically-controls a workpiece loader  32 , and a control system  4  numerically-controls a peripheral device  33 . A sequential control section (i.e., a programmable machine controller (PMC))  20  has a plurality of sequence programs (ladders) under which signals re sent and received independently. The sequential control section (PMC)  20  executes the sequence programs in parallel. Between the sequential control section  20  and the numerical control section  10 , independent interfaces are provided for the individual control systems of the numerical control section  10 . In the example of  FIG. 1   a,  the interfaces for the control systems  1  and  2  of the numerical control section  10  are assigned to a ladder (sequence program)  1 , the interface for the control system  3  to a ladder  2 , and the interface for the control system  4  to a ladder  3 . 
   In  FIG. 1   b , the system is so changed that the control system  1  of the numerical control section  10  numerically-controls a machine  34 , the control system  2  a peripheral device  35 , the control system  3  a machine  36 , and the control system  4  a peripheral device  37 . Here, the interfaces for the control systems  1  and  3  are assigned to the ladder  1  of the sequential control section (PMC)  20 , and the interfaces for the control systems  2  and  4  to the ladder  2 . 
   Like this, in the present invention, the sequence programs in the sequential control section (PMC)  20  can be assigned to the control systems of the numerical control section  10 , freely, i.e., selectively. 
     FIG. 2  is a block diagram showing relevant parts of a numerical controller according to an embodiment of the invention. To a processor  11  of a numerical control section  10  of the numerical controller, a RAM  12  for storing control software for controlling the numerical control section, a work RAM  13 , a nonvolatile memory formed of RAM, and a shaft control means  15  for controlling servomotors for driving shafts of a to-be-controlled machine are connected by means of a bus  16 . The work RAM  13  has signal tables F for storing signals sent out to the sequential control section (PMC)  20  and signal tables G for storing signals sent from the sequential control section (PMC)  20  to the numerical control section. The signal tables F and signal table G are provided for individual control systems of the numerical control section, and form the interfaces between the individual control systems of the numerical control section and the sequential control section (PMC)  20 . 
   To a processor  21  of the sequential control section  20 , a RAM  22  for storing control software for controlling the sequential control section, a RAM  23  for storing various sequence programs, a work RAM  24 , a signal memory (RAM)  25 , and an input/output device  26  for connection to a machine or a peripheral device are connected by means of a bus  27 . The signal memory (RAM)  25  has signal tables F for storing signals sent from the numerical control section to the sequential control section and signal tables G for storing signals sent from the sequential control section to the numerical control section. The signal tables F and signal tables G are provided for individual control systems of the sequential control section, and form the interfaces between the individual control systems of the sequential control section and the numerical control section  10 . The bus  16  and the bus  27  are connected by a bus  18 . 
   The numerical control section  10  and the sequential control section  20  are interfaced by periodically transferring and updating the signal tables F, G for the individual control systems of the numerical control section  10  provided in the work RAM  13  thereof and the signal tables F, G for the individual control systems of the sequential control section  10  provided in the signal memory thereof. Specifically, the data stored in signal tables F of the numerical control section  10  provided for storing signals sent from the numerical control section to the sequential control section is periodically written in the signal tables F of the sequential control section  20 , while the data stored in signal tables G of the sequential control section  20  provided for storing signals sent from the sequential control section to the numerical control section is periodically written in the signal tables G of the numerical control section  10 . 
   The above-described structure of the numerical controller is the same as that of the conventional numerical controller, except that the signal tables F and signal tables G are provided for the individual control systems. 
   In the present embodiment, parameter values used for assigning the signal tables provided for the individual control systems of the numerical control section to the sequence programs are stored in the nonvolatile memory  14  of the numerical control section  10 .  FIG. 3  shows an example of parameter values. In this example, parameter value “100” means that a signal table for a control system of the numerical control section should be assigned to address F 0 ˜F 767  of the signal table F for the sequence program  1  and address G 0 ˜G 767  of the signal table G for the sequence program  1 . Parameter value “101” means that a signal table for a control system of the numerical control section should be assigned to address F 1000 ˜F 1767  of the signal table F for the sequence program  1  and address G 1000 ˜G 1767  of the signal table G for the sequence program  1 . Parameter value “200” means that a signal table for a control system of the numerical control section should be assigned to address F 0 ˜F 767  of the signal table F for the sequence program  2  and address G 0 ˜G 767  of the signal table G for the sequence program  2 . Parameter value “300” means that a signal table for a control system of the numerical control section should be assigned to address F 0 ˜F 767  of the signal table F for the sequence program  3  and address G 0 ˜G 767  of the signal table G for the sequence program  3 . Like this, each parameter value is connected with a combination of a sequence program number and an address of a block of a signal table F and an address of a block of a signal table G, as shown in  FIG. 3 . The parameter values may be stored in a manner other than the above-described manner. They may be stored in another nonvolatile memory or a volatile memory (not shown) provided in the numerical controller. 
   First, the case in which a control system shown in  FIG. 4  should be constructed will be described. In the example of control system shown in  FIG. 4 , the numerical controller controls a complex machine  40  having three systems of operation, and two workpiece loaders  41  and  42  for supplying workpieces to the machine  40 . The first, second and third control systems of the numerical control section  10  controls the first (x 1 , z 1 ), second (x 2 , z 2 ), and third (x 3 , z 3 ) operation systems of the complex machine  40 , respectively. The fourth and fifth control systems of the numerical control section  10  controls the loaders  41  and  42 , respectively. 
   Here, as shown in  FIG. 5 , parameter value “100” is assigned to parameter number “5100” and stored in the nonvolatile memory  14 . Parameter value “101” is assigned to parameter number “5101”, parameter value “102” to parameter number “5102”, parameter value “200” to parameter number “5103”, and parameter value “300” to parameter number “5104”, and they are stored in the nonvolatile memory  14 . 
   Parameter number “5100” represents the first control system, “5101” the second, “5102” the third, “5103” the fourth, “5104” the fifth, “5105” the sixth, and so on. In the example of parameter setting shown in  FIG. 5 , parameter value “100” is assigned to parameter number  5100  which represents the first control system. Hence, address F 0 ˜F 767  of the signal table F for the sequence program  1  and address G 0 ˜G 767  of the signal table G for the sequence program  1  are assigned to the first control system of the numerical control section  10 . Likewise, address F 1000 ˜F 1767  of the same signal table F and address G 1000 ˜G 1767  of the same signal table G are assigned to the second control system, and address F 2000 ˜F 2767  of the same signal table F and address G 2000 ˜G 2767  of the same signal table G to the third control system. Further, since parameter value “200” is assigned to parameter number  5103 , address F 0 ˜F 767  of the signal table F for the sequence program  2  and address G 0 ˜G 767  of the signal table G for the sequence program  2  are assigned to the fourth control system. Furthermore, since parameter value “300” is assigned to parameter number  5104 , address F 0 ˜F 767  of the signal table F for the sequence program  3  and address G 0 ˜G 767  of the signal table G for the sequence program  3  are assigned to the fifth control system. 
   Thus, for controlling the operation system  1  of the complex machine  40 , signals are sent and received between the numerical control section  10  and the sequential control section  20  using address F 0 ˜F 767  of the signal table F for the sequence program  1  and address G 0 ˜G 767  of the signal table G for the sequence program  1 . For controlling the operation system  2  of the complex machine  40 , signals are sent and received using address F 1000 ˜F 1767  of the signal table F for the sequence program  1  and address G 1000 ˜G 1767  of the signal table G for the sequence program  1 . Likewise, for controlling the operation system  3  of the complex machine  40 , signals are sent and received using address F 2000 ˜F 2767  of the same signal table F and address G 2000 ˜G 2767  of the same signal table G. For controlling the loader a  41 , signals are sent and received using address F 0 ˜F 767  of the signal table F for the sequence program  2  and address G 0 ˜G 767  of the signal table G for the sequence program  2 . For controlling the loader b  42 , signals are sent and received using address F 0 ˜F 767  of the signal table F for the sequence program  3  and address G 0 ˜G 767  of the signal table G for the sequence program  3 . 
   Next, suppose that the existing system is changed or a new system is constructed so that the numerical controller will control a complex machine  50  having four systems of operation and a loader  42  as shown in  FIG. 6 . When the control systems  1  to  5  of the numerical control section  10  are connected with the machine  50  and the loader  42  as shown in  FIG. 6 , parameter setting for interfacing the numerical control section  10  and the sequential control section  20  as shown in  FIG. 7  is stored in the nonvolatile memory  14 . 
   Specifically, parameter value “100” is assigned to parameter number “5100”, parameter value “101” to parameter number “5101”, parameter value “102” to parameter number “5102”, and parameter value “103” to parameter number “5103”. Hence, address F 0 ˜F 767  of the signal table F for the sequence program  1  and address G 0 ˜G 767  of the signal table G for the sequence program  1  are assigned to the first operation system of the complex machine  50 , address F 1000 ˜F 1767  of the same signal table F and address G 1000 ˜G 1767  of the same signal table G to the second operation system of the complex machine  50 , address F 2000 ˜F 2767  of the same signal table F and address G 2000 ˜G 2767  of the same signal table G to the third operation system of the complex machine  50 , and address F 3000 ˜F 3767  of the same signal table F and address G 3000 ˜G 3767  of the same signal table G to the fourth operation system of the complex machine  50 . Further, since parameter value “300” is assigned to parameter number “5104”, address F 0 ˜F 767  of the signal table F for the sequence program  3  and address G 0 ˜G 767  of the signal table G for the sequence program  3  are assigned to the loader  42 . 
   Thus, the numerical control section  10  and the sequential control section  20  can be interfaced in a desired manner, by assigning or changing the parameter values. Thus, the system can be changed or expanded very easily. Since there is no need to add a new programmable controller or the like, the system can be changed at a low cost. 
   It can be so arranged that the sequential control section of the numerical controller controls a device which is not controlled by the numerical control section. 
     FIG. 8  is a block diagram of an example of this arrangement. Here, a machine  60  controlled by the numerical controller has a single system of operation. Only one interface of signal system is provided between the numerical control section  10  and the sequential control section  20  by setting parameters. When the parameters for interfacing the sequence program  2  installed in the sequential control section  20  and the numerical control section  10  are not set, the sequential control section  20  does not have an interface between the sequence program  2  and the numerical control section  10 . Thus, the sequential control section  20  controls an independent peripheral device  43  according to the sequence program  2  installed in the sequential control section  20 . 
   In the present invention, a plurality of sequence programs installed in the sequential control section can be assigned to the multiple control systems of the numerical control section, freely. Thus, the numerical control system can be changed or expanded easily, and a peripheral device can be added or chanced easily. Further, even when a peripheral device or the like is added to the system or changed, there is no need to provide a new programmable controller or the like. Thus, the numerical control system can be changed or expanded at a low cost. Further, sequence programs can be organized flexibly in accordance with to-be-controlled machines and peripheral devices.

Technology Classification (CPC): 6