JP2020055043A - Machine tool - Google Patents

Abstract

To provide a machine tool, which can easily conform tool data including change histories of set values related to a service life of tools and count values.SOLUTION: A machining center 1 includes: tool data preparing means (an NC device 2) that prepares tool data, associating set values related to a service life of tools and count values of actual use frequencies thereof with tool identification information for identifying the tools, in machining a plurality of work-pieces using the tools; memorizing means (a memorizing part 2a) that memorizes the tool data prepared by the NC device 2 and a change history of change of the tool data; and display means (an HMI device 4) that displays the tool data and the change history.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a machine tool such as a machining center.

  In machine tools, in order to prevent machining defects in the work due to tool abnormalities such as breakage, the maximum number of tool uses is set in advance as a set value, and the actual number of tool uses is counted and counted. If the value has reached the set value or has reached a predetermined count value before the set value, the tool is notified that the tool has reached the end of its life and prompts for replacement. In particular, Japanese Patent Application Laid-Open No. H11-163873 discloses that tool-related data including a workpiece number of a workpiece machined immediately before and immediately after a tool change based on the set value and the count value, including the set value and the count value in the work processing data. The invention of a machining history search system that enables a tool and a work to be specified by making the search possible.

JP 2017-220061 A

  In the above-mentioned machining history search system, since the workpiece machining data is stored in a personal computer or the like installed separately from the machine tool, the worker moves from the machine tool to a location such as a personal computer to search and confirm the workpiece machining data. Needed and was troublesome. Further, even if the set value or the count value is changed or reset on the site, it is not left as a history, so that the tool is continuously used even if the tool life has expired, and there is a possibility that a machining defect may occur.

  Therefore, an object of the present invention is to provide a machine tool that can easily confirm tool data including a change history of a set value and a count value related to a tool life on the machine tool itself.

  In order to achieve the above object, according to the present invention, when machining a plurality of workpieces using a tool, at least a set value relating to the life of the tool and an actual use are included in tool identification information for identifying the tool. Tool data creating means for creating tool data in association with the count value of the number of times; storage means for storing the tool data created by the tool data creating means and a change history when the tool data is changed; Display means for displaying a change history.

  According to the first aspect of the present invention, since the tool data created by the tool data creating means and the change history thereof are stored and can be displayed, the tool including the change history of the set value and the count value related to the tool life is provided. The data can be easily checked on the machine tool itself.

It is a schematic diagram of a machining center. It is a flowchart of a save process of a program activation history. It is a flowchart of a save process of a program activation history. It is an explanatory view of a menu screen. It is an explanatory view of a display screen of a program activation history. It is explanatory drawing of an individual management search screen. FIG. 9 is an explanatory diagram of a setting screen of a rotation speed and a threshold value in the tool shake detection device. 9 is a flowchart of a setting information saving process in the tool shake detection device. 6 is a flowchart of a shake amount detection process in the tool shake detection device. It is an explanatory view of a display screen of a tool shake detection history. It is explanatory drawing of the display screen of a tool counter. It is an explanatory view of a display screen of a tool counter change history.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic diagram of a machining center as a machine tool. The machining center 1 includes an HMI (Human Machine Interface) device 4 and an eddy current sensor 5 for detecting tool runout, in addition to a known NC device 2 and PLC device 3. Is provided. In the HMI device 4, a keyboard, a touch panel, a mouse, and the like are included as input means from the operator side, and a monitor, a meter, a lamp, a speaker, and the like are included as information transmission means from the machine tool side.
The NC device 2 processes a work by controlling a spindle, a feed shaft, an ATC, and the like via the PLC device 3, and when a work is processed by a predetermined tool, a work ID for identifying the work and a tool identification. It also has a function as a processing history creating means for creating processing history data in which a tool number as information, a processing program, and processing date and time information are associated with each other, and storing the generated processing history data in the storage unit 2a as storage means. The NC device 2 also has a function as tool data creation means for creating tool data in which a set value relating to the life of the tool and a count value of the actual number of times of use are associated with the tool number and storing the tool data in the storage unit 2a. Have. The processing history data and the tool data can be output to a monitor serving as a display means in accordance with a command from an input means of the HMI device 4.

The eddy current sensor 5 is provided in the vicinity of the main shaft, and measures the amount of vibration of a tool holder mounted on the main shaft by an ATC (not shown). It constitutes a shake detection device. The measured amount of shake is compared with a preset threshold value to determine whether the tool held in the measured tool holder is acceptable (usable or unusable). Thus, it is possible to prevent machining defects caused by the inclination of the tool holder due to the cutting chips bitten between the main shaft and the tool holder.
In the storage unit 2a, as described later, registration of tool holders and tools and setting information such as threshold values can be performed via input means of the HMI device 4. Further, the history of the determination result is also stored in the storage unit 2a, and can be output to the monitor in accordance with a command from the input means of the HMI device 4.

In the machining center 1 configured as described above, when processing a workpiece, the activation history of the program is stored based on the flowcharts of FIGS. 2 and 3.
First, when a work is loaded in S1 of FIG. 2, a work ID is read from a recognition tag of the work by a reading device (not shown) in S2, and in S3, the read work ID information is stored as an individual management number. .
When the machining of the workpiece is started in S11 of FIG. 3, the machining program being executed is read from the NC device 2 in S12, and in S13, the execution date and time of the machining and the machining program number are stored in the storage unit 2a. Is stored. Then, in S14, the date and time of the processing and the processing program number are linked with the individual management number of the processed work and stored as processing history data.

  FIG. 4 shows an example of a menu screen of the monitor in the HMI device 4. Various operation buttons are displayed on the monitor, and the operation is performed by touching the operation buttons of the monitor, which is a touch panel and also serves as an input unit. It is possible. Here, an operation state display button 10 for displaying an operation state, an abnormality alarm button 11 for generating and displaying an abnormality alarm, a program start history display button 12 for displaying a start history of a machining program, a displacement amount of a tool holder (a displacement amount of a drawbar) ) And a shake detection history display button 13 for displaying the detection history of the shake of the tool, a tool counter button 14 for displaying the number of times the tool has been used, a shake detection button 15 for registering setting information of the tool shake detection device, and the like. ing.

For example, when the program start history display button 12 is touch-operated on the menu screen, as shown in FIG. 5, the date, time, the individual management number which is the work ID information processed at that time, and the processed program number are listed in a new order. Is displayed.
When the user wants to inquire about information on a specific work, such as when a defective product occurs in the work, touching the individual management number search button 16 displayed in FIG. 5 causes the individual management search as shown in FIG. The screen 20 is displayed in a pop-up. Therefore, when the operator inputs the individual management number, detailed information related to the input individual management number, that is, a related list including a tool number, a processing date, a machine number, and the like is created and displayed on the monitor. From this related list, the machine number, tool number, and processing date of the defective product can be specified.

On the other hand, in the tool shake detection device, input and storage of setting information such as a tool holder used in advance for the spindle, a tool mounted on the tool holder, and a threshold for determining shake detection for each tool are performed. The processing can be performed by the machining center itself via the monitor of the HMI device 4.
For example, when registering the tool and the threshold value, when the shake detection button 15 is touch-operated on the menu screen of FIG. 4, the rotation speed and the threshold value are individually set for up to 32 tools as shown in FIG. The available setting fields are displayed.
The method of registering the setting information will be described with reference to the flowchart of FIG. 8. First, in S21, the tool number, the number of revolutions, and the threshold value to be used are respectively input from the registration No. 1 of FIG.
Then, in S22, when the tool having the input tool number is attached to the main spindle and the sensor adjustment button 17 in FIG. 7 is touch-operated, the main spindle rotates at the input number of revolutions to perform sensor adjustment. In S23, if the threshold value input with respect to the shake amount measured here is appropriate, touching the OK button 18 causes these setting information to be stored in S24. In FIG. 7, the shake amount 19 measured together with the threshold value is also displayed. If this is done for all tools, the setting operation is completed.

In this tool shake detection device, shake detection is automatically performed when a tool is exchanged by the ATC. That is, in the flowchart of FIG. 9, when the shake amount is detected in S31, it is determined in S32 whether or not the detected shake amount exceeds a threshold value set for the tool number. If not, the normal processing (OK determination) is performed in S33, and the work is processed as it is. On the other hand, if the shake amount exceeds the threshold value in the determination of S32, error processing (determined as NG) is performed in S34, and the operation is abnormally stopped.
Then, in S35, the detected shake amount information and the determination result are stored and linked with the individual management number of the work processed in S36 and stored.

  Therefore, when the shake detection history display button 13 is touch-operated on the menu screen, a list of tool numbers, thresholds, and determination results (OK / NG) used for each individual management number is displayed as shown in FIG. . In FIG. 10, the detection history of the drawbar is also displayed, and the history of the shake detection for each individual management number is displayed as “shaking 1” and the drawbar detection is displayed as “draw”. Here, when the individual management number search button 16 is touch-operated, the individual management search screen 20 pops up in the same manner as in FIG. 6. Therefore, when the individual management number is input, detailed information related to the input individual management number, ie, tool A related list including numbers, processing dates, machine numbers, and the like is created and displayed on the monitor. From this related list, the machine number, tool number, and processing date of the defective product can be specified.

On the other hand, when the tool counter button 14 is touch-operated on the menu screen, as shown in FIG. 11, for each tool, the number of use up to that time, the set number which is the replacement time, and a notice is given before the set number is reached. In this case, the number of times subtracted from the set number (advance notice) is displayed in a list.
The values in each table, including the number of uses and the number of settings, can be arbitrarily changed by selecting the corresponding column or reset by operating the reset selection button. And reset are stored as change history.
The change history can be displayed as a list as shown in FIG. 12 by touching the tool counter change history display button 21. The portion related to the change or reset is displayed along with the date and time and the numerical value before the change, so that the change history can be grasped at a glance.

In FIG. 12, the number of uses of the tool of the tool code 1 is reset (history number 1), and a history of the changed number of uses is left before that (history number 2). Further, the number of tools used in the tool code 22 is reset (history number 3), and histories in which the numbers of tools used in the tool code 6 and the tool code 3 are changed remain (history numbers 4 and 5). Further, a history of the change in the number of tools set in the tool code 22 is also left (history number 5).
In the history numbers 7 and 8, the history of the change of the tool code is left. In the history numbers 9 to 13, a history in which the number of uses or the set number has been changed is left.

  As described above, according to the machining center 1 of the above embodiment, when a plurality of workpieces are machined using the tool, the work identification information (individual management number) for identifying each work, the tool information for machining each work, and the machining. Machining history creating means (NC device 2) for creating machining history data by associating date and time information with machining program information; storage means (storage unit 2a) for storing machining history data created by NC device 2; Input means (HMI device 4) capable of specifying the individual management number, and display means for extracting and displaying processing history data related to the specified individual management number when the individual management number is specified by the HMI device 4. (HMI device 4), the history of which product was processed and when can be searched by the machining center 1 itself. Therefore, information relating to the processing trouble can be easily confirmed in a short time.

In particular, here, a shake detection means (tool shake detection device) that measures the shake amount of the tool with the eddy current sensor 5 and compares the measured shake amount with a preset threshold value to determine whether the tool is good or not. In addition, the HMI device 4 can input setting information including a threshold value in the tool shake detection device, the storage unit 2a can store a determination result by the tool shake detection device, and the HMI device 4 Since the determination result stored in the storage unit 2a can be displayed, the setting relating to the tool shake detection device can be performed by the machining center 1 itself without connecting an external personal computer, and the determination result is also monitored by the machining center 1 itself. can do.
Further, in the storage unit 2a, the difference between the determination result and the threshold value can be stored together with the quality of the tool as a determination result, so that the details of the determination result of each tool can be confirmed by the machining center 1 itself.

  According to the machining center 1 of the above-described embodiment, when processing a plurality of workpieces using a tool, the setting value relating to the tool life and the count value of the actual number of times of use are associated with the tool identification information for identifying the tool. Tool data creation means (NC device 2) for creating tool data, storage means (storage unit 2a) for storing the tool data created by the NC device 2 and a change history when the tool data is changed, Display means (HMI device 4) for displaying the data and the change history, so that the machining data including the change history of the set value and the count value relating to the tool life can be easily confirmed by the machining center 1 itself. it can.

In the above embodiment, the storage unit of the NC device is used as the storage unit, but the storage unit of the PLC device may be used.
Although the processing history data can be searched from the individual management number, the processing history data may be searchable from tool information such as a tool number.
Further, the present invention is applicable not only to a machining center as a machine tool but also to other machine tools such as a multi-tasking machine.

  1. Machining center, 2. NC device, 3. PLC device, 4. HMI device, 5. Eddy current sensor, 10. Operation status display button, 12 Program start history display button, 13. Shake detection history display button, 14 Tool counter button, 15 Shake detection button, 16 Individual control number search button, 19 Shake amount, 20 Individual control search screen, 21 Tool counter change history Display button.

Claims (1)

When machining a plurality of workpieces using a tool, tool data for creating tool data in which tool setting information for identifying the tool is associated with at least a set value relating to the life of the tool and a count value of an actual number of times of use. Creation means,
A storage unit that stores a change history when the tool data and the tool data created by the tool data creation unit are changed,
Display means for displaying the tool data and the change history,
A machine tool characterized by comprising:

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