JP2016030348A - Injection molding machine and display control method executed by injection molding machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To diminish operation load for observing a plurality of fundamental screens which display set data or supervisory data about an injection molding machine.SOLUTION: A screen for displaying set data and/or supervisory data about an injection molding machine whose display form is determined in advance is defined as a fundamental screen. Intrinsic screen-generating information is stored, which displays an intrinsic screen constituted by arbitrarily arranging a plurality of slave screens obtained by displaying a plurality of required fundamental screens selected from a plurality of types of fundamental screens by a predetermined display magnification ratio which are set for respective operator specific information, at a predetermined position in a predetermined region in a screen of a display part 71, the operator specific information is received, and the intrinsic screen-generating information corresponding to the operator specific information is acquired to display an intrinsic screen corresponding to the operator specific information at a predetermined region. The intrinsic screen contains at least one slave screen which displays supervisory data, and when there is an update of the supervisory data, the supervisory data of the intrinsic screen is renewed and displayed in a predetermined region, in the slave screen displaying the supervisory data included in the intrinsic screen.SELECTED DRAWING: Figure 3

Description

  The present invention is an injection molding machine for obtaining a molded product by melting a molding material such as resin or metal and injecting and filling it into a mold, and solidifying the molding material in the mold. The present invention relates to an injection molding machine that includes a display unit and an input unit that receives input from an operator and a display control unit that performs display control of a display unit in accordance with an input from the operator, and a display control method that is executed in the injection molding.

  In recent years, as shown in Patent Document 1, an injection molding machine including a display unit in which a touch panel is placed on a display is known. In addition, in the injection molding machine, a lot of setting data and a lot of monitoring data are provided for observing the operation status and operating conditions of the injection molding machine and setting the operating conditions as necessary. The operator selects a screen selection button on the display to display a basic screen for displaying desired setting data or monitoring data, and observes the desired setting data or monitoring data or changes the setting data. Yes. In addition, for example, a plurality of basic screens are classified into a plurality of layers in advance, and screen selection buttons for each basic screen belonging to each category are displayed on the touch panel in accordance with the selection of the classification. Further, a screen selection method is adopted in which the selected basic screen is displayed when selected.

  In Patent Document 1, screen selection buttons for switching the basic screen in an injection molding machine are divided into a first group related to the operation of the injection molding machine and a second group other than that, and screen selections belonging to the first group A technique is disclosed in which buttons are displayed in an arbitrary arrangement in a horizontal row on the upper stage of the screen, and screen selection buttons of the second group are displayed in a plurality of layers in the lower stage of the screen. Patent Document 2 displays a list of reduced images of a basic image in a form such as a so-called icon on a menu screen in a display unit used for monitoring and control of a manufacturing system or the like so that a user can select a desired reduced image. Discloses a technique for displaying a basic screen corresponding to a selected reduced image when is selected.

Japanese Patent No. 3806393 JP 60-227294 A

  Here, in an injection molding machine, it is often necessary to check specific monitoring data that is updated as needed, and even if work is performed using a basic screen that does not include specific monitoring data, In order to appropriately check the monitoring data, there has been a case where an operation of switching the screen to a basic screen for displaying specific monitoring data is frequently performed.

  However, according to the display method of Patent Document 1, in order to observe a basic screen on which specific monitoring data is displayed, from the state in which another basic screen is displayed, the screen selection button is selected and the corresponding basic is displayed. An operation to switch and display on the screen is required. Similarly, in the display method of Patent Document 2, in order to observe a basic screen displaying specific monitoring data, a menu screen is displayed once from a state in which another basic screen is displayed, and a list is displayed. An operation to select a reduced image is necessary. For this reason, in an injection molding machine, there is an increasing demand for reducing the operational burden of switching and displaying a plurality of basic screens and efficiently grasping the contents of a desired basic screen.

  In order to solve the above-described problems, a display control method according to the present invention displays in advance display setting data indicating operating conditions set in an injection molding machine and / or monitoring data indicating an operation status of the injection molding machine. A predetermined plurality of basic screens selected from a plurality of types of basic screens set for each operator specifying information, which is information for specifying an operator, with a screen having a determined form as a basic screen. A storage step for storing unique screen generation information representing a unique screen formed by arbitrarily arranging a plurality of sub-screens represented by display magnifications at predetermined positions in a predetermined area in the screen of the display unit; and the operator specifying information A receiving step for receiving the input, and acquiring the unique screen generation information corresponding to the received operator specifying information and displaying the unique screen corresponding to the operator specifying information in the predetermined area The display control step, and the unique screen includes at least one child screen representing the monitoring data, and when the monitoring data is updated in the child screen representing the monitoring data included in the unique screen An update display control step of updating the monitoring data of the unique screen and displaying the updated data in the predetermined area.

  Further, the injection molding machine according to the present invention is a screen in which a display form is determined in advance, which displays setting data indicating operating conditions set in the injection molding machine and / or monitoring data indicating the operating status of the injection molding machine. Is a basic screen, and a plurality of desired basic screens selected from a plurality of types of basic screens set for each operator specifying information, which is information for specifying an operator, are displayed at a predetermined display magnification. A storage unit for storing unique screen generation information representing a unique screen formed by arbitrarily arranging a child screen at a predetermined position in a predetermined area in the screen of the display unit, a display unit for displaying the unique screen, and the unique screen An injection molding machine comprising: an input unit that receives an input from an operator for displaying a screen; and a display control unit that performs display control of the display unit according to the input from the operator, wherein the display control Part is said A display control unit configured to acquire the unique screen generation information corresponding to the operator specifying information received from the force unit and display the unique screen on the display unit, wherein the unique screen represents the monitoring data. At least one screen, and the display control means updates the monitoring data of the specific screen when the monitoring data is updated in a sub-screen representing the monitoring data included in the specific screen. It is what is displayed on the said display part, It is characterized by the above-mentioned.

  The display control method according to the present invention includes a selection receiving step for receiving selection of the sub-screen on the displayed unique screen, and a selection screen that is the selected sub-screen is larger than the selected sub-screen. It is preferable to further include a selection screen display control step of displaying in a further predetermined area in the screen of the display unit together with the unique screen.

  The “setting data indicating the operating conditions set in the injection molding machine” means data indicating the setting conditions relating to the operation of the injection molding machine. For example, the setting data includes various setting values such as temperature, pressure, position, time, number of times, amount of molding material, number of molded products, warnings, etc. in various operations such as mold clamping, weighing, injection molding, mold opening, protrusion, and purge. This includes the determination conditions for data, the display format setting of various data, and the like. The setting data may be displayed in an arbitrary display format. For example, the setting data may be displayed in a graph, may be displayed in a meter format, or numerical data may be displayed as numerical data. It may be shown.

  Further, the “monitoring data indicating the operation status of the injection molding machine” means the measurement value obtained by measuring the operation status of the injection molding machine or data obtained by judging the measurement value under a predetermined condition. For example, the monitoring data includes measured values of pressure, position and temperature provided in the injection molding machine, the number of molded products produced by the injection device, the processing time required for each process, and the weight of the material weighed. Or the volume, error log, etc. are included. The monitoring data may be displayed in an arbitrary display format. For example, the monitoring data may be displayed in a graph, or numbers may be displayed as numerical data.

  In addition, the “basic screen” is a type of setting data or monitoring data, as long as the predetermined setting data or monitoring data can be displayed in a predetermined display form such as a predetermined display format and a predetermined screen design. The number and combination may be set arbitrarily, may be set to any display format such as numerical display, graph display, and character string display, and the screen design such as color and arrangement can be arbitrarily set. In addition, the sub-screen represents the basic screen at a predetermined display magnification. If the sub-screen is within the range that can be considered to substantially represent the basic screen, an element with a small area in the screen design or an aspect ratio can be omitted. Minor edits such as adjustments may be made. In addition, if the selection screen is within the range that can be regarded as substantially representing the basic screen corresponding to the child screen, small edits such as omission of elements with a small area in the screen design and adjustment of the aspect ratio can be performed. It may be done.

  The “unique screen” is set for each operator specifying information that is information for specifying an operator, and a plurality of desired basic screens selected from a plurality of types of basic screens are represented by a predetermined display magnification. The sub-screen is arbitrarily arranged at a predetermined position within a predetermined area in the screen of the display unit, and the setting data or monitoring data in each sub-screen is displayed in a size that can be visually confirmed. For example, the number, arrangement, and size of the sub-screens may be set arbitrarily. Depending on the size and resolution of the entire screen, the child screen size can be secured to the extent that the setting data or monitoring data indicated by the child screen can be seen while grasping more information on the unique screen. It is preferable to appropriately determine the number of. For example, in the case of a 15-inch vertical monitor, the number of sub-screens can be 10 or less, and it is more preferable that the number of sub-screens is 4-6. Further, for example, the sub-screens can be arranged in one or a plurality of rows in a predetermined direction such as a vertical direction or a horizontal direction. The plurality of sub-screens may have the same size or different sizes.

  Further, the above-mentioned “when the monitoring data is updated in the sub-screen representing the monitoring data included in the unique screen, the monitoring data of the unique screen is updated and displayed in the predetermined area” If there are multiple sub-screens that represent monitoring data, the monitoring data on the unique screen is generated by updating the monitoring data for at least one of the sub-screens that represent the monitoring data. If it is. Preferably, the monitoring data is updated and generated for as many child screens as possible among the child screens representing the monitoring data included in the unique screen.

  Further, according to the display control method and the injection molding machine of the present invention, the display form for displaying the setting data indicating the operating conditions set in the injection molding machine and / or the monitoring data indicating the operation status of the injection molding machine is determined in advance. The display unit displays a plurality of sub-screens representing a desired plurality of basic screens selected from a plurality of types of basic screens set for each operator specific information at a predetermined display magnification. Stores unique screen generation information representing a unique screen that is arbitrarily arranged at a predetermined position in a predetermined area of the screen, receives operator specific information, and specific screen generation information corresponding to the received operator specific information And a unique screen corresponding to the operator specifying information can be displayed in a predetermined area. In addition, the unique screen includes at least one child screen representing the monitoring data, and when monitoring data is updated in the child screen representing the monitoring data included in the unique screen, the monitoring data on the unique screen is updated to be a predetermined value. It can be displayed in the area.

  For this reason, when the operator inputs the operator specifying information, the operator can display a desired unique screen of the operator in which a plurality of predetermined sub-screens are arranged at predetermined positions according to the operator specifying information. it can. As a result, it is possible to reduce an operation burden for switching and displaying a desired basic screen, and it is possible to efficiently observe a plurality of basic screens. In addition, since the unique screen is updated and displayed when the monitoring data is updated in the sub-screen representing the monitoring data, the operator does not need to switch the display to the basic screen representing the monitoring data. The monitoring data updated at can be observed.

The schematic block diagram of the injection molding machine which concerns on one Embodiment of this invention. The functional block diagram of the control apparatus which comprises the injection molding machine of FIG. The figure which shows the example of a display screen. The figure which shows the example of a specific screen production | generation information table. The flowchart which shows the display control process of an injection molding machine. The figure which shows the example of the screen which registers and changes specific screen production | generation information. The figure which shows the example of the screen which preserve | saves specific screen production | generation information to an external recording medium.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of an injection molding machine and a display control method thereof according to the present invention will be described in detail with reference to the drawings. In each figure, corresponding elements are indicated by common symbols. FIG. 1 is a schematic view of an injection molding machine 1 according to an embodiment of the present invention.

  As shown in FIG. 1, an injection molding machine 1 includes a screw preplar type injection device 2 for injection molding a thermoplastic resin material, a mold 4, a mold clamping device (not shown), an input / output device 7, and an injection device. 2, a mold clamping device, and a control device 6 for controlling the input / output device 7. The input / output device 7 includes a display unit 71 that is a liquid crystal display, an input / output unit 74 that includes a touch panel 72 that is placed on the display unit 71 and an operation unit 73 that is provided with a plurality of operation buttons. .

  FIG. 2 is a functional block diagram of the control device 6 provided in the injection molding machine 1. The control device 6 is a standard computer including a storage unit 64 including a CPU (not shown), a memory (not shown), and a hard disk. The storage unit 64 shows a display control program that defines a display control method according to an embodiment of the present invention, various setting data that sets operating conditions of the injection molding machine 1, and the operating status of the injection molding machine 1. A basic screen which is a screen with a predetermined display form for displaying various types of monitoring data, setting data indicating operating conditions set in the injection molding machine 1 and / or monitoring data indicating the operating status of the injection molding machine For the control of the injection molding machine 1, the basic screen generation information to be displayed, the unique screen generation information table that associates the unique screen generation information that represents the unique screen set for each operator specifying information that is information for specifying the operator, and A necessary control program and various data necessary for executing the control program are stored. The specific screen is a predetermined sub-screen in the screen of the display unit 71 that represents a plurality of desired basic screens selected from a plurality of types of basic screens at a predetermined display magnification according to an operator's request. It is a screen that is arbitrarily arranged at a predetermined position in an area.

  The control device 6 accepts detection data from various detectors 50 provided in the injection device 2 and the mold clamping device by the CPU executing a control program, and analyzes the detection data based on a predetermined analysis condition. Based on the analyzed data 65 and the detected detection data and setting data, the driving unit 80 (various driving units, temperature adjusting unit, etc.) provided in the injection device 2, the mold 4, the mold clamping device, etc. It functions as a control means 66 for executing a desired injection molding operation in the injection molding machine 1 by performing feedback control. Further, the data analysis unit 65 stores the analyzed detection data in the storage unit 64 as monitoring data in a predetermined format.

  In addition, the control device 6 functions as a display control unit 60 that executes the display control method according to the embodiment of the present invention by a CPU (display control unit) executing a display control program. The display control unit 60 according to the embodiment of the present invention receives an operation unit 61 that receives an operator specifying information that is information for specifying an operator from the input unit 74, and an operation received with reference to the unique screen generation information table. Display data generating means 62 for generating display data representing the unique screen corresponding to the operator specifying information received based on the unique screen generation information corresponding to the operator specifying information, and the operator specifying received based on the generated display data Display instruction means 63 for displaying a unique screen corresponding to the information on the display unit. Further, the unique screen includes at least one child screen representing the monitoring data, and the display data generation unit 62 displays the unique screen when the monitoring data is updated in the child screen representing the monitoring data included in the unique screen. The display data to be represented is updated and generated, and the display instruction unit 63 causes the display unit 71 to display a unique screen based on the updated display data. Further, the display control means 60 updates the setting data in the storage unit 64 as appropriate based on the information received from the input unit 74 or loads the necessary information in the storage unit 64 and displays it on the display unit 71. Take control.

  Here, a display screen displayed on the display unit 71 by the injection molding machine 1 will be described. FIG. 3 shows an example of a display screen, and FIG. 4 shows an example of a unique screen generation information table for generating a unique screen included in the display screen of FIG.

  As shown in FIG. 3, the display screen includes a unique screen column R10 in which the sub-screen columns R1 to R6 are arranged at predetermined positions, and a mode selection column R8 that displays a list of selectable buttons indicating operation categories. When a classification button is selected, a function column R9 that displays a selection item preset according to the selected classification button, a selection screen column R7 that displays a selected basic screen, and other current items Various data display fields R11, R12, and R13 for displaying time, information on the basic operation status of the injection molding machine 1, messages, and the like are provided.

  The mode selection field R8 includes a plurality of predetermined operation categories for setting and confirming various functions of the injection molding machine 1, such as injection setting, mold opening / closing setting, temperature setting, production counter, process monitoring, maintenance, and customization screen. The classification button is displayed. In addition, when the operator selects a predetermined classification button other than the customization screen in the mode selection field R8, a basic screen selection button for selecting each basic screen corresponding to the selected classification button is set. The basic screen selection button is displayed in the function column R9, and when the operator further selects the desired basic screen selection button, the desired basic screen is displayed in the selection screen column R7. Each basic screen is set to display setting data indicating the operating conditions set in the injection molding machine and / or monitoring data indicating the operating status of the injection molding machine in a predetermined display form. It is a screen.

  In the selection screen column R7, one basic screen selected by the operator is displayed as a selection screen. In the state where the basic screen is displayed in the selection screen column R7, the number of setting data and / or monitoring data, the arrangement thereof, and the like are set so as to ensure visibility and operability. The monitoring data included in the selection screen is updated and displayed as needed according to the latest measured value. In addition, when the selection screen includes setting data, the selection screen is displayed so as to be able to accept changes in the setting data. The selection screen column R7 is set to have an area larger than each area of the sub-screen columns R1 to R6 in the unique screen column R10, and the selection screen is displayed together with the unique screen described later, and the selection screen The display magnification may be arbitrarily set within a range that is displayed larger than each child screen included in the unique screen.

  In the unique screen column R10, unique screens in which a maximum of six basic screens selected from a plurality of basic screens are arranged as sub-screens are displayed in the respective sub-screen columns R1 to R6. The unique screen is arranged in a predetermined position as a plurality of sub-screens each representing a desired plurality of basic screens at a predetermined display magnification, and the size of the data etc. in each sub-screen can be visually confirmed. The number and arrangement of the sub-screens may be arbitrarily set as long as they are displayed as follows.

  A unique screen is created for each operator based on a unique screen generation information table that defines, for each operator, unique screen generation information that associates operator identification information, multiple child screens, and arrangement information of multiple child screens. This is a screen customized so as to display a child screen composed of a desired basic screen at a desired position.

  Here, according to the analysis of the present inventor, each operator who operates the injection molding machine displays a basic screen corresponding to a limited amount of setting data and monitoring data to some extent according to matters necessary for a desired work purpose. It has been found that an operation of repeatedly observing and changing predetermined setting data as necessary is performed. For example, as the type of operator, the person in charge of injection condition determination who determines the conditions of the injection process, the person in charge of quality control such as product inspection, process monitoring data or injection waveform management and monitoring, and mold There may be a person in charge of general production work such as mounting, mold change, material replenishment, product boxing, mold maintenance, and a person in charge of maintenance work of an injection molding machine. Although these persons in charge have different work purposes and use different combinations of basic screens, the number of basic screens frequently checked by the same person in charge is often 20 or less.

  Therefore, in the present injection molding machine 1, as shown in FIG. 4, the unique screen generation information in which the plurality of sub-screens and the sub-screen fields R1 to R6 corresponding to the predetermined positions where the sub-screens are displayed is associated with the operator. A unique screen generation information table defined for each is generated in advance and stored in the storage unit 64, and the display of the injection molding machine 1 is displayed so that a unique screen customized for each operator can be displayed based on the unique screen generation information. Decided to do control.

  For example, in the example of FIG. 4, the operator A corresponds to the person in charge of determining the injection conditions, the operator B corresponds to the person in charge of quality control, and the operator C corresponds to the worker who performs general production work. The operator D corresponds to a person in charge of performing maintenance work. FIG. 3 shows an example of a unique screen corresponding to the operator A in FIG. For example, the operator A sets an injection design, a mold design, a cylinder heater setting, a mold temperature setting, an injection waveform, and a process monitoring waveform as a basic screen constituting a fixed screen.

  According to this injection molding machine 1, each operator selects a necessary basic screen as a sub-screen in advance, determines a desired arrangement of the sub-screen, and arranges the selected sub-screen at a desired position. If the unique screen generation information representing the unique screen is stored in the storage unit 64, a desired plurality of basic screens such as frequently used basic screens are always displayed as sub-screens by simply displaying the unique screen corresponding to the operator specifying information. Can be displayed. For this reason, the labor and time to repeat the display to the basic screen necessary for each work are reduced, and desired information can be grasped quickly and easily and the work can be performed efficiently. In addition, by limiting the number of sub-screens constituting the fixed screen and setting the sub-screen display position in a desired arrangement in advance, it is possible to determine which information is displayed at which position by the operator. It is easy to grasp efficiently and can reduce labor and time for searching for target information from a large number of information. Further, in the fixed display screen, it is preferable that the sub-screens are arranged close to each other. In this case, the operator can easily grasp each child screen, and can confirm necessary information efficiently and quickly.

  On the unique screen, setting data and monitoring data included in each basic screen are updated and displayed as needed. For this reason, each operator can always confirm desired monitoring data on the unique screen, and does not need to frequently perform an operation of switching the display to the basic screen representing the desired monitoring data. For this reason, an operator who has many opportunities to refer to the basic screen including the monitoring data can greatly improve the operation efficiency because the switching operation of the basic screen is greatly reduced. In the example of FIG. 4, the basic screen indicated by a thick frame is a basic screen including monitoring data.

  Further, the unique screen is displayed so as to be able to accept selection of a sub-screen, and the accepted sub-screen is configured to be displayed together with the unique screen as a selection screen. For this reason, the operator can display the basic screen corresponding to the child screen on the selection screen having a size larger than the child screen by one operation, and select and select the classification button and the screen selection button sequentially. The switching operation of the selection screen can be performed quickly and easily than displaying the screen. In addition, the design of the selection screen and the sub-screen that constitutes the unique screen is shared, and the selection screen is displayed when the operator selects the sub-screen. Easy to understand and easy to operate. In addition, since various necessary setting data and monitoring data are updated and displayed on the unique screen, the operator can change the setting data on the selection screen while accurately and quickly grasping a plurality of related information. It is possible to improve the accuracy and efficiency of the setting work. For example, when an abnormality is detected, a basic screen that reports the abnormality, a basic screen that shows the monitoring data that caused the abnormality, and a basic screen that shows the setting data that sets the judgment criteria for the abnormality, an error log, etc. By setting the unique screen so that it can be confirmed together, it is possible to analyze the abnormality quickly and accurately.

  In the present embodiment, as shown in FIG. 4, the selection screen is stored in the storage unit 64 in association with the operator specifying information. In FIG. 4, the unique screen generation information table is combined for each operator specifying information with the unique screen generation information and the selection screen generation information that is information for specifying the basic screen corresponding to the selection screen in one file. However, if the unique screen generation information and the selection screen generation information can be specified for each operator specifying information, the unique screen generation information and the selection screen generation information may be stored as separate files.

  If the selection screen and the basic screen in the unique screen can be recognized that the displayed items and the screen configuration are substantially the same, the size of the characters in the screen and the size of the graph are very small. May be different. Further, the display area for displaying the selection screen may be arranged at an arbitrary position on the display screen, and is preferably arranged at an observable position together with the unique screen and the selection screen.

  The flow of the display control process in the injection molding machine 1 of this embodiment will be described according to the flowchart of FIG.

  First, when the “customize screen selection” button indicating the operation category is selected in the mode selection column R8, the display control means 60 displays the operator selection button in the function column R9 so as to be selectable as shown in FIG. Let Then, when the operator touches one of the operator selection buttons displayed in the function column R9 and selects the operator, the reception unit 61 is selected based on the selected position on the screen. An input of operator specifying information for specifying an operator is accepted (S01).

  Next, the display data generation unit 62 loads (acquires) the unique screen generation information table from the storage unit 64 to the memory based on the received operator specifying information (S02).

  Here, for example, it is assumed that the operator specifying information of the operator A who is the person in charge of determining the molding conditions shown in FIG. 4 is selected. Then, the display data generation unit 62 specifies the unique screen generation information corresponding to the operator specifying information of the operator A with reference to the unique screen generation information table. Subsequently, the display data generating unit 62 generates an injection setting screen, a mold opening / closing setting screen, a cylinder heater setting screen, a mold temperature setting screen, an injection waveform screen, as sub-screens based on the specified unique screen generation information. Then, the process monitoring waveform screen is specified, and the sub-screen fields R1 to R6 on which each sub-screen is displayed are specified (S03). Then, the display data generation unit 62 stores, for each identified sub-screen, the setting data and / or monitoring data included in the basic screen corresponding to the sub-screen and basic screen generation information that defines the design of each display screen in the memory. Based on the basic screen definition information, predetermined setting data and / or monitoring data necessary for generating each child screen is loaded from the storage unit 64 into the memory (S04). Further, the display data generating unit 62 specifies a predetermined display magnification for reducing each basic screen so that each of the specified sub screens has a size corresponding to each of the sub screen columns R1 to R6.

  Next, the display data generation unit 62 refers to the unique screen generation information table and specifies the basic screen set in the selection screen corresponding to the operator specifying information of the operator A (S05). Further, the display data generating unit 62 specifies a predetermined display magnification for enlarging the basic screen so that the size corresponds to the selection screen field R7 with respect to the basic screen set as the selection screen. In the initial state, the selection screen is assumed to have a basic screen corresponding to the sub-screen field R1.

  The display data generating means 62 includes basic screen generation information corresponding to each of the sub-screen fields R1 to R6, setting data and / or monitoring data necessary for each of the sub-screens, and a predetermined number of basic screens corresponding to each of the sub-screens. Based on the display magnification, the basic screen generation information corresponding to the selection screen column R7, and the predetermined display magnification corresponding to the selection screen, the display data of the unique screen and the selection screen are generated (S06). Then, the display data generating means 62 displays the unique screen and the selection screen on the display unit 71 based on the generated display data (S07). Then, the display screen shown in FIG. 3 is displayed.

  In addition, the sub-screens included in the unique screen are displayed so as to be selectable. When the operator performs an operation of selecting a sub-screen displayed on the touch panel (S08, Y), the accepting unit 61 receives and acquires the selected sub-screen (S12). Then, the display data generation means 62 identifies the selected sub-screen as a selection screen (S05), updates the display data on the selection screen (S06), and gives a display instruction to the display unit 71 based on the updated display data. Send. The display unit 71 updates the selection screen based on the updated display data (S07).

  On the other hand, when the selection of the basic screen is not detected (S08, N), the accepting unit 61 determines whether the setting data has been changed on the selection screen. If the setting data is changed (S09, Y), the display data generating means 62 acquires the changed setting data (S13), and updates the display data of the selection screen and the unique screen. (S06), the processing after S07 is performed in order.

  If no change in the setting data is detected (S09, N), the display data generation unit 62 determines whether any of the monitoring data included in the child screen has been updated. When any of the monitoring data included in the child screen is changed (S10, Y), the display data generating unit 62 acquires the changed monitoring data (S14), and the unique screen and / or The display data of the selection screen is updated (S06), and the processes after S07 are performed in order. Until the receiving unit 61 receives a display end instruction (S11, Y), the display control unit 60 repeats the processes of S08-S10.

  A method for creating unique screen generation information and a file operation method according to this embodiment will be described. FIG. 6 is a diagram illustrating an example of a registration screen for unique screen generation information. FIG. 7 is a diagram illustrating an example of a file operation screen of unique screen generation information. When the operator selects a classification button indicating a customization screen from among the classification buttons displayed in the mode selection field R8, an operator selection for displaying a unique screen corresponding to the selected operator in the function field R9 A button, a “select” button for creating and changing the unique screen generation information, and a “file operation” button for performing a file operation of the unique screen generation information are displayed.

  When the operator selects the “select” button, an editing screen for creating and changing the unique screen generation information as shown in FIG. 6 is displayed. As shown in FIG. 6, the editing screen includes an operator registration field R28 for performing new registration, name change, or deletion of an operator, and an operator selection field R27 for selecting an operator for creating a unique screen. Basic screen selection columns R21 to R26 for registering basic screens corresponding to the sub-screen columns R1 to R6 are provided. When creating new unique screen generation information, the operator registers the operator name by entering the operator name in the operator registration field R28 and touching the registration button. Next, the operator displays the registered operators in a drop-down list format in the operator selection field R27, and selects his / her operator name from the displayed operators. In addition, the operator displays each basic screen in a selectable drop-down list format for each basic screen selection field R21 to R26, and the basic screen name corresponding to the desired basic screen from the displayed basic screen. Select. After the selection of the operator and the selection of the basic screen is completed, the unique screen generation information that associates the operator with the basic screen corresponding to each sub-screen column is created and stored by touching the setting registration button. Stored in the unit 64.

  Further, here, when newly creating unique screen generation information, the basic screen set in the sub-screen column R1 is initially set as a selection screen. When the selection screen is subsequently updated, the selection screen generation information is preferably updated based on the last updated selection screen. Moreover, the update registration of each selection screen may be performed at an arbitrary timing. For example, even if the unique screen generation information is updated based on the selection screen updated last in the shutdown process of the injection molding machine 1. Good. In addition, as long as it is possible to create and edit the unique screen generation information that defines the operator-specific information, a predetermined number of basic screens, and a predetermined position where each basic screen is displayed in parallel, any method for creating and editing the specific screen generation information Various methods may be adopted.

  Further, it is preferable that the unique screen generation information can be used in common among a plurality of injection molding machines having the display control function according to the present invention. For example, the display control unit 60 copies the unique screen generation information in a file format that can be used by another injection molding machine, and from the storage unit 64 to another storage medium, and from the other storage medium to the storage unit 64. It is preferable to provide a function. As an example, the present injection molding machine 1 is provided with a file operation option so that the unique screen generation information can be copied to a removable recording medium such as a USB memory. Specifically, when the operator selects the “file operation” button while the customization screen is selected, a file operation screen as shown in FIG. 7 is displayed. As shown in FIG. 7, the file operation screen includes a save target operator selection field R31 for selecting operator specifying information corresponding to the specific screen generation information to be stored, a storage destination designation field R32 for specific screen generation information, and a reading source. A reading source designation field R33 for specifying (recording medium storing unique screen generation information) and a target operator selection field R34 for selecting operator identification information corresponding to the unique screen generation information to be read are provided. It has been.

  In the example of FIG. 7, when copying the unique screen generation information from the storage unit 64 built in the injection molding machine 1 to another recording medium, it corresponds to the target unique screen generation information in the save target operator selection field R31. The specific screen generation information corresponding to the designated operator can be copied to another recording medium by selecting the operator to be selected, selecting the storage medium to be stored in the storage destination designation field R32, and touching the save button. On the other hand, when copying the unique screen generation information from another recording medium to the storage unit 64 built in the injection molding machine 1, the reading destination recording medium is designated in the reading destination designation field R33, and the target operator is selected. By selecting an operator corresponding to the target unique screen generation information in the field R34 and touching the read button, the unique screen generation information corresponding to the designated operator can be copied to the storage unit 64.

  As described above, the unique screen generation information can be used in common among multiple injection molding machines, reducing the trouble of setting and registering the unique screen, and refer to the unique screen common to each injection molding machine. Thus, various operations can be performed, so that the operation efficiency can be increased. Note that any method that enables the unique screen generation information to be used in common among a plurality of injection molding machines may be applied. By connecting the control devices of the respective injection molding machines with a network, the unique screen generation information common to the control devices of the respective injection molding machines may be used.

  According to the above embodiment, when the operator inputs the operator specifying information, the operator can display a unique screen in which a predetermined plurality of sub-screens are arranged at predetermined positions according to the operator specifying information. . For this reason, the operation burden for switching and displaying a desired basic screen can be reduced, and a plurality of basic screens can be efficiently observed. In addition, when the monitoring data is updated in the sub-screen that represents the monitoring data, the unique screen is updated and displayed. Therefore, even if the operator does not perform an operation to switch the display to the basic screen that represents the monitoring data, the unique screen is displayed. The monitoring data updated above can be observed.

  When the selection of the child screen is received on the displayed unique screen, the selection screen which is the selected child screen is displayed on the display unit 71 together with the unique screen in a predetermined size larger than the selected child screen. Therefore, it is possible to intuitively grasp a sub-screen corresponding to a desired basic screen from a plurality of sub-screens and select it with a simple operation. In addition, the setting data can be changed on the selection screen, and multiple sub-screens and selection screens are displayed on the display screen at the same time. Can be changed. Further, since the setting data is changed on a selection screen larger than the child screen, erroneous input can be suppressed as compared with the case where the setting data is changed on the child screen.

  In each embodiment shown above, each function of the display control means of the injection molding machine 1 is executed by installing the display control program of each embodiment in a computer. The computer may be a computer built in the injection molding machine 1 or a computer connected to the injection molding machine 1 via a network. The display control program that defines each function of the present invention is stored and distributed in a recording medium such as a DVD, CD-ROM, or USB memory, and installed in the computer from the recording medium. Alternatively, it is stored in a storage device of a computer connected to a network or a network storage in a state where it can be accessed from the outside, and is downloaded and installed on a computer constituting the display control means upon request.

  Below, the structure of the injection apparatus 2 in the injection molding machine 1 and the outline | summary of injection molding operation | movement are demonstrated. In the present embodiment, a screw preplasticating injection molding machine is exemplified. However, the present invention is not limited to this embodiment, and the present invention is not limited to the vertical, horizontal inline type, etc. The invention can be applied.

  In the present embodiment, the injection apparatus 2 includes a plasticizing unit 20 that plasticizes and melts a resin material, an injection unit 30 that injects and fills molten resin from the injection nozzle 33 toward the cavity space 4a in the mold 4, and A connecting member 40 connecting the plasticizing unit 20 and the injection unit 30 is provided in the molten resin communication path 40a.

  The plasticizing unit 20 includes a plasticizing cylinder 24 having a hopper 25 for supplying a resin material, a plasticizing screw 21 disposed in the plasticizing cylinder 24, and a rotation drive device 22 for rotating the plasticizing screw 21. And a non-return drive device 23 for slightly moving the plasticizing screw 21 back and forth.

  The injection unit 30 includes an injection cylinder 36, an injection plunger 31 disposed in the injection cylinder 36, an injection drive device 34 that is connected to the injection plunger 31 and includes a drive rod that moves the injection plunger 31 forward and backward, and an injection cylinder 36. And an injection nozzle 33 which is attached to the front end via a nozzle adapter 32. Further, as a space surrounded by the tip surface of the injection plunger 31, a facing surface 32 b formed in a shape corresponding to the tip surface at a position facing the tip surface in the nozzle adapter 32, and the cylinder hole of the injection cylinder 36. An injection chamber 35 is formed. The injection chamber 35 has a communication passage 32 a communicating with the inside of the plasticizing cylinder 24 through the communication passage 40 a of the connecting member 40 and an injection hole 33 a communicating with the tip of the injection nozzle 33.

  In addition, in the injection molding machine 1 and a mold clamping device and a mold (not shown), various detectors 50, a drive device, a temperature control device, and the like are provided for measuring and adjusting the pressure, position, and temperature at predetermined positions. Is provided. For example, the injection drive device 34 includes a position detector 51 for detecting the position and speed of the injection plunger 31 and a pressure detector 52 for detecting the injection pressure of the injection plunger 31. Further, on the outer periphery of the plasticizing cylinder 24, the injection cylinder 36, the nozzle adapter 32, the connecting member 40, the injection nozzle 33, etc., a temperature adjusting device such as a band heater (not shown) is appropriately provided. Further, the various drive devices are appropriately configured as a hydraulic type, a pneumatic type, an electric type, or the like.

  In the control device 6, the data analysis means 65 reads the actual detection values of the various detectors 50, and the control means 66 compares the read detection values with the preset setting data while setting the preset setting data. Each drive device and temperature control device are controlled by various drive drivers (not shown) so as to operate according to the above.

  An outline of the injection molding operation of the injection molding machine 1 will be described. First, a mold is placed, and the mold is clamped by a mold clamping device. Next, as a measuring step, the check driving device 23 retracts the plasticizing screw 21 and opens the opening of the communication passage 40a on the plasticizing cylinder 24 side. Then, the resin material supplied from the hopper 25 is injected through the communication passages 40a and 32a by the rotation of the plasticizing screw 21 while being plasticized and melted by the shearing heat generated by the rotation of the plasticizing screw 21 and the heating by the band heater. It is pushed out into the chamber 35. The molten resin that has flowed into the injection chamber 35 is measured by the distance by which the injection plunger 31 has moved backward while receiving a predetermined back pressure by moving the injection plunger 31 backward. When the metering is finished, the check driving device 23 advances the plasticizing screw 21 to close the opening of the communication passage 40a on the plasticizing cylinder 24 side. Next, as an injection process, the injection plunger 31 moves forward, and a filling process for filling the measured molten resin from the injection nozzle 33 toward the cavity space 4a in the mold 4 is performed. Thereafter, a pressure holding process is performed in which the injection plunger 31 applies a holding pressure in the cavity space 4a until the molten resin in the cavity space 4a is solidified. In the pressure-holding step, the insufficient amount of molten resin in the mold 4 is filled, including the heat shrinkage accompanying the cooling of the molten resin filled in the mold 4. When the pressure holding process is completed, the mold is opened by the mold clamping device, and the protruding operation is performed to remove the molded product from the mold 4. In addition, the remaining resin is discharged (purged) as necessary.

  The present invention described above can be implemented in various other forms without departing from the spirit and essential features of the present invention. Accordingly, the examples described herein are illustrative and should not be construed as limiting.

DESCRIPTION OF SYMBOLS 1 Injection molding machine 2 Injection apparatus 4 Mold 6 Control apparatus 60 Display control means 61 Reception means 62 Display data generation means 63 Display instruction means 64 Storage part 71 Display part 74 Input part
R1-R6 Sub-screen column
R10 unique screen column
R7 selection screen field

Claims (3)

Information for specifying an operator on the basis of a screen with a predetermined display form for displaying setting data indicating operating conditions set in the injection molding machine and / or monitoring data indicating the operating status of the injection molding machine A predetermined area in the screen of the display unit, which is set for each operator specifying information, and is a plurality of sub-screens representing the desired plurality of basic screens selected from the plurality of types of basic screens at a predetermined display magnification. A storage step of storing unique screen generation information representing a unique screen that is arbitrarily arranged at a predetermined position in
A reception step for receiving input of the operator identification information;
A display control step of acquiring the unique screen generation information corresponding to the received operator specifying information and displaying the unique screen corresponding to the operator specifying information in the predetermined area;
The unique screen includes at least one child screen representing the monitoring data,
An update display control step of updating the monitoring data of the unique screen and displaying it in the predetermined area when there is an update of the monitoring data in a sub-screen representing the monitoring data included in the unique screen. A display control method for an injection molding machine. A selection receiving step for receiving selection of the child screen on the displayed unique screen;
A selection screen display control step for displaying a selection screen that is the selected sub-screen in a predetermined size larger than the selected sub-screen together with the unique screen in a further predetermined area in the screen of the display unit; The display control method according to claim 1, further comprising: Information for specifying an operator on the basis of a screen with a predetermined display form for displaying setting data indicating operating conditions set in the injection molding machine and / or monitoring data indicating the operating status of the injection molding machine A predetermined area in the screen of the display unit, which is set for each operator specifying information, and is a plurality of sub-screens representing the desired plurality of basic screens selected from the plurality of types of basic screens at a predetermined display magnification. A storage unit for storing unique screen generation information representing a unique screen arbitrarily arranged at a predetermined position, a display unit for displaying the unique screen, and an operator input for displaying the unique screen. An injection molding machine comprising: an input unit that accepts; and a display control unit that performs display control of the display unit in response to an input from the operator,
The display control unit includes display control means for acquiring the unique screen generation information corresponding to the operator specifying information received from the input unit and displaying the unique screen on the display unit,
The unique screen includes at least one child screen representing the monitoring data,
The display means updates the monitoring data of the unique screen and causes the display unit to display the updated monitoring data when the monitoring data is updated in a sub-screen representing the monitoring data included in the unique screen. Characteristic injection molding machine.