JP2010152882A - Display device for machine tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a user-friendly display device for machine tool, which freely customizes configuration of a display screen as intended by an operator. <P>SOLUTION: In the display device for machine tool, for a display item and display size selected by the operator, a plurality of divided screens corresponding to the display size are displayed on a display based on display information in a divided screen storage area 13d. When the operator specifies any one of the plurality of divided screens displayed on the screen, the display size and divided screen position information for the designated divided screen are stored in a customized screen storage area 13e. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a display device for a machine tool, and more particularly to a display device configured to allow an operator to freely customize the configuration of a display screen that displays a plurality of display items.

  2. Description of the Related Art Conventionally, a display device of a machine tool can display numerical control information such as a current position of each operation axis, a spindle speed, and a feed speed on a display screen for each display item. The manufacturer decides in advance which display items are displayed on the display screen, and the display screen configuration set at the time of machine tool shipment is fixed. Therefore, the configuration of the display screen cannot be freely customized according to the intention of the worker.

  In the display device in the NC machine tool described in Patent Document 1, after selecting a desired display pattern from a plurality of display patterns consisting of one or a plurality of display areas, it is set which display item is displayed in which display area It is possible.

JP 2000-66709 A

  However, the display device of Patent Document 1 has a low degree of freedom for customization because a desired display pattern is selected from a plurality of display patterns set in advance by the manufacturer, and the display screen can be freely configured according to the operator's intention. Can't be customized.

  In addition, there are an NC mode and an interactive mode as input modes for inputting a machining program. Generally, display items that an operator wants to see when inputting a machining program differ for each input mode. Therefore, regarding the customization of the configuration of the display screen, it is more convenient to provide display items that can be set for each input mode rather than to make them common to the two input modes.

  An object of the present invention is to provide a display device for a machine tool that can freely customize the configuration of a display screen in accordance with the intention of an operator and is easy to use.

  The display device for a machine tool according to claim 1 is a display device for a machine tool capable of displaying a display screen including a plurality of display items on a display means, and a display item storing a display size that can be displayed for each of the plurality of display items. Storage means, display information for displaying each of a plurality of divided screens obtained by equally dividing the display screen into a plurality of display sizes, and position information indicating a display position for each of the plurality of divided screens are stored. Divided screen storage means, item selection means for selecting any combination of the display item and the display size from the combination of the plurality of display items and the display size stored by the display item storage means, Each of the plurality of divided screens corresponding to the display size selected by the item selection unit is displayed based on the display information stored in the divided screen storage unit. Split screen display control means for displaying in a row; designation means for designating any one of the plurality of split screens displayed by the split screen display control means; and the split screen designated by the designation means The position information based on the position information and the display item stored in the customization screen storage means, the customization screen storage means for storing the position information in association with the display item selected by the item selection means Display control means for displaying the display items on the divided screen of the display screen.

  In the above configuration, the operator selects one of the display item and display size combinations from the plurality of display item and display size combinations stored in the display item storage unit by the item selection unit. The divided screen display control means displays each of the plurality of divided screens corresponding to the display size selected by the item selection means on the display means based on the display information of the divided screen storage means.

  The operator designates one of the plurality of divided screens displayed by the display means using the designation means. The customized screen storage means stores the position information of the divided screen designated by the worker in association with the display item selected by the worker. The display control means displays the display items on the divided screen of the display screen indicated by the position information based on the position information and display items stored in the customization screen storage means. Thereby, it is possible to display the divided screen corresponding to the display item designated by the worker on the customization screen.

  The display device for a machine tool according to claim 2 includes mode setting means for setting an input mode for inputting a machining program to the control device for the machine tool, and the display item storage means includes the display item and the display item. A combination of display sizes is stored in association with the input mode, and the display item and the display size combination that can be selected by the item selection unit are selected based on the input mode set by the mode setting unit. Item switching means is provided.

  The display device for a machine tool according to claim 3, wherein among the plurality of display items stored by the display item storage means, setting item storage means for storing the display item capable of setting arbitrary data, and the setting item Data setting means for setting arbitrary data for the display items stored in the storage means, and the display control means on the divided screen corresponding to the display items stored in the setting item storage means, Arbitrary data set by the data setting means is displayed.

  According to the invention of claim 1, the operator can freely combine the divided screens, and the degree of freedom when customizing the configuration of the display screen is increased. Therefore, the display device of the machine tool can freely set the configuration of the display screen by the worker according to the intention of the worker.

  According to the invention of claim 2, it is possible to realize a display device for a machine tool that is easy to use by allowing an operator to select only necessary display items for each input mode.

  According to the invention of claim 3, the operator can select only display items for which arbitrary data can be set, thereby improving the usability of the display device of the machine tool.

1 is a front view of a machine tool according to an embodiment of the present invention. It is a block diagram which shows the electric constitution of a control apparatus. It is explanatory drawing which shows the storage area of RAM. It is a figure which shows the table memorize | stored in the display item storage area. It is a figure which shows the display information and division | segmentation screen position information in case a display size is 1/2. It is a figure which shows the display information and division | segmentation screen position information in case a display size is 1/4. It is a figure which shows the display information in case a display size is 1/8, and division | segmentation screen position information. It is a figure which shows the display information and division | segmentation screen position information in case a display size is 1/8 (horizontal). It is a figure which shows the display information and division | segmentation screen position information in case a display size is 1/12. It is a flowchart of a customization screen creation control program. It is a flowchart of a screen edit control program. It is a figure which shows the selection screen of a display item. It is a figure which shows the designation | designated screen of a split screen. It is a figure which shows the display screen after screen editing. It is a figure which shows a display item setting screen. It is a flowchart of a display item setting process.

  Hereinafter, the best mode for carrying out the present invention will be described.

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

  First, a schematic configuration of the machine tool 1 will be described.

  The machine tool 1 shown in FIG. 1 can perform desired machining (for example, “drilling”, “cutting”, etc.) on the workpiece by relatively moving the workpiece and the tool. The machine tool 1 includes an iron base 2 as a base, a machine main body (not shown) provided on the upper part of the base 2 for cutting a workpiece, and fixed to the upper part of the base 2. 2 and a box-shaped splash cover 4 that covers the upper part.

  The base 2 is a substantially rectangular parallelepiped casting that is long in the Y-axis direction (perpendicular to the paper surface in FIG. 1). Legs 2a whose heights can be adjusted are provided at the four corners of the lower part of the base 2, and the machine tool 1 is installed by installing these legs 2a on the floor of a factory or the like. The splash cover 4 is formed in a substantially rectangular parallelepiped box shape. The front surface of the splash cover 4 has an opening (not shown), and the opening is provided with a pair of sliding opening / closing doors 5 and 6.

  The open / close doors 5 and 6 have rectangular glass window portions 5a and 6a, respectively, at substantially the center thereof. The open / close door 5 has a handle portion 5b at its right end, and the open / close door 6 has a handle portion 6b at its left end. The display device 31 is fixed to the splash guard 4 on the right side of the open / close door 6. The display device 31 includes a keyboard 32 having a numeric keypad and various operation keys, a control device 10 (see FIG. 2), a display 33 (display means), and a control circuit 21 (see FIG. 2). The operator operates the keyboard 32 while checking the display 33 of the display device 31 to set a machining program for machining the workpiece, the type of tool to be used, tool information, various parameters, etc. can do. Further, the operator can alternatively set an NC mode, which is an input mode for inputting a machining program to the control device 10, and an interactive mode via the keyboard 32.

  The NC mode and the dialogue mode are input modes for inputting a machining program to the control device 10. The NC mode is a mode in which an operator directly inputs information necessary for a machining program using a code (so-called NC language) defined in the JIS standard. The dialogue mode is a mode in which information necessary for the machining program is interactively inputted to the machine tool 1 by repeatedly performing an operation for an operator to arbitrarily set the input items sequentially displayed on the display 33. A RAM 13 to be described later stores an NC mode or an interactive mode preset by the operator as a parameter relating to the input mode.

  Next, the electrical configuration of the control device 10 will be described.

  As shown in FIG. 2, the control device 10 includes a microcomputer, and includes an input interface 14, a CPU 11, a ROM 12, a RAM 13, and an output interface 15. The input interface 14 is connected to the keyboard 32. The output interface 15 is connected to an X-axis motor 27, a Y-axis motor 28, a Z-axis motor 29, and a main shaft motor 30 via drive circuits 17 to 20, respectively. The X-axis motor 27, the Y-axis motor 28, and the Z-axis motor 29 include encoders 27a to 30a, respectively. The drive circuits 17 to 20 receive position feedback signals from the encoders 27a to 30a and perform position feedback control. The output interface 15 is connected to the display 33 via the control circuit 21.

  The ROM 12 stores a main control program for causing the machining program of the machine tool 1 to function, a control program for customizing screen creation control shown in FIG. 10, a control program for screen editing control shown in FIG. 11, and a display item setting process shown in FIG. A control program area for storing the control program is provided.

  Next, the storage area of the RAM 13 will be described.

  As shown in FIG. 3, the RAM 13 has a numerical control program area 13a that stores a machining program for machining a workpiece, a display information area 13b that stores numerical control information such as machine coordinate positions, and a table shown in FIG. The stored display item storage area (display item storage means) 13c, the divided screen storage area (divided screen storage means) 13d that stores information related to the divided screens shown in FIGS. 5 to 9, and the customized display screen shown in FIG. A customized screen storage area (customized screen storage means) 13e for storing information, a display item setting storage area (setting item storage means) 13f for storing display items arbitrarily set by the operator by display item setting processing, and the like are provided. .

  As shown in FIG. 4, the table stored in the display item storage area 13c is a table that defines the correspondence between the mode name of the input mode, the item name of the display item, and the display size set for each display item. The table shown in FIG. 4 is stored in advance in the display item storage area 13c by the manufacturer. In this table, for a plurality of display items displayed for each input mode, the mode name, the item name of the display item, and one or a plurality of display sizes set for each item are set. That is, in the display item storage area 13c, the combination of the item name and display size of the display item is stored in association with the input mode.

  Next, split screen display information and split screen position information stored in the split screen storage area 13d will be described.

  5 to 9 are diagrams showing display information and divided screen position information when the display sizes are 1/2, 1/4, 1/8, 1/8 (horizontal), and 1/12. The display information is information for displaying each of the divided screens obtained by equally dividing the display screen into a plurality of display sizes. The divided screen position information is information indicating the position in the screen for each of the plurality of divided screens, and different divided screen position information from 1 to 34 is assigned to each divided screen for each display size. The CPU 11 can recognize which divided screen the operator has designated on the screen based on the divided screen position information corresponding to the divided screen. The CPU 11 stores the divided screen position information of the divided screen designated by the worker in the customized screen storage area 13e in association with the display item designated by the worker.

  Next, customization screen creation control executed by the control device 10 will be described based on the flowcharts of FIGS. 10 and 11. In the figure, Si (i = 1, 2,...) Indicates each step.

  As shown in FIG. 10, in the setting screen creation process, when the operator selects the “customize screen” key by operating the keyboard 32 on the menu screen displayed on the display 33, the control device 10 displays a customization screen on the display 33. Display (S1). The customization screen is a display screen in which arbitrary display items designated by the worker are allocated to the divided screen designated by the worker. The display screen displays data (parameters) corresponding to an arbitrary display item designated by the operator. Data (parameters) corresponding to each display item is information acquired by the control device 10 based on the operation status of the machine tool 1 and the operator's input operation. A RAM 13 to be described later stores data (parameters) corresponding to display items acquired by the control device 10. When there is no customization screen edited by the operator, the CPU 11 displays an initial customization screen (set in advance by the machine tool manufacturer) on the display 33.

  The CPU 11 detects an input operation of the keyboard 32 to determine whether or not the operator has performed a screen switching operation on the customization screen (S2). When the operator has not performed the screen switching operation (S2; No), the CPU 11 detects whether the operator has pressed the item addition / change key on the customization screen by detecting the input operation of the keyboard 32. (S3). The item addition / change key is a button for instructing the control device 10 that the operator arbitrarily edits the customization screen displayed on the display 33. When the operator presses the item addition / change key (S3; Yes), the CPU 11 starts a screen editing process (see FIG. 11) (S4). When the operator does not press the item addition / change key (S3; No), the CPU 11 returns the process to S1. However, when the operator performs a screen switching operation (S2; Yes), the CPU 11 switches the display on the display 33 from the customization screen to another screen and ends this processing.

  Screen editing processing executed by the CPU 11 of the control device 10 will be described based on the flowchart of FIG. In the figure, Si (i = 10, 11,...) Indicates each step.

  When the screen editing process is started, the CPU 11 refers to the parameter relating to the input mode stored in the RAM 13 and determines whether or not the NC mode is selected as the input mode (S10). When the input mode is the NC mode (S10; Yes), the CPU 11 reads display items that can be selected when the NC mode is set from the display item storage area 13c. The CPU 11 displays the read display item on the display 33. The CPU 11 displays the display items that can be selected by the operator in the NC mode on the display 33 in association with the display sizes of the display items (S11). Specifically, when the RAM 13 stores the NC mode, the CPU 11 displays the display items corresponding to the NC mode in the table shown in FIG. 4 on the display item selection screen shown in FIG. The display item selection screen (FIG. 12) displays display items corresponding to the NC mode for each display size. For example, the table shown in FIG. 4 associates the display item “absolute coordinate position” corresponding to the NC mode with two display sizes “1/12” and “1/8”. The display item selection screen (FIG. 12) displays the display item “absolute coordinate position” (display item of No. “003”) corresponding to the display size “1/8” and the display corresponding to the display size “1/12”. The item “absolute coordinate position” (display item of No. “004”) is displayed.

  The operator operates the keyboard 32 to select an arbitrary display item and display size combination from among display items that can be selected in the NC mode. Specifically, the operator can select a display item and a display size by selecting an arbitrary display item on the display item selection screen (FIG. 12). For example, the worker is no. The display item “absolute coordinate position” and the display size “1/8” can be selected simply by selecting the display item “003”. The CPU 11 detects whether the operator has selected a display item from among a plurality of display items by detecting an input operation of the keyboard 32 (S12). When the worker selects a display item (S12; Yes), the CPU 11 shifts the process to S13. When the operator does not select the display item (S12; No), the CPU 11 shifts the process to S11.

  On the other hand, when the interactive mode is selected as the input mode (S10; No), the CPU 11 reads out the selected item when the interactive mode is set from the display item storage area 13c and displays it on the display 33 (S25). Specifically, when the RAM 13 stores the interactive mode, the CPU 11 displays the display items corresponding to the interactive mode in the table shown in FIG. 4 on the display item selection screen similar to FIG. The operator operates the keyboard 32 to select item names and display sizes of arbitrary display items among display items that can be selected in the interactive mode. Similarly to S11, the CPU 11 determines whether or not the operator has selected a display item from among a plurality of display items (S26).

  When the worker selects a display item (S12; Yes or S26; Yes), the CPU 11 determines whether or not the display size of the display item selected by the worker is ½ (S13). For example, the operator selects No. on the display item selection screen (FIG. 12). It is assumed that the display item “program” and the display size “1/2” are selected by selecting the display item “103”. In this case, since the display size of the display item selected by the operator is ½ (S13: YES), the CPU 11 displays the display information of the display size ½ stored in the divided screen storage area 13d (FIG. 5). Read). Based on the read display information, the CPU 11 displays each of the two divided screens corresponding to the display size 1/2 on the screen (S14).

  When the display size of the display item selected by the worker is not ½ (S13; No), the CPU 11 determines whether or not the display size of the display item selected by the worker is ¼ (S18). . For example, the operator selects No. on the display item selection screen (FIG. 12). It is assumed that the display item “program” and the display size “1/4” are selected by selecting the display item “104”. In this case, since the display size of the display item selected by the worker is 1/4 (S18; Yes), the CPU 11 displays the display information of the display size 1/4 stored in the divided screen storage area 13d (see FIG. 6). ). Based on the read display information, the CPU 11 displays each of the four divided screens corresponding to the display size 1/4 on the screen (S19).

  When the display size of the display item selected by the worker is not ¼ (S18; No), the CPU 11 determines whether or not the display size of the display item selected by the worker is ８ (S20). . For example, the operator selects No. on the display item selection screen (FIG. 12). It is assumed that the display item “absolute coordinate position” and the display size “1/8” are selected by selecting the display item “003”. In this case, since the display size of the display item selected by the operator is 1/8 (S20; Yes), the CPU 11 displays the display information of the display size 1/8 stored in the divided screen storage area 13d (see FIG. 7). ). Based on the read display information, the CPU 11 displays each of the eight divided screens corresponding to the display size 1/8 on the screen (S21).

  When the display size of the display item selected by the worker is not 1/8 (S20; No), the CPU 11 determines whether or not the display size of the display item selected by the worker is 1/8 (horizontal). (S22). For example, the operator selects No. on the display item selection screen (FIG. 12). It is assumed that the display item “magazine” and the display size “1/8 (horizontal)” are selected by selecting the display item “025”. In this case, since the display size of the display item selected by the operator is 1/8 (horizontal) (S22; Yes), the CPU 11 has the display size 1/8 (horizontal) stored in the divided screen storage area 13d. Display information (see FIG. 8) is read. Based on the read display information, the CPU 11 displays each of the eight divided screens corresponding to the display size 1/8 (horizontal) on the screen (S23). When the display size of the display item selected by the worker is not 1/8 (horizontal) (S22; No), the CPU 11 determines that the display size of the display item selected by the worker is 1/12. For example, the operator selects No. on the display item selection screen (FIG. 12). It is assumed that the display item “absolute coordinate position” and the display size “1/12” are selected by selecting the display item “002”. In this case, since the display size of the display item selected by the operator is 1/12, the CPU 11 reads the display information of the display size 1/12 (see FIG. 9) stored in the divided screen storage area 13d. Based on the read display information, the CPU 11 displays each of the 12 divided screens corresponding to the display size 1/12 on the screen (S24).

  The CPU 11 displays a plurality of divided screens on the display 33 in any one of the processes S14, S19, S21, S23, and S24. Thereafter, the CPU 11 detects an input operation of the keyboard 32, and determines whether or not the operator has specified an arbitrary divided screen from the plurality of divided screens and pressed the setting key (S15). For example, in FIG. 13, the operator can designate one of two divided screens by designating the keyboard 32 and pressing a setting key.

  When the worker presses the setting key (S15; Yes), the CPU 11 stores the position information of the divided screen designated by the worker in the customized screen storage area 13e in association with the display item designated by the worker ( S16). The position information of the divided screen stored in the customized screen storage area 13e is information for displaying the divided screen corresponding to the display item designated by the operator on the customized screen. Based on the display items and position information stored in the customization screen storage area 13e, the CPU 11 displays the divided screen designated by the operator on the customization screen being edited. At the same time, the CPU 11 displays the item name of the display item designated by the operator on the divided screen (see FIG. 14).

  After executing the process of S16, the CPU 11 determines whether or not the operator has pressed the end key by detecting the input operation of the keyboard 32 (S17). When the operator has not pressed the end key (S17; No), the CPU 11 returns the process to S10. The operator can assign an arbitrary display item corresponding to the input mode to an arbitrary arrangementable area, for example, as in the customization screen shown in FIG.

  In the process of editing the customization screen by the worker as described above, the display items assigned to the customization screen by the worker may overlap with some or all of the display items assigned earlier. In this case, the CPU 11 gives priority to the display item assigned later. The CPU 11 deletes the previously assigned display item and the position information corresponding to the display item in the customization screen storage area 13e, and stores the position information of the display item assigned later and the position information corresponding to the display item. (S16).

  When the worker presses the end key (S17; Yes), the CPU 11 stores the customization screen edited by the worker in the RAM 13. CPU11 complete | finishes a screen edit process and transfers a process to S1. When the operator has not pressed the end key (S17; No), the CPU 11 returns the process to S10. If the operator does not press the setting key in S15 (S15; No), the CPU 11 proceeds to S17.

  Returning to the setting screen creation processing (FIG. 10), the CPU 11 displays the customization screen edited by the operator in the screen editing processing (FIG. 11) on the display 33 (S1). The CPU 11 displays an arbitrary display item designated by the worker on an arbitrary divided screen designated by the worker. The CPU 11 displays data (parameters) corresponding to the display item on the divided screen of each display item. For example, in the customization screen shown in FIG. 14, the CPU 11 displays the display items “enlarged coordinates (XYZ)”, “GM modal”, “work coordinates (modal)”, “spindle speed / feed speed”, “ Data (parameters) corresponding to “magazine” and “program” are acquired from the RAM 13. CPU11 displays the data (parameter) acquired from RAM on the divided screen of each display item. Thereby, the operator can confirm the data (parameter) regarding a desired display item with a desired screen position and screen size by referring to the customization screen.

As described above, in the screen editing process (see FIG. 11), when the operator sets a display screen in the NC mode or the interactive mode, the worker can select any display item among display items that can be displayed in each input mode. Select a combination of items and display size. The display 33 displays a plurality of divided screens according to the display size of the display item selected by the worker. The operator can display an arbitrary display item on the divided screen by designating a desired divided screen among the plurality of divided screens. The present invention is also effective in a machine tool that does not have mode setting means for setting either the interactive mode or the NC mode. The keyboard 32 corresponds to mode setting means, item selection means, and designation means. CPU11 of the control apparatus 10 which performs S14, S19, S21, S23, and S24 is equivalent to a divided screen display control means. The CPU 11 of the control device 10 that executes S1 corresponds to display control means.
The CPU 11 of the control device 10 that executes S10, S11, and S25 corresponds to a selection item switching unit.

  Next, the display item setting process will be described based on the flowchart of FIG. In the figure, Si (i = 30, 31...) Indicates each step.

  The machine tool 1 has a plurality of macro variables that the CPU 11 refers to when executing the machining program. Of the plurality of macro variables, for example, a specific macro variable frequently used by the operator is desirably set and confirmed by the operator on the customization screen. Among the display items that can be assigned to the customization screen shown in the table of FIG. 4, “macro variables 1 to 8” to “macro variables 9 to 16” are display items that allow an operator to set arbitrary data (parameters). is there. The display item setting process (FIG. 16) is a process for the operator to set an arbitrary numerical value for the display items “macro variables 1 to 8” to “macro variables 9 to 16”.

  As shown in FIG. 16, in the display item setting process, when the operator selects the display item setting screen key on the menu screen, the CPU 11 displays the display item setting screen shown in FIG. 15 on the display 33 (S30). The display item setting screen (FIG. 15) refers to the display item setting storage area 13f and displays display items for which display item data (parameters) can be arbitrarily set. Specifically, the display item setting screen (FIG. 15) displays a plurality of macro variables used by the machine tool 1. In the example of the display item setting screen (FIG. 15), display items “macro variables 1 to 8” to “macro variables 9 to 16” are displayed as macro variables. That is, the operator can set arbitrary numerical values to the 16 macro variables (macro variables 1 to 16).

  The operator operates the keyboard 32 to select an arbitrary macro variable from the display item setting screen (FIG. 15) and arbitrarily set the value of the macro variable (S31). In the example of the display item setting screen shown in FIG. 15, the operator sets an arbitrary numerical value to any one of “macro variables 1 to 16”. In the example of the display item setting screen (FIG. 15), the operator sets the numerical value “100” to the “macro variable 1” via the keyboard 32. The CPU 11 determines whether or not the operator has pressed the setting key by detecting the input operation of the keyboard 32 (S32). When the operator presses the setting key (S32; Yes), the CPU 11 stores the contents set by the worker in the display item setting storage area 13f (S33), and ends the display item setting process. In the example of the display item setting screen (FIG. 15), the display item setting storage area 13 f stores a numerical value “100” corresponding to the macro variable 1. Similarly, for the other macro variables 2 to 16, numerical values set by the operator corresponding to each macro variable are stored. When the operator does not press the setting key (S32; No), the CPU 11 ends the display item setting process without saving the contents set by the worker in the display item setting storage area 13f.

  When the customization screen displayed on the display 33 includes a macro variable as a display item (S1), the CPU 11 reads a numerical value corresponding to the macro variable from the display item setting storage area 13f. On the customization screen displayed on the display 33, the CPU 11 displays the numerical value read from the display item setting storage area 13f on the corresponding macro variable split screen. For example, when displaying the customization screen including the display item “macro variables 1 to 8”, the CPU 11 reads the numerical value “100” corresponding to the macro variable 1 from the display item setting storage area 13f. The CPU 11 displays “macro variable 1: 100” on the divided screen of the display item “macro variables 1 to 8”. The keyboard 32 corresponds to data setting means.

  The operation and effect of the display device 31 of the machine tool 1 described above will be described. In the display device 31 of the machine tool 1, the operator sets the input mode. The worker arbitrarily selects a combination of a plurality of display items and display sizes stored in the display item storage area 13c. The CPU 11 displays each of the plurality of divided screens corresponding to the combination of the display item and the display size selected by the worker on the display 33 based on the display information in the divided screen storage area 13d.

  The operator designates one of the plurality of divided screens displayed on the display 33. The customized screen storage area 13e stores the position information of the divided screen specified by the worker in association with the display item specified by the worker. Based on the display items and position information stored in the customization screen storage area 13e, the CPU 11 displays a divided screen corresponding to the display item designated by the worker on the customization screen. Therefore, since the operator can freely combine a plurality of divided screens, the degree of freedom when setting the configuration of the display screen is increased. Therefore, the display device can freely set the configuration of the display screen in accordance with the operator's intention.

  The display item storage area 13c stores a combination of display items and display sizes in association with input modes. CPU11 switches the display item which can be selected for every input mode which the operator set in the display item selection screen (FIG. 12) displayed when editing a setting screen. By enabling the operator to select only display items necessary for each input mode on the display item selection screen (FIG. 12), it is possible to realize a display device 31 that is easy to use.

  When the data (parameter) is set for the display item, the CPU 11 displays a display item on which the operator can set arbitrary data (parameter) on the display item setting screen (FIG. 15). Therefore, since only the display items necessary for the operator can be selected on the display item setting screen (FIG. 15), the usability of the display device 31 is improved.

  Next, a modified example in which the above embodiment is partially modified will be described.

  In the above embodiment, the display size of the divided screen stored in the divided screen storage area 13d is 1/2, 1/4, 1/8, 1/8 (horizontal), 1/12. It is also possible to apply.

DESCRIPTION OF SYMBOLS 1 Machine tool 10 Control apparatus 11 CPU
13c Display item storage area 13d Split screen storage area 13e Customized screen storage area 13f Display item setting storage area 31 Display device 32 Keyboard

Claims (3)

In a display device of a machine tool capable of displaying a display screen including a plurality of display items on a display means,
Display item storage means for storing a display size that can be displayed for each of the plurality of display items;
A divided screen storage storing display information for displaying each of a plurality of divided screens obtained by equally dividing the display screen into a plurality of display sizes, and position information indicating display positions for each of the plurality of divided screens. Means,
Item selection means for selecting any one of the display items and the display size combination from the plurality of display items and the display size combinations stored by the display item storage means;
Split screen display control means for displaying each of the plurality of split screens corresponding to the display size selected by the item selection means on the display means based on the display information stored by the split screen storage means;
A designation unit for designating any one of the plurality of divided screens displayed by the divided screen display control unit;
Customization screen storage means for storing the position information of the divided screen designated by the designation means in association with the display item selected by the item selection means;
A display device for a machine tool, comprising: display control means for displaying the display items on the divided screen of the display screen indicated by the position information based on the position information and the display items stored by the customization screen storage means. . Comprising a mode setting means for setting an input mode for inputting a machining program to the control device of the machine tool;
The display item storage means stores a combination of the display item and the display size in association with the input mode,
The machine tool according to claim 1, further comprising selection item switching means for switching a combination of the display item and the display size that can be selected by the item selection means based on the input mode set by the mode setting means. Display device. Among the plurality of display items stored by the display item storage unit, a setting item storage unit that stores the display item capable of setting arbitrary data;
Data setting means for setting arbitrary data for the display items stored in the setting item storage means,
The display of a machine tool according to claim 1 or 2, wherein the display control means displays arbitrary data set by the data setting means on the divided screen corresponding to the display items stored by the setting item storage means. apparatus.