DE102014205615B4 - Textile machine equipped with winding section and display control device - Google Patents

Abstract

A textile machine comprising: a plurality of winding units (1) arranged side by side, each winding unit comprising: a winding section (13) winding a yarn (Y) to form a package (P), and a detection section (141) which Vibrations detected during formation of the package; a display section (5) which displays information about each of the winding units; and a display control section (4c) that controls contents displayed on the display section, the display control section exercising control to cause the display section to display a graph (G) in which a vibration value of each of the winding units is visually side by side and to also display in the graph an abnormality determination level (L) that serves as a reference for determining whether the vibration is large.

Description

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to a textile machine equipped with a winding section and a display control device.

Description of the related art

Textile machines with a large number of winding units are known in the prior art. Such a textile machine is in Japanese Patent Application Laid-Open JP 2012-218,915A disclosed. A winding unit turns a bobbin and forms a package by winding a yarn on the rotating bobbin. For this purpose, the winding unit comprises a winding section which winds the yarn to form the yarn body.

However, since the yarn is wound by rotating the package, a vibration is generated in the winding unit due to the eccentricity and the like of the package. Therefore, in the conventional textile machines, particularly, for example, in the textile machine, the Japanese Patent Application Laid-Open JP H08-301 523 A or in the utility model application publication JP H04-118 462 U. discloses a vibration sensor installed in each winding unit to enable the magnitude of the vibration to be recognized. In the conventional textile machine, however, it is difficult to see exactly which winding unit has large vibrations among a large number of winding units arranged side by side. Therefore, there is a need for a technology to make it easier to recognize the winding unit with large vibrations among the winding units arranged side by side. There is also a need for an associated technology in which a user can set a reference to determine whether the vibrations are large.

JP H11 - 334 999 A relates to a textile machine and an information transmission system for a textile machine. An automatic winder includes an AC-DC converter board on which an electrical circuit is formed by mounting electronic components, sensors, and an information storage section. The sensors record a temperature, a voltage and an electrical current. The information storage section stores the temperature values, voltage values, and current values acquired at various times as load log information.

describes a method of winding a yarn and a winding device therefor. The frame of a winder is provided with a vibration pickup sensor that receives the vibration information generated by a winder and a storage device that detects and records the vibration information of the winder with the vibration pickup sensor when the yarn wound around a bobbin fixed on a spindle reaches a prescribed amount of bobbins , and an alarm device that generates an alarm when the respective values are higher than a previously entered setting value.

US 2010/0 157 301 A1 describes a threadline inspection method and carbon fiber manufacturing method using it. A test method for running thread lines tests parallel thread lines on the same surface. The test method for running yarn lines is provided with a first illuminating device and a line sensor for imaging the yarn lines on the first surface side of the running surface of the yarn lines and a second illuminating device on the second surface side, and includes a data processing device that receives data obtained from the row sensor processed, and a recording device which records data processed by the data processing device over time.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a technology for easily recognizing the winding unit with large vibrations among a plurality of winding units arranged side by side, and a technology associated with the above technology. This object is achieved with the features of the independent claims. Advantageous developments of the invention are the subject of the dependent claims.

According to a first aspect of the present invention, a textile machine includes a plurality of winding units arranged side by side, a display section that displays information about each of the winding units, and a display control section that controls contents displayed on the display section. Each winding unit includes a winding section that winds a yarn to form a package, and a detection section that detects vibrations during the formation of the package. The display control section exerts control to cause the display section to display a graph in which a vibration value of each of the winding units is visually arranged side by side, and also in the graph Display abnormality determination level, which serves as a reference for determining whether the vibration is large.

According to a second aspect of the present invention, the textile machine according to the first aspect further comprises an adjustment section capable of setting the abnormality determination level, and the display control section exerts control to cause the display section to adjust the abnormality determination level set by the adjustment section displays.

According to a third aspect of the present invention, the display control section in the textile machine according to the second aspect exercises control to cause the display section to shift an abnormality determination level, following the operation of the setting section, with the graph on the display section is displayed.

According to a fourth aspect of the present invention, the textile machine according to any one of the first to third aspects further includes a storage section that stores therein the abnormality determination level for each winding state, and the display control section exerts control to cause the display section to leave the The memory section reads and displays the abnormality determination level according to a selected winding state.

According to a fifth aspect of the present invention, the display control section in the textile machine according to the fourth aspect exercises control such that when the abnormality determination level for a first winding state is changed, the abnormality determination level for a second winding state stored in the storage section is changed , based on an amount of change in the abnormality determination level for the first winding state.

According to a sixth aspect of the present invention, the display control section in the textile machine according to the fifth aspect exercises control such that when the abnormality determination level for the first winding state is changed by a predetermined change rate, the abnormality determination level for the second one in the storage section stored winding state is changed by the same rate of change as that of the abnormality determination level for the first winding state.

According to a seventh aspect of the present invention, the display control section in the textile machine according to any one of the first to sixth aspects exercises control to cause the display section to display different graphs for a period of time until a yarn layer thickness reaches a predetermined value, and for a period afterwards.

According to an eighth aspect of the present invention, the display control section in the textile machine according to any one of the first to seventh aspects exercises control to cause the display section to display the graph for each vibration detection direction.

According to a ninth aspect of the present invention, the winding unit in the textile machine according to any one of the first to eighth aspects further comprises a yarn cutter capable of cutting the yarn, and the display control section in the graph does not reflect vibrations caused by the operation of the thread cutting device.

According to a tenth aspect of the present invention, the display control section in the textile machine according to any one of the first to ninth aspects exercises control to cause the display section to display the graph package by package.

According to an eleventh aspect of the present invention, the display control section in the textile machine according to the tenth aspect exercises control to cause the display section to display the graph at the time of forming the last package.

According to a twelfth aspect of the present invention, when the first package is formed, the display control section in the textile machine according to the tenth or eleventh aspect exerts control to cause the display section to display the graph of the package being wound .

According to a thirteenth aspect of the present invention, the sensing portion in the textile machine according to any one of the first to twelfth aspects is attached to an electronic circuit board housed in the winding unit.

According to a fourteenth aspect of the present invention, the winding unit of the textile machine according to one of the first to twelfth aspects comprises a cage or bobbin which rotatably supports the package, and the detection section is attached to the cage.

A fifteenth aspect of the present invention relates to a display control device of a textile machine. The textile machine includes a plurality of winding units arranged side by side and a display section which displays information about each of the winding units. Each winding unit includes a winding section that winds a yarn to form a package, and a detection section that detects vibrations during the formation of the package. The display controller generates signals to cause the display section to display a graph in which a vibration value of each of the winding units is visually arranged side by side, and also to display in the graph an abnormality determination level, which is used as a reference for determination, whether the vibration is large serves.

According to a sixteenth aspect of the present invention, the display control device according to the fifteenth aspect further comprises a setting section capable of setting the abnormality determination level, and the display control device generates a signal to cause the display section to do so by the setting section set the abnormality determination level.

According to a seventeenth aspect of the present invention, the display controller according to the sixteenth aspect generates a signal to cause the display section to shift the abnormality determination level following the operation of the setting section, and the graph is displayed on the display section.

An eighteenth aspect of the present invention relates to a control program for executing on a textile machine. The textile machine includes a plurality of winding units arranged side by side and a display section which displays information about each of the winding units. Each winding unit includes a winding section that winds a yarn to form a package, and a detection section that detects vibrations during the formation of the package. The control program executes a process to make the display section display a graph in which a vibration value of each of the winding units is visually arranged side by side, and also to display in the graph an abnormality determination level, which is used as a reference for determining, whether the vibration is large serves.

According to a nineteenth aspect of the present invention, the control program according to the eighteenth aspect further realizes a setting section capable of setting the abnormality determination level, and the control program executes a process to cause the display section to display the abnormality determination level set by the setting section.

According to a twentieth aspect of the present invention, the control program according to the nineteenth aspect executes a process to cause the display section to shift the abnormality determination level following the operation of the setting section, with the graph being displayed on the display section.

According to the first aspect of the present invention, the display control section exerts control to cause the display section to display the graph in which a vibration value of each of the winding units is visually arranged side by side, and also in the graph Display abnormality determination level, which serves as a reference for determining whether the vibration is large. As a result, the winding unit with large vibrations can be easily recognized under the winding units arranged side by side.

According to the second aspect of the present invention, the display control section exerts control to cause the display section to display the abnormality determination level set by the setting section. As a result, the reference for determining whether the vibrations are large can be set as desired.

According to the third aspect of the present invention, the display control section exerts control to cause the display section to shift the abnormality determination level following the operation of the setting section, and the graph is displayed on the display section. Accordingly, the reference for determining whether the vibrations are large can be set while referring to the actual magnitude of the vibration values.

According to the fourth aspect of the present invention, the display control section exerts control to cause the display section to read from the storage section and display the abnormality determination level according to a selected wrapping state. Consequently, even if the winding conditions vary, an appropriate abnormality determination level can be set.

According to the fifth aspect of the present invention, the display control section exerts control such that when the abnormality determination level for the first winding state is changed, that Abnormality determination level for the second winding state stored in the storage section is changed based on an amount of change in the abnormality determination level for the first winding state.

As a result, time and effort for changing the abnormality determination level for each winding state can be saved. According to the sixth aspect of the present invention, the display control section exercises control such that when the abnormality determination level for the first winding state is changed by a predetermined change rate, the abnormality determination level for the second winding state stored in the storage section is changed by the same change rate how to change that of the abnormality determination level for the first winding state. As a result, the abnormality determination level can be optimized for each winding condition.

According to the seventh aspect of the present invention, the display control section exerts control to cause the display section to display different graphs for a period until a yarn layer thickness reaches a predetermined value and for the period thereafter. As a result, the winding unit with large vibrations is recognized with high accuracy.

According to the eighth aspect of the present invention, the display control section exercises control to cause the display section to display the graph for each vibration detection direction. As a result, the winding unit with large vibrations is recognized with even higher accuracy.

According to the ninth aspect of the present invention, the display control section in the graph does not reproduce vibrations caused by the operation of the yarn cutter. As a result, the winding unit with large vibrations is recognized with high accuracy.

According to the tenth aspect of the present invention, the display control section exercises control to cause the display section to display the graph per package. As a result, the content displayed on the display section can be simplified.

According to the eleventh aspect of the present invention, the display control section exerts control to cause the display section to display the graph obtained when the last package is formed. Accordingly, it can be determined whether the vibration at the time of forming the last package P was great.

According to the twelfth aspect of the present invention, when the first package is formed, the display control section exercises control to cause the display section to display the graph of the package that is being wound. As a result, the winder can be prevented from being displayed on the graph with no vibration value.

According to the thirteenth aspect of the present invention, the detection section is attached to the electronic circuit board accommodated in the winding unit. As a result, the structure of the winding unit can be simplified.

According to the fourteenth aspect of the present invention, the detection portion is attached to the cradle. As a result, only the vibrations generated during the formation of the package by the winding unit are detected.

According to the fifteenth aspect of the present invention, the display control section generates the signals to cause the display section to display a graph in which a vibration value of each of the winding units is visually arranged side by side, and to also generate an abnormality determination level in the graph which serves as a reference for determining whether the vibration is large. As a result, the winding unit with large vibrations can be easily recognized among the plurality of winding units arranged side by side.

According to the sixteenth aspect of the present invention, the display controller generates the signal to cause the display section to display the abnormality determination level set by the setting section. As a result, the reference for determining whether the vibrations are large can be set arbitrarily.

According to the seventeenth aspect of the present invention, the display controller generates the signal to cause the display section to shift the abnormality determination level following the operation of the setting section, and the graph is displayed on the display section. Accordingly, the reference for determining whether the vibrations are large can be set while referring to the actual magnitude of the vibration values.

According to the eighteenth aspect of the present invention, the control program executes a process for causing the display section to display a graph in which a vibration value of each of the winding units is visually arranged side by side, and also in that Graphs to display an abnormality determination level, which serves as a reference for determining whether the vibration is large. As a result, the winding unit with large vibrations can be easily recognized under the winding units arranged side by side.

According to the nineteenth aspect of the present invention, the control program executes the process to cause the display section to display the abnormality determination level set by the setting section. As a result, the reference for determining whether the vibrations are large can be set arbitrarily.

According to the twentieth aspect of the present invention, the control program executes the process to cause the display section to shift the abnormality determination level following the operation of the setting section, and the graph is displayed on the display section. Accordingly, the reference for determining whether the vibrations are large can be set while referring to the actual magnitude of the vibration values.

The above and other objects, features, advantages, and the technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention when taken in conjunction with the accompanying drawings.

Figure list

• 1 Fig. 12 is a drawing of an entire structure of an automatic winding machine;
• 2nd Fig. 12 is a drawing of a structure of a winding unit and a control system thereof;
• 3rd Fig. 12 is an image of a graph in which a vibration value of each of the winding units is visually arranged side by side;
• 4th Fig. 12 is an image of an adjustment section capable of setting an abnormality determination level;
• 5 Fig. 14 shows how the abnormality determination level is shifted following the operation of the setting section;
• 6A Fig. 14 shows the function that the abnormality determination level corresponding to a first winding state is displayed;
• 6B shows the function that the abnormality determination level corresponding to a second winding state is displayed;
• 7A shows how the abnormality determination level is changed for the first winding state;
• 7B shows how the abnormality determination level is changed for the second winding state;
• 8th shows different graphs, one for a period until a yarn layer thickness of a package reaches a predetermined value, and the other for a period thereafter;
• 9 shows a graph for each vibration detection direction; and
• 10th shows different graphs, one for the period until the yarn layer thickness of the package reaches the predetermined value and the other for the period thereafter, together with a graph for each vibration detection direction.

DETAILED DESCRIPTION

A textile machine according to an embodiment of the present invention is first explained in a simple manner. The technical idea of the present invention is not on an automatic winding machine 100 limited, which is explained below, and can also be applied to other textile machines (for example an air-jet spinning machine or an open-end spinning machine).

1 Fig. 12 is a drawing of an overall structure of the automatic winding machine 100 . The automatic winding machine 100 mainly comprises winding units 1 , a transport device 2nd , a customer ("doffing device") 3rd , and a control device 4th (Machine control section). The control device or the control device 4th is used by all of the winding units 1 of the machine, and is located at one end of the machine.

The winding unit 1 wraps a yarn Y from a (yarn) spool B1, and winds the unwound yarn Y around a spool of thread B2 to a package P to train. During the package P is formed, the winding unit is removed 1 any faulty section of the yarn Y to the quality of the yarn Y to improve. In this way, the winding unit 1 a package P train with a stable quality. Each winding unit 1 includes a unit control section or a control section of a unit 14 (please refer 2nd ). The unit control section 14 is with the transport device 2nd and the customer 3rd via the control device 4th electrically connected. Thus, the unit control section allows 14 transmission and reception of electrical signals between the Control device 4th , the transport device 2nd and the customer 3rd .

The transport device 2nd transports the spool of thread B1 with the yarn Y therefore wound up to each of the winding units 1 . In this way, the transport device delivers 2nd the yarn Y to each winding unit 1 . The transport device 2nd also transports the empty spool of thread B1 to a prescribed location after the yarn is off the bobbin B1 was handled. The transport device 2nd includes a transport control section, not shown. The transport control section is with each of the winding units 1 and the customer 3rd via the control device 4th electrically connected. Thus, the transport control section allows transmission and reception of electrical signals between the control device 4th , the winding units 1 and the customer 3rd .

The customer 3rd has a function, the bobbin B2 from the winding unit 1 to remove and the twine P from each of the spools of thread B2 to collect. The customer thus allows 3rd collecting the completely wound package P from the winding units 1 . The customer 3rd also has a function, an unused spool of thread B2 into the winding unit 1 to put. The customer 3rd includes a customer control section, not shown. The customer control section is with each of the winding units 1 and the transport device 2nd via the control device 4th electrically connected. Thus, the customer control section allows transmission and reception of electrical signals between the control device 4th , the winding units 1 and the transport device 2nd .

The control device 4th recognizes the operating state of each of the winding units 1 , the transport device 2nd and the customer 3rd . In addition, the control device 4th Drive action commands to each of the winding units 1 , the transportation device 2nd and the customer 3rd output. In this way, the control device performs 4th coordination between the control objectives, namely the winding units 1 , the transport device 2nd and the customer 3rd . The control device 4th collects information showing the operational state from the unit control section 14 each of the winding units 1 affect. The controller collecting information 4th is carried out periodically, for example. The through the control device 4th Information collected includes vibration information generated by a detection section 141 is detected, which will be explained later. The control device 4th includes the function of a display control section 4c (please refer 2nd ). The display control section 4c controls the display of content on a display section 5 . The display section 5 the automatic winding machine 100 is a touch panel, and therefore information can also be obtained from the display section 5 can be entered.

The winding unit 1 is explained in detail below.

2nd Fig. 12 is a drawing of a structure of the winding unit 1 and a tax system thereof. The winding unit 1 mainly comprises a yarn feeding section 11 , a processing section 12th and a winding section 13 . The winding unit 1 also includes the unit control section 14 .

The yarn feed section 11 has a configuration which allows the yarn package B1 is set or fixed. During the winding process, the yarn Y from that to the yarn feed section 11 set spool of thread B1 handled. The yarn feed section 11 includes an unwinder 111 . The unwinder 111 regulates the yarn Y which from the spool of thread B1 is unwound so that the yarn Y does not scatter or spread due to the centrifugal force.

The processing section 12th removes any faulty section of the yarn Y . The processing section 12th comprises a voltage application device 121 , a defect detection device 122 , a thread cutting device 123 and a yarn joining device 124 . The voltage application device 121 brings a predetermined tension to that from the package B1 unwound yarn Y on. The defect detection device 122 detects the faulty section of the yarn Y based on one of the yarn Y shielded amount of light. The thread cutting device 123 separates the yarn Y when the defect detection device 122 detected that a faulty section in the yarn Y is. A yarn separation signal output in the yarn separation is in the unit control section 14 is entered, and thereby the unit control section recognizes 14 that the yarn cutter 123 was operated. The yarn joining device 124 adds the broken yarn Y if a yarn break occurs or if the yarn Y through the thread cutting device 123 is separated. The term "defective section" refers to a section of the yarn Y which is too thin or too thick, or where there is a foreign body with the yarn Y is mixed.

The winding section 13 wraps the yarn Y to the package P to train. The winding section 13 includes a spool support 131 and a spool rotating device 132 . The spool support device 131 supports the spool in a rotatable or rotatable manner B2 or the package P , the one on the spool of thread B2 is trained. The spool rotating device 132 turns the spool of thread B2 or the one on the spool of thread B2 trained package P .

The spool support device 131 is explained in detail below. The spool support device 131 mainly includes a cage 131a . The cage 131a rotatably supports the thread spool B2 or the package P on the spool of thread B2 is formed in an insert-held state. The cage 131a can be swiveled around an axis of rotation. This feature allows the cage 131 a contact with a traverse drum explained later 132b at a constant load, even if the outer diameter of the package P with winding the yarn Y increases. Furthermore, a yarn layer thickness (thickness of the portion where the yarn is wound) of the package P by detecting a swing angle of the cage 131a be recognized.

The spool rotating device 132 is explained in detail below. The spool rotating device 132 mainly includes an electric motor 132a and the traversing drum 132b . The electric motor 132a is driven based on instructions from an engine control section 132c be issued. The traversing drum 132b is determined by the torque of the electric motor 132a turned. Because the spool of thread B2 (or the package P ) with the traversing drum 132b the bobbin turns B2 (or the package P ) when the traversing drum 132b is rotated. The yarn Y is guided along spiral grooves on an outer circumferential surface of the traversing drum 132b are provided. Thus the traversing drum oscillates 132b the yarn Y . By traversing the yarn Y , the traverse drum 132b sure the yarn Y evenly over the package P is wrapped.

The unit control section 14 detects the operating conditions of the yarn feeding section 11 , the processing section 12th and the winding section 13 . The unit control section 14 also gives drive operation commands to the yarn feed section 11 , the processing section 12th and the winding section 13 out. The unit control section 14 comprises a CPU ("Central Processing Unit"), a ROM ("Read Only Memory") and a RAM ("Random Access Memory"). The CPU is an arithmetic processing device that executes control programs. The ROM is a storage medium that stores the control programs in it. The RAM is a storage medium that temporarily stores data in it when the control programs are executed. All of the winding units 1 that the automatic winding machine 100 form, point the detection section 141 in the unit control section 14 on. The acquisition section 141 is a vibration sensor that detects vibrations during the formation of the package P occur. That is, the acquisition section 141 is a vibration sensor that detects an amount of vibration that occurs during the formation of the package P is produced. The acquisition section 141 is on an electronic circuit board 142 appropriate. The CPU, ROM and RAM are also on the electronic circuit board 142 appropriate. The unit control section 14 always stores updated vibration detection values by the detection section 141 are detected in a storage section. The in the storage section of the unit control section 14 Stored vibration detection values are sent to the control device 4th on requests from the controller 4th transfer. The timing or the time specified by the control device 4th made request for the vibration detection values to the unit control section 14 can be periodic or non-periodic. The unit control section 14 can voluntarily send the vibration detection values to the control device 4th transmitted without any request from the controller 4th . The control device 4th stores those from the unit storage section 14 received vibration detection values in the storage section.

Because the capture section 141 on the in the winding unit 1 recorded electronic circuit board 142 is not long wiring to connect the electronic circuit board 142 of the unit control section 14 and the detection section 141 required, and this can simplify the structure of the winding unit 1 will be realized. In an alternative embodiment, the detection section 141 on the cage 131a to be appropriate. With this arrangement, only the vibrations are detected during the formation of the package P through the winding unit 1 are generated, and not the vibrations of the thread cutter 123 or the yarn joining device 124 or similar.

The on the display section 5 displayed content is explained in detail below.

3rd is an image of a graph G in which the vibration value of each of the winding units 1 is arranged visually side by side. 4th is an image of an adjustment section 53 capable of an abnormality determination level L adjust.

A graph view frame 51 is provided in this graphic. The graph view frame 51 shows the graph G (Bar chart) in which the vibration value of each of the winding units 1 is arranged visually side by side. The graph G shows the maximum value of the order of magnitude Vibration value (height of the bar) from each winding unit 1 in the process of forming a package P . The abnormality determination level L , which serves as a reference for determining whether the vibration is large, is in the graph view frame 51 displayed. The abnormality determination level L is a straight line that extends in the direction in which the bars are placed. The display of the components of the graph G is through the display control section 4c controlled.

The display control section 4c thus exerts control over the graph G indicate in which the vibration value of each of the winding units 1 is arranged visually side by side. The display control section 4c also exerts control over the graph G the abnormality determination level L display, which serves as a reference for determining whether the vibration is large. If the bar that acts as a visual representation of the vibration value, the abnormality determination level L crosses, it indicates that the vibration is large. With the help of such a graph, an operator can use the winding unit 1 which has a large vibration, slightly below the winding units arranged side by side 1 detect. As in 3rd etc. shown, a display style (display color) of the winding unit differs 1 , the bar of which is the abnormality determination level L crosses from that of the other winding units 1 . That is, those bars under the bars that the graph G with the upper ends of the abnormality determination level L cross, have a display style that differs from that of the other bars. This allows the operator to change the winding units 1 which is the abnormality determination level L cross, easily recognized. In addition, a warning lamp can be lit or a warning buzzer can be rung from those winding units 1 whose vibration detection values are the abnormality determination level L cross. With this arrangement, the operator can more easily use those winding units 1 under the winding units arranged side by side 1 recognize whose vibrations are large.

A symbol or icon 52 is provided in this picture. When you touch the symbol 52 becomes a screen for setting the abnormality determination level L displayed. This screen can be the setting section 53 to be named. In an alternative embodiment, the adjustment section 53 a keyboard, etc., which allows information to be entered into the controller 4th can be entered. Immediately setting the abnormality determination level L is completed, the newly set abnormality determination level L in the graph view frame 51 displayed.

The display control section 4c thus exerts control to do this by using the setting section 53 set abnormality determination level L display. The operator can therefore set a desired reference to determine whether the vibrations are large.

5 shows how the abnormality determination level L is moved, the operation of the setting section 53 following. An in 5 area R shown shows the shifted abnormality determination level L .

As explained above, the adjustment range 53 for setting the abnormality determination level L on the display section 5 displayed. That in the graph view frame 51 indicated abnormality determination level L moves up or down (see an arrow M ) if the setting section 53 is operated. That is, in the graph view frame 51 indicated abnormality determination level L shifts, the operation of the adjustment section 53 following.

The display control section 4c exerts control to the abnormality determination level L to move, following the operation of the setting section 53 , where the graph G on the display section 5 is shown. In this way, the reference for determining whether the actual vibrations are large can be set while referring to the actual magnitude (variation) of the vibration values. For example, as in 5 shown the abnormality determination level L be shifted upward by referring to the magnitude of the actual vibration values.

The technology that affects variations in winding conditions is discussed below.

6A and 6B show the function that the abnormality determination levels L displayed for different winding conditions. 6A Fig. 12 is an image of the display of an abnormality determination level L for a first winding condition. 6B Fig. 12 is an image of the display of an abnormality determination level L for a second winding condition.

The control device 4th the automatic winding machine 100 includes a storage section 41 (please refer 2nd ). The storage section 41 is a storage medium that stores winding conditions therein, such as a thickness (number) of the yarn Y and a winding speed, etc. The storage section 41 stores an abnormality determination level therein L for each winding section. The control device 4th works as the display control section 4c to a controller exercise so that the abnormality determination level L is displayed according to the winding condition.

The display control section 4c thus exerts control such that the abnormality determination level L , which corresponds to the selected winding state, from the storage section 41 is read out and displayed. As a result, even if the winding conditions vary, a suitable abnormality determination level can be L can be set.

The technology that affects how the abnormality determination level L can be changed is explained below.

7A and 7B show if the abnormality determination level L for the first winding state is changed, such as the abnormality determination level L is changed for the second winding state. 7A shows how the abnormality determination level L is changed for the first winding state. 7B shows how the abnormality determination level L is automatically changed for the second winding state. The on the display section 5 however, the displayed graph only shows a change in the abnormality determination level L for the first winding state (the winding state of the current winding process) (see 7A) . Therefore 7B is a schematic diagram for explaining the above process.

The control device 4th the automatic winding machine 100 includes an arithmetic section 42 (please refer 2nd ). The arithmetic section 42 is an arithmetic processing device that executes the control programs. If the abnormality determination level L is changed for the first winding condition (see arrow M ), writes the control device 4th the information in the storage section 41 based on a calculation result by the arithmetic section 42 is obtained. That is, the control device 4th exerts control such that the abnormality determination level L for the second winding state is automatically changed based on an amount of change in the abnormality determination level L is made for the first winding state (see an arrow m). When instructed to change from the first winding state to the second winding state, the controller exercises 4th a controller to get out of the storage section 41 to read and the level of abnormality determination L for the second winding state. The abnormality determination level L for the second winding state, which from the storage section 41 is read out, the abnormality determination level L which was changed automatically.

The display control section 4c thus exerts control so that when the abnormality determination level L for the first winding state is changed, the abnormality determination level L for the second winding state that is in the storage section 41 is automatically changed based on an amount of change in the abnormality determination level L for the first winding condition. As a result, it can take time and labor to manually change the abnormality determination level L saved for every winding condition.

The arithmetic section 42 calculates a rate of change in the abnormality determination level L with its value before the change as a reference. “Rate of change” is a percentage amount of change from the abnormality determination level L , with its value before the change as a reference. The control device 4th changes the abnormality determination level L for the second winding state automatically, based on the calculated rate of change.

The display control section 4c thus exerts control such that when the abnormality determination level L for the first winding state is changed by a certain change rate, the abnormality determination level L for the second winding state, which was previously in the storage section 41 was stored by the same rate of change as that of the abnormality determination level L is automatically changed for the first winding state. For example, if the abnormality determination level L is increased by 5% for the first winding state, the abnormality determination level L also increased by 5% for the second winding state. Consequently, the abnormality determination level can L can be optimized for every winding condition.

The technology that makes the winding unit 1 detected with large vibrations with high accuracy is explained below.

8th shows graphs G (including the level of abnormality determination L ), one for a period of time until the yarn layer thickness of the package P reaches a predetermined value, and the other for the period thereafter.

The outer diameter of the package P takes with winding the yarn Y gradually or gradually. That is, the outer diameter of the package P gradually increases when winding the yarn Y around the spool of thread B2 (Package P ) progresses. During such a thickening of the package P , takes off due to the eccentricity of the thread spool B2 caused vibration to continue until the yarn layer thickness of the package P one predetermined value is reached, and the vibration continues to decrease thereafter. That is, by the eccentricity of the bobbin B2 The vibration caused continues to increase until the yarn layer thickness of the package P reaches a predetermined value. One of the reasons for this is that after the yarn layer thickness of the package P has reached the predetermined value, the vibrations are absorbed by the yarn layers. Another reason is that the speed of rotation of the package P with a thickening of the package P decreased. Consequently, it becomes necessary to estimate the magnitude of the vibrations while making a distinction between the period up to the yarn layer thickness of the package P reaches the predetermined value and the period thereafter. Therefore, the display control section practices 4c a control out to different graphs G (including the level of abnormality determination L ) display, one for the period up to the yarn layer thickness of the package P reached the predetermined value, and the other for the period thereafter.

The display control section 4c thus exerts control over different graphs G display one for the period up to the yarn layer thickness of the package P reached the predetermined value, and the other for the period thereafter. As a result, the winding unit with large vibrations can be recognized with high accuracy. Furthermore, in the present embodiment, two graph view frames 51 , each with a different graph G contains, displayed simultaneously on one screen. In an alternative embodiment, however, a single graph view frame can be used 51 displayed on a screen, and the graphs G can be displayed one at a time by selectively switching the ones in the graph view frame 51 displayed graphic. The term “the period after” does not have to be limited to one period, but can be a multitude of periods. The graph G , which represents "the period after", can indicate the average of chronologically changing vibration values.

9 shows a graph G (including the level of abnormality determination L ) for each direction of vibration detection.

Although it is also possible to estimate the vibration values in one direction (determining the presence / absence of abnormality) with respect to the eccentricity of the package B2 caused vibration, by using the vibration values in a plurality of directions, an estimation (determination of the presence / absence of abnormality) can be made with even higher accuracy. For example, vibrations in the two directions perpendicular to the direction of gravity are detected and the magnitude of the vibrations is comprehensively estimated (“assessed”). In this case, the display control section practices 4c a controller out to the graph G for the two directions.

The display control section 4c thus exerts control over the graphs G display for each vibration detection direction. Consequently, the winding unit 1 can be detected with great vibrations with even greater accuracy. Furthermore, in the present embodiment, two graph view frames 51 , each with a different graph G contains, displayed simultaneously on one screen. In an alternative embodiment, however, a single graph view frame can 51 displayed on a screen, and the graphs G can be displayed one at a time by selectively switching the ones in the graph view frame 51 displayed images. The vibration detection directions are not limited to those mentioned above. For example, vibrations can be detected in three directions, including the direction of gravity.

With the automatic winding machine 100 , update the unit control section 14 Bars the vibration detection values through the detection section 141 for a predetermined period immediately after the yarn cutter 123 was operated. Therefore, the vibration detection values are not sent to the controller in the period 4th transfer. As a result, the vibrations in the period are not in the graph G reflected.

The display control section 4c therefore does not exist in the graph G the vibration again caused by the operation of the thread cutter 123 is caused. Consequently, the winding unit 1 with the large vibrations can be recognized with even greater accuracy.

10th shows different graphs G , one for the period up to the yarn layer thickness of the package P reaches a predetermined value, and the other for the period thereafter, along with a graph G for each direction of vibration detection.

This type of display enables the winding unit 1 is recognized at a glance with great vibrations.

The possible patterns on the display section 5 displayed content is described next.

In the graph G , in the 3rd to 10th will be shown, the vibration value per package P shown. The one in the graph G The vibration value shown is not that of the package P , which is currently being formed, but from the last completely wound package P (That is, the vibration value at the time of forming the last package P ).

The display control section 4c thus exerts control over the graph G display that was obtained during the last package P is trained. Accordingly, it can be determined whether the vibration at the time of forming the last package P was great. In an alternative embodiment, the display control section can be caused 4c , instead of the graph G from just the last package P who have favourited Graphs G for several previous packages P indicates where they are differentiated by package or package by package. This enables a comparison of the vibration values of the previous several packages P . The display control section 4c thus exerts control over the graph G per package P display. As a result, those on the display section 5 displayed content can be simplified. If there is no vibration value data from the previous package P are available, for example in the case of formation of the very first package P , the graph G for the package P displayed which is currently being wound. As a result, the winding unit can be prevented 1 with no vibration value in the graph G is shown.

The automatic winding machine 100 according to an embodiment of the present invention is explained above. The object of the present invention is to provide a technology for easily recognizing the winding unit 1 with great vibrations among the large number of winding units arranged side by side 1 , and a technology associated with the above technology. It can also be said that the present invention is that of a display controller because its focus is on the controller 4th the automatic winding machine 100 lies. That is, it can also be said that the present invention is that of a display controller which generates signals to enable the above technical ideas to be realized. The automatic winding machine is also implemented 100 the above technical ideas by executing a control program by the control device 4th . Therefore, it can also be said that the present invention is that of a control program for executing a process to realize the above technical ideas.

Claims (20)

Textile machine, with: a plurality of winding units (1) arranged side by side, each winding unit comprising: a winding section (13) which winds a yarn (Y) to form a package (P), and a detection section (141) which detects vibrations during the formation of the package; a display section (5) which displays information about each of the winding units; and a display control section (4c) which controls contents displayed on the display section, the display control section exerting control to cause the display section to display a graph (G) in which a vibration value of each of the winding units is visually side by side and to also display in the graph an abnormality determination level (L) that serves as a reference for determining whether the vibration is large. Textile machine after Claim 1 further comprising a setting section (53) capable of setting the abnormality determination level, the display control section exercising control to cause the display section to display the abnormality determination level set by the setting section. Textile machine after Claim 2 wherein the display control section exerts control to cause the display section to shift an abnormality determination level following the operation of the setting section with the graph displayed on the display section. Textile machine according to one of the Claims 1 to 3rd , further comprising a storage section that stores therein the abnormality determination level for each wrapping condition, the display control section exercising control to cause the display section to read from the storage section and display the abnormality determination level according to a selected wrapping condition. Textile machine after Claim 4 wherein the display control section performs control such that when the abnormality determination level for a first winding state is changed, the abnormality determination level for a second winding state stored in the storage section is changed based on an amount of change in the abnormality determination level for the first winding state. Textile machine after Claim 5 , wherein the display control section exercises control, such that when the abnormality determination level for the first winding state is changed by a predetermined change rate, the abnormality determination level for the second winding state stored in the storage section is changed by the same change rate as that of the abnormality determination level for the first winding state. Textile machine according to one of the Claims 1 to 6 wherein the display control section exerts control to cause the display section to display different graphs for a period of time until a yarn layer thickness reaches a predetermined value and for a period thereafter. Textile machine according to one of the Claims 1 to 7 wherein the display control section exerts control to cause the display section to display the graph for each vibration detection direction. Textile machine according to one of the Claims 1 to 8th wherein the winding unit further comprises a yarn cutter (123) capable of cutting the yarn, and the display control section in the graph does not reflect vibrations caused by the operation of the yarn cutter. Textile machine according to one of the Claims 1 to 9 wherein the display control section exerts control to display the package-by-package graph. Textile machine after Claim 10 , the display control section exerting control to cause the display section to display the graph at the time of formation of the last package. Textile machine after Claim 10 or 11 wherein, when the first package is formed, the display control section exerts control to cause the display section to display the graph of the package being wound. Textile machine according to one of the Claims 1 to 12th wherein the sensing portion is attached to an electronic circuit board (142) housed in the winding unit. Textile machine according to one of the Claims 1 to 12th , the winding unit further comprising a cage which rotatably supports the package, and wherein the sensing portion is attached to the cage. Display control device of a textile machine, the textile machine showing: a plurality of winding units (1) arranged side by side, each winding unit having: a winding section (13) which winds a yarn (Y) to form a package (P), and a detection section (141) which detects vibrations during the formation of the package; and a display section (5) which displays information about each of the winding units; a display control section (4c) generating signals to cause the display section to display a graph (G) in which a vibration value of each of the winding units is visually arranged side by side, and also to generate an abnormality determination level (L ), which serves as a reference for determining whether the vibration is large. Display control device after Claim 15 further comprising a setting section (53) capable of setting the abnormality determination level, the display controller generating a signal to cause the display section to display the abnormality determination level set by the setting section. Display control device after Claim 16 wherein the display controller generates a signal to shift the abnormality determination level following the operation of the setting section, with the graph displayed on the display section. Control program for execution on a textile machine, the textile machine showing: a plurality of winding units (1) arranged side by side, each winding unit having: a winding section (13) which winds a yarn (Y) to form a package (P), and a detection section (141) which detects vibrations during the formation of the package; and a display section (5) which displays information about each of the winding units; the computer control program executing a process to cause the display section to display a graph (G) in which a vibration value of each of the winding units is visually arranged side by side, and also to display an abnormality determination level (L) in the graph , which serves as a reference for determining whether the vibration is large. Control program after Claim 18 wherein the textile machine further comprises an adjusting section (53) capable of adjusting the abnormality determination level, and the control program executes a process to cause that the display section displays the abnormality determination level set by the setting section. Control program after Claim 19 , wherein the control program executes a process to cause the display section to shift the abnormality determination level following the operation of the setting section, with the graph displayed on the display section.

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