JP2021092007A - Spinning pattern setting device in spinning frame - Google Patents

Abstract

To provide a spinning pattern setting device in a spinning frame capable of shortening a time required for setting a spinning pattern based on an image generated based on spinning pattern data.SOLUTION: A spinning pattern setting device comprises: a parameter input unit for inputting a parameter of a spinning yarn spun by a spinning frame; a pattern data generation unit for generating pattern data according to the parameter input to the parameter input unit; an image generation unit for generating an image generated based on the pattern data generated by the pattern data generation unit; and a display unit 17 for displaying the image generated by the image generation unit. The pattern data generation unit automatically generates pattern data independently of an operator's instruction, and the image generation unit generates an image each time the pattern data is generated, and updates and displays the image on the display unit 17.SELECTED DRAWING: Figure 2

Description

The present invention relates to a spinning pattern setting device in a spinning frame.

As a conventional technique related to a spinning pattern setting device in a spinning frame, for example, a device for operating and programming a ring spinning frame is known. The device for operating and programming the ring spinning machine of Patent Document 1 sets an operating device for operating the driving means according to a speed instruction, and a count and / or twisting progress along the length of the yarn. It comprises an electronic programming device that can be programmed for the purpose. The electronic programming device has a first interface suitable for designing the contour of the slab, and a conversion means suitable for converting the parameters of the contour of the designed slab into speed indications for the operating device. It has. In addition, the electronic programming device includes a second interface suitable for programming repetitions along the threads of a plurality of slabs designed by the first interface.

If the slab pattern data in the spinning frame can be set by this type of device, for example, it is possible to display an image image of a blackboard or an image image of a cloth pattern simulated based on the slab pattern data. The image of the blackboard is a simulation representation of the state in which the slab is wrapped around the blackboard, and the image of the cloth pattern is a simulation representation of a cloth woven with slab yarn spun based on the slab pattern data. Is.

Japanese Patent Application Laid-Open No. 2013-528728

In the conventional device, for the image image related to the slab simulation, after inputting all the slab parameters and confirming the slab pattern data, the determined slab pattern data is read into the simulator, and the image image based on the simulation is generated by the simulator. It was generating. Therefore, for example, when looking at an image of a blackboard or a cloth pattern and changing the slab pattern data because the desired design is not formed, the parameters that are thought to affect the design are corrected by prediction. After confirming the slab pattern data, the determined slab pattern data must be read into the simulator and the image image must be displayed again. If the redisplayed image still does not match the desired design, the work of parameter correction, slab pattern data confirmation, slab pattern data reading, and image image display must be repeated until they match, for parameter setting. The work was complicated and took a lot of time.

The present invention has been made in view of the above problems, and an object of the present invention is in a spinning frame capable of shortening the setting work time of a spinning pattern based on an image generated based on spinning pattern data. It is in the provision of a spinning pattern setting device.

In order to solve the above problems, the present invention has a parameter input unit for inputting parameters of spun yarn spun by a spinning machine, and a pattern data generation for generating pattern data with parameters input by the parameter input unit. The pattern data includes a unit, an image generation unit that generates an image based on the pattern data generated by the pattern data generation unit, and a display unit that displays the image generated by the image generation unit. The generation unit automatically generates the pattern data regardless of the instruction of the operator, and the image generation unit generates the image every time the pattern data is generated and updates and displays the image on the display unit. And.

In the present invention, the pattern data generation unit generates pattern data according to the input parameters. The image generation unit generates an image based on the generated pattern data. The display unit displays the image generated by the image generation unit. The pattern data generation unit automatically generates pattern data regardless of the operator's instruction, and the image generation unit generates an image each time the pattern data is generated and updates and displays it on the display unit. Therefore, the image is automatically updated and displayed on the display unit based on the pattern data being edited, so that the operator confirms the image generated based on the pattern data being edited during the editing of the pattern data. It is possible to grasp in real time how the image changes due to parameter changes. As a result, the parameter setting work based on the image generated by the image generation unit becomes simple, and the work time can be significantly shortened.

Further, in the spinning pattern setting device in the spinning frame, the image may be an image image simulated based on the pattern data.
In this case, the operator can confirm the simulated image image based on the pattern data being edited during the editing of the pattern data, and can grasp in real time how the image image changes due to the parameter change.

Further, in the spinning pattern setting device in the spinning frame, the image may be a distribution graph image generated based on the pattern data.
In this case, the operator can check the distribution graph image generated based on the pattern data being edited while editing the pattern data, and grasp in real time how the distribution graph image changes due to the parameter change. it can.

Further, in the spinning pattern setting device in the spinning frame, the pattern data generation unit may be configured to simultaneously display the parameter input screen displayed on the display unit and the image on the display unit.
In this case, since the operator can compare the input parameters and the image at the same time on the same screen, it is easy to grasp how the image changes due to the change of the parameters.

Further, in the spinning pattern setting device in the spinning frame, the spun yarn is a slab yarn, and the pattern data is defined by the pitch, the length, and the thickness of the slab yarn, which are parameters of the slab yarn. It may be configured as pattern data.
In this case, the slab pattern data can be generated based on the slab thread parameters pitch, length and slab thread thickness, and the image generated based on the slab pattern data and the slab parameter input screen are displayed. , Can be displayed.

Further, in the spinning pattern setting device in the spinning frame, the display unit may be configured to automatically update and display the image at preset time intervals.
In this case, the image displayed by the display unit is automatically updated and displayed at preset time intervals, so that when the parameter is changed, the image based on the simulation data in which the parameter change is reflected can be confirmed.

Further, in the spinning pattern setting device in the spinning frame, the display unit may be configured to update and display the image when the parameter is changed.
In this case, the image displayed by the display unit is updated and displayed each time the parameter is changed. Since the image is not updated when the parameter is not changed, the load on the device due to the updated display of the image can be reduced.

Further, in the spinning pattern setting device in the spinning frame, the display unit may be configured to update only the portion where the change has occurred in the image.
In this case, if the parameter is changed during the editing of the pattern data, only the changed portion is updated in the image displayed on the display unit, and the non-changed portion is not updated. As a result, as compared with the case of updating the entire image including the portion where the change does not occur, the flicker due to the image update is lessened, and the burden on the operator's eyes can be reduced.

According to the present invention, it is possible to provide a spinning pattern setting device in a spinning frame capable of shortening the setting work time of a spinning pattern based on an image generated based on the spinning pattern data.

It is a schematic block diagram of the spinning pattern setting apparatus in the spinning frame which concerns on 1st Embodiment. It is a figure which shows the display example in the display part. It is an enlarged view of the parameter input window in FIG. It is a figure which shows an example of the slab image window as an image image. It is a figure which shows an example of the cloth image window as an image image. It is a flow chart which shows the procedure of the update display of an image image. It is a figure which shows the display example in the display part which concerns on 2nd Embodiment. It is a figure which shows an example of the distribution graph window as a distribution graph image. It is a flow chart which shows the procedure of the update display of a distribution graph image. It is a flow chart which shows the procedure of the update display of the image image which concerns on another example.

Hereinafter, the spinning pattern setting device in the spinning frame according to the embodiment of the present invention will be described with reference to the drawings. In the present embodiment, a slab pattern setting device (hereinafter, simply referred to as “slab pattern setting device”) in a spinning machine that sets a slab pattern as a spinning pattern will be described as an example.

As shown in FIG. 1, the slab pattern setting device 10 includes a control unit 11, a program memory 12, a working memory 13, an input unit 14, an input interface 15, an output interface 16, a display unit 17, and data output. The unit 18 is provided.

The control unit 11 includes a CPU (not shown) that executes various programs. The control unit 11 is connected to the program memory 12 and the working memory 13. Further, the control unit 11 is connected to the input unit 14 via the input interface 15 and is also connected to the display unit 17 via the output interface 16. The control unit 11 corresponds to a pattern data generation unit that generates slab pattern data corresponding to the spinning pattern data.

The program memory 12 is a ROM which is a read-only memory, and stores various programs and data necessary for executing the programs. Various programs include a slab pattern data generation program that generates slab pattern data from slab thread parameters, a display program in which the display unit 17 displays an image as an image simulated based on the slab pattern data, and a display program. It is included. The control unit 11 corresponds to an image generation unit that generates an image based on pattern data. Furthermore, the control unit 11 corresponds to a simulation unit that generates an image as an image simulated based on the slab pattern data generated by the pattern data generation unit.

The working memory 13 is a readable and rewritable RAM, and has a function of temporarily storing data input from the input unit 14 and processing results by the control unit 11. Specifically, in the working memory 13, in addition to the parameters of the slab thread input from the input unit 14, the slab pattern data processed by the control unit 11 and the image image data of the slab thread based on the slab pattern data are stored. Will be done.

The input unit 14 corresponds to a parameter input unit, and is specifically a keyboard. By operating the input unit 14, the operator can input the slab parameters pitch (mm), length (mm) and slab thickness (%), and is also used for inputting various data. .. The pitch is the reference thickness of the slab, the length is the length of the slab, and the slab thickness is a percentage based on the pitch. The slab thickness is set to exceed 100%. The data input to the input unit 14 is transmitted to the control unit 11 via the input interface 15. Although the input unit 14 is a keyboard, it may be a touch panel having both a display function and an input function integrated with the display screen.

The display unit 17 is, for example, a liquid crystal display that displays various data and images. The display unit 17 is connected to the control unit 11 via the output interface 16. As shown in FIG. 2, the parameter input window 20 is displayed on the display screen 19 of the display unit 17. Further, the slab image window 21 and the cloth image window 22 are displayed on the display screen 19. In FIG. 2, the parameter input window 20 and the slab image window 21 are displayed, and the cloth image window 22 is not displayed. The slab image window 21 and the cloth image window 22 correspond to image images.

The data output unit 18 is connected to the control unit 11 via the output interface 16 and is an external storage device such as a USB memory, and can retrieve data and programs in the work memory 13.

Next, the parameter input window 20 displayed on the display screen 19 shown in FIGS. 2 and 3 will be described. The parameter input window 20 corresponds to a parameter input screen and is a window for displaying the parameters of the slab yarn that determines the slab pattern spun by the spinning frame. In the parameter input window 20, the parameters input by the input unit 14 are displayed. As shown in FIG. 3, the slab pattern is determined by inputting the slab yarn parameters pitch (mm), length (mm), and slab thickness (%) for each step for spinning the slab. To. In the present embodiment, the maximum number of steps that can be input for the parameter that determines the slab pattern is 1000 steps. The parameters displayed and input in the parameter input window 20 are transmitted to the control unit 11. Each time each parameter is input, it is transmitted to the control unit 11, and the control unit 11 generates slab pattern data.

The slab image window 21 is an image image simulated based on the slab pattern data based on the input data of each parameter. The slab image window 21 schematically shown in FIG. 2 shows a state in which the slab thread simulated by the control unit 11 based on the slab pattern data is wound around the blackboard. That is, the slab image window 21 is an image image obtained by simulating the spun slab yarn. FIG. 4 is an example of the slab image window 21. In the slab image window 21 shown in FIG. 4, the black part is the part where the blackboard can be seen, and the white part is the part showing the slab thread. In the slab image window 21, the slab threads are represented by white, and the slab threads are set to extend in the left-right direction and the slab threads are arranged in the vertical direction. The detailed setting regarding the representation of the slab image window 21 is performed through a window for setting (not shown) separate from the parameter input window 20.

The image of the simulation data is shown by the cloth image window 22 shown in FIG. 5, in addition to the slab image window 21 showing the image obtained by simulating the slab yarn. The cloth image window 22 is a window showing an image obtained by simulating a woven cloth using slab yarn. FIG. 5 is an example of the cloth image window 22. In the cloth image window 22, the weft is expressed by the simulated slab yarn, but it is possible to express the cloth image according to the weaving method such as plain weave or twill weave. In the cloth image window 22, the slab yarn extends in the left-right direction, and the warp yarn extends in the up-down direction. The detailed setting regarding the representation of the cloth image window 22 is performed through a window for setting (not shown) separate from the parameter input window 20.

On the display screen 19, the slab image window 21 and the cloth image window 22 are displayed at the same time as the parameter input window 20 by the display program. In the present embodiment, the first state in which the slab image window 21 is displayed at the same time as the parameter input window 20 and the second state in which the cloth image window 22 is displayed at the same time as the parameter input window 20 are selectively switched.

By the way, the slab pattern data is determined by inputting the parameters of the slab yarn of each step. The input parameter data is transmitted to the control unit 11, and the control unit 11 generates slab pattern data based on the parameters. The generated slab pattern data is transmitted to the control unit 11, and the control unit 11 generates slab image data or cloth image data simulated based on the slab pattern data. On the display unit 17, the slab image data or cloth image data generated by the control unit 11 is displayed as an image image. The image images are the slab image window 21 and the cloth image window 22.

Specifically, the update display of the slab image window 21 and the cloth image window 22 is performed by the procedure shown in FIG. When the preset set time periodically elapses (see step S01), the control unit 11 outputs the slab pattern data generated based on the parameters input at that time to the pattern data file. The pattern data is updated (see step S02). Since the pattern data file is automatically updated every set time regardless of the operator's instruction, if a part of the parameters is changed by the operator within the set time, the slab pattern data generated by the changed parameters will be displayed. It is reflected in the pattern data file and the pattern data file is updated. The set time is a set time in seconds (for example, 10 seconds), and can be changed in a window for setting different from the parameter input window 20.

Next, the control unit 11 generates simulated slab image data and cloth image data based on the pattern data file updated every set time, and updates and displays the image image displayed on the display screen 19. (See step S03). Specifically, the slab image window 21 and the cloth image window 22 displayed on the display screen 19 are updated and displayed. In the present embodiment, the pattern data file is periodically updated regardless of whether or not the parameters of the slab yarn are changed. Therefore, if the parameter is changed within the set period, the image is updated and displayed to reflect the parameter change, but if the parameter is not changed within the set period, the image does not change even if the parameter is updated.

Next, the operation of the slab pattern setting device 10 will be described. First, the operator activates the slab pattern setting device 10. By activating the slab pattern setting device 10, the parameter input window 20 can be displayed on the display screen 19 of the display unit 17, and the slab image window 21 and the cloth image window 22 can be displayed.

The operator displays the parameter input window 20 and inputs the parameters necessary for determining the slab pattern data by operating the input unit 14. Specifically, the input of the pitch (mm), the length (mm), and the slab thickness (%) is repeated for each step. The input parameters are displayed in the parameter input window 20.

The slab pattern data is output to a pattern data file, slab image data or cloth image data is generated based on the pattern data file, and an image image is displayed. The operator looks at the slab image window 21 and the cloth image window 22 displayed on the display screen 19 and determines whether or not to determine the slab pattern.

By the way, in the present embodiment, even in the editing process before the slab pattern data is determined, the slab pattern data is automatically output to the pattern data file at each set time, and the slab generated based on the pattern data file is generated. The image image based on the image data or the cloth image data is updated and displayed. That is, even during the editing of the slab pattern data for inputting the parameters to the parameter input window 20, the slab image window 21 and the cloth image window 22 are updated and displayed based on the slab pattern data being edited.

The operator confirms an image image such as the slab image window 21 or the cloth image window 22 in the process of editing the slab pattern data, and then determines the final slab pattern data. It is also possible to change the slab pattern data by changing some parameters after the slab pattern data is confirmed. The operator may take the determined pattern data file into an external storage medium such as a USB memory via the data output unit 18 and input the pattern data file to the spinning frame (not shown). The spinning frame spins the slab based on the determined slab pattern data.

According to the slab pattern setting device 10 of the present embodiment, the following effects are obtained.
(1) The control unit 11 as the pattern data generation unit generates slab pattern data according to the parameters input by the input unit 14. The control unit 11 as a simulation unit generates a simulated image based on the generated slab pattern data. The display unit 17 displays an image image generated by the control unit 11. Therefore, since the image image is automatically updated and displayed on the display unit 17 based on the slab pattern data being edited, the operator simulated the slab pattern data during editing based on the slab pattern data being edited. The image can be confirmed, and how the image changes due to parameter changes can be grasped in real time. As a result, the parameter setting work based on the simulated image becomes simple, and the work time can be significantly shortened.

(2) The control unit 11 simultaneously displays the parameter input window 20 for inputting the parameters of the slab yarn displayed on the display unit 17 and the image image on the display unit 17. Therefore, the operator can compare the input parameter and the image image at the same time on the same screen, so that it is easy to understand how the image image changes due to the change of the parameter.

(3) The spun yarn is a slab, and the spun pattern data is slab pattern data defined by the pitch, length, and thickness of the slab yarn, which are parameters of the slab yarn. Therefore, slab pattern data can be generated based on the slab yarn parameters pitch, length, and slab yarn thickness, and the image image simulated based on the slab pattern data and the slab yarn parameter input window. 20 and can be displayed.

(4) The display unit 17 automatically updates and displays the image image at preset time intervals. Therefore, the image image displayed by the display unit 17 is automatically updated and displayed at preset time intervals. Therefore, when the parameter is changed, the image image based on the slab pattern data in which the parameter change is reflected is confirmed. be able to.

(5) The slab image window 21 as an image image can show a state in which the slab thread simulated based on the slab pattern data is wound around the blackboard. Further, the cloth image window 22 can show an image obtained by simulating a woven cloth using slab yarn. The slab image window 21 and the cloth image window 22 that simulate the slab pattern data being edited can be displayed.

(6) Since the image image reflecting the slab pattern data being edited is always displayed during the editing of the slab pattern data, the operator can always check the image image while editing the slab pattern data.

(Second embodiment)
Next, the spinning pattern setting device in the spinning frame according to the second embodiment will be described with reference to the drawings. The present embodiment is different from the first embodiment in that a distribution graph image as an image is displayed on the display device. In the present embodiment, the description of the first embodiment is incorporated for the same configuration as that of the first embodiment, and a common reference numeral is used.

As shown in FIG. 7, in the present embodiment, the parameter input window 20 is displayed on the display screen 19 of the display unit 17, and the distribution graph image 31 as an image is displayed. Although not shown in FIG. 7, the slab image window 21 and the cloth image window 22 can be displayed on the display screen 19.

The distribution graph image 31 is an image for visually showing the distribution of the slab pattern based on the slab pattern data based on the input data of each parameter. FIG. 8 is an example of the distribution graph image 31. The distribution graph image 31 shown in FIG. 8 has a range input unit 32, a distribution graph unit 33, and a numerical display unit 34. The range input unit 32 is an input unit for designating a range of length (mm) and thickness (%), which is parameter data of the slab yarn. The range input unit 32 has input fields 32A and 32B for designating a range of length (mm). Further, the range input unit 32 has input fields 32C and 32D for designating a range of thickness (%). Further, the range input unit 32 is provided with an OK button 32E for determining the range of the input length (mm) and thickness (%), as well as the length (mm) and thickness (%). A FULL button 32F is provided to specify the maximum range of.

The distribution graph unit 33 includes a length display cell group on the horizontal axis, a thickness display cell group on the vertical axis, and a number display cell group in which other cell groups are arranged in a matrix. The length display cell group has a plurality of length display cells 33A. The length display cell 33A is a cell that displays the length (mm) of the parameter data of the slab yarn. In the distribution graph unit 33, a plurality of (10) length display cells 33A indicating the length (mm) are arranged in the horizontal direction. The value displayed in the length display cell 33A is the value of the length (mm) of the parameter data included in the range of the length (mm) determined by the range input unit 32. The length displayed in the plurality of length display cells 33A increases from left to right.

The thickness display cell group has a plurality of thickness display cells 33B. The thickness display cell 33B is a cell that displays the thickness (%) of the parameter data of the slab yarn. In the distribution graph unit 33, a plurality of (10) thickness display cells 33B indicating the thickness (%) are arranged in the vertical direction. The value displayed in the thickness display cell 33B is the value of the thickness (%) of the parameter data included in the range of the thickness (%) determined by the range input unit 32. The thickness displayed in the plurality of thickness display cells 33B increases from the bottom to the top.

The number display cell group has a plurality of number display cells 33C arranged in a matrix. The number of number display cells 33C in this display cell group is 100 (10 × 10). In the number display cell 33C, the number of slabs specified by the length (mm) of the length display cell 33A and the thickness (%) of the thickness display cell 33B is displayed. Further, in the number display cell 33C, the brightness of the background of the number display cell 33C gradually decreases as the number of displayed cells increases.

The numerical display unit 34 is a portion where the minimum value, the average value, and the maximum value of the length (mm) and the thickness (%) of the distribution graph image 31 are displayed.

In the present embodiment, the distribution graph unit 33 arranges a plurality of number display cells 33C in a matrix with respect to a plurality of length display cells 33A on the horizontal axis and a plurality of thickness display cells 33B on the vertical axis. This is a graph showing the distribution of the number of slab yarns of a specific length (mm) and thickness (%).

On the display screen 19, the distribution graph image 31 is displayed at the same time as the parameter input window 20 by the display program. In the present embodiment, the slab image window 21 is displayed at the same time as the parameter input window 20, the cloth image window 22 is displayed at the same time as the parameter input window 20, and the distribution graph image 31 is the parameter input. The third state, which is displayed at the same time as the window 20, can be selectively switched.

By the way, the control unit 11 generates slab pattern data based on the parameters, and generates distribution graph image data based on the slab pattern data. In the display unit 17, the distribution graph image data generated by the control unit 11 is displayed as a distribution graph image 31 as an image.

Specifically, the update display of the distribution graph image 31 is performed by the procedure shown in FIG. When the parameters of the slab thread are input at the time of editing the slab pattern data (see step S11), the control unit 11 reflects the parameters input at that time in the slab pattern data and outputs the parameters to the pattern data file. Update the slab pattern data (see step S12). That is, when the parameter is input, the pattern data file is automatically updated regardless of the operator's instruction. Therefore, when a part of the parameter is changed by the operator, the slab pattern data generated by the changed parameter is reflected in the pattern data file, and the pattern data file is updated.

Next, the control unit 11 updates and displays the distribution graph image 31 displayed on the display screen 19 based on the pattern data file updated by the input of the parameter (see step S13). In the present embodiment, the pattern data file is updated each time the slab yarn parameter is changed. Therefore, when the parameter is changed, the distribution graph image 31 is updated and displayed to reflect the parameter change, but is not updated unless the parameter is changed.

Further, in the present embodiment, when the distribution graph image 31 is updated by inputting a parameter, in the distribution graph image 31 displayed on the display screen 19, only the portion where the change has occurred in the distribution graph unit 33 is updated and changed. The part that does not cause is not updated. In this case, when the parameter of the slab yarn is changed, the control unit 11 compares the slab pattern data before the change with the slab pattern data after the change, and if there is a difference in the distribution graph unit 33, the change occurs. Only the part where the change occurs in the distribution graph unit 33 is updated. The control unit 11 changes the distribution graph unit 33 in the comparison between the slab pattern data before the change and the slab pattern data after the change even if the parameters of the slab yarn are changed. If there is no difference, the distribution graph image 31 Do not update.

According to the present embodiment, when the parameter is changed, the control unit 11 automatically generates pattern data regardless of the operator's instruction, and generates a distribution graph image 31 each time the pattern data is generated. The display unit 17 updates and displays. Therefore, the operator can confirm the distribution graph image 31 generated based on the pattern data being edited during the editing of the pattern data, and how the distribution graph image 31 changes by changing the parameters. It can be grasped in real time. Further, the operator can visually grasp the distribution state of the slab yarn by checking the distribution graph image 31. In particular, the difference between the number display cell 33C in which a large number of lines is displayed and the number display cell 33C in which a small number of lines are displayed can be intuitively grasped by the difference in brightness.

According to the present embodiment, when the parameter is changed, the distribution graph image 31 is updated and displayed to reflect the change in the parameter, but if the parameter is not changed, the distribution graph image 31 is not updated. Therefore, the load on the device due to the updated display of the distribution graph image 31 can be reduced. Further, in the present embodiment, when the distribution graph image 31 is updated by inputting the parameters, in the distribution graph image 31 displayed on the display screen 19, only the portion that has changed due to the parameter change is updated, and the change is caused. The part that does not occur is not updated. As a result, as compared with the case where the entire distribution graph image 31 is updated including the portion where the change does not occur, the flicker due to the image update in the distribution graph image 31 is lessened, and the burden on the operator's eyes can be reduced.

Further, in the present embodiment, the range of the length (mm) and the thickness (%) displayed on the distribution graph unit 33 is changed by changing the value input to the range input unit 32 in the distribution graph image 31. Can be done.

The present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the gist of the invention. For example, the present invention may be modified as follows.

○ In the first and second embodiments, the slab pattern as the spinning pattern has been illustrated and described, but the spinning pattern is not limited to the slab pattern. The present invention can be applied not only to a slab pattern but also to a combination pattern of colors of spun yarn as a spun pattern. In this case, the parameters that determine the pattern are different from the parameters of the slab yarn.
○ In the first embodiment, the image image is automatically updated and displayed at a preset cycle by the display unit during editing of the slab pattern data, but this is not the case. For example, as shown in FIG. 10, when the parameters of the slab thread are input at the time of editing the slab pattern data, the pattern data file is updated to reflect the input parameters, and the pattern data file is updated based on the updated pattern data file. The image image may be updated and displayed. In this case, the image image displayed by the display unit is updated and displayed each time the parameter is input (or changed), and the image image is not updated when the parameter is not input (or changed). Therefore, it is possible to reduce the load on the device due to the updated display of the image image. In addition, instead of updating and displaying all of the image images at once, as in the second embodiment, only the parts that have changed due to the parameter change in the distribution graph image are updated, and the parts that do not change are the parts that do not change. You may not update it.
○ In the first and second embodiments, while editing the slab pattern data, the image reflecting the slab pattern data being edited is always displayed, but this is not the case. For example, the image may be temporarily hidden while the parameter is being input, and the image may be displayed after the parameter is input. Specifically, there is a case where the image overlaps with the parameter input screen during parameter input and part or all of the image is hidden.
○ In the first and second embodiments, the pattern data is output to the data file, but the present invention is not limited to this. The pattern data may be output by a means other than the output to the data file, and may be output by socket communication by the TCP / IP protocol, for example.
○ In the second embodiment, when the distribution graph image is updated by inputting the parameters, in the distribution graph image displayed on the display unit, only the part that has changed due to the parameter change is updated and no change occurs. The site was not updated, but it is not limited to this. For example, when the distribution graph image is updated by inputting a parameter, the entire distribution graph image may be updated including not only the portion where the change occurs but also the member which does not cause the change in the distribution graph image.
○ In the second embodiment, the distribution graph image is updated and displayed each time a parameter is input (or changed) during editing of the slab pattern data, but this is not the case. For example, the distribution graph image may be automatically updated and displayed at a preset cycle by the display unit during editing of the slab pattern data.

10 Slab pattern setting device 11 Control unit (spinning pattern data generation unit, image generation unit, simulation unit)
12 Program memory 13 Working memory 14 Input section (parameter input section)
15 Input interface 16 Output interface 17 Display unit 18 External memory 19 Display screen 20 Parameter input window (parameter input screen)
21 Slab image window (image image)
22 Cloth image window (image image)
31 Distribution graph image (image)
32 Range input unit 33 Distribution graph unit 34 Numerical display unit

Claims (8)

A parameter input unit for inputting the parameters of the spun yarn spun by the spinning frame,
A pattern data generation unit that generates pattern data based on the parameters input by the parameter input unit, and a pattern data generation unit.
An image generation unit that generates an image based on the pattern data generated by the pattern data generation unit, and an image generation unit.
It has a display unit for displaying the image generated by the image generation unit, and has a display unit.
The pattern data generation unit automatically generates the pattern data without an operator's instruction, and the image generation unit generates the image each time the pattern data is generated and updates and displays the image on the display unit. A spinning pattern setting device in a spinning frame. The spinning pattern setting device in a spinning frame according to claim 1, wherein the image is an image image simulated based on the pattern data. The spinning pattern setting device in a spinning frame according to claim 1, wherein the image is a distribution graph image generated based on the pattern data. The spinning pattern setting device in a spinning frame according to claim 1, wherein the pattern data generation unit simultaneously displays the parameter input screen displayed on the display unit and the image on the display unit. The spun yarn is a slab yarn and
The spinning frame according to any one of claims 1 to 3, wherein the pattern data is slab pattern data defined by pitch, length, and thickness of the slab yarn, which are parameters of the slab yarn. Spinning pattern setting device. The spinning pattern setting device in a spinning frame according to any one of claims 1 to 5, wherein the display unit automatically updates and displays the image at preset time intervals. The spinning pattern setting device in a spinning frame according to any one of claims 1 to 5, wherein the display unit updates and displays the image when the parameter is changed. The spinning pattern setting device in a spinning frame according to any one of claims 1 to 7, wherein the display unit updates only a portion where a change has occurred in the image.

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