JP5550822B2 - How to display the weft insertion status of the loom - Google Patents

Description

The present invention relates to a display method for facilitating the determination of the cause of a statistical value from an abnormality in a loom having a display device that graphically displays a statistical value related to a weft insertion status on a time axis.

Patent Document 1 discloses, as a “weaving machine weft insertion status display device”, that a statistical value related to the weft insertion situation is graphically displayed as a time series on the time axis. According to the technique of Patent Document 1, the change over time of the statistical value of the reaching angle of the weft yarn at the time of weft insertion can be visually recognized by a graphic display within a predetermined sampling period. It is possible to confirm whether or not an abnormality such as a variation occurs in the weft arrival angle. In addition to the above display, Patent Document 1 describes that the occurrence status of a weft insertion failure is displayed on the same time axis in order to identify the cause of the weft insertion abnormality. However, the technique disclosed in Patent Document 1 only displays whether or not a weft insertion defect has occurred in each sampling period and displays the type of the weft insertion defect. Absent.

By the way, when an abnormality is found in the statistical value of the weft arrival angle as a result of the graphic display, it is preferable to identify the cause early. For example, when the cause is a root cause such as a weft (yarn feeder) to be used or an abnormality in a weft insertion device, it is necessary to deal with it early so that the same situation is not repeated. Therefore, it is desirable that when the statistical value is abnormal as described above, the cause can be easily determined.

In addition, when the abnormality of the said statistical value has generate | occur | produced continuously from the certain time during weaving, it can discriminate | determine that the cause is based on the above root causes. However, when the above statistical value abnormality occurs temporarily instead of continuously, various causes are considered, and it is difficult to determine the cause. However, even if the occurrence of the statistical value abnormality is temporary, the cause may be a yarn feeder abnormality or a weft insertion device abnormality. Necessary.

However, since the display device according to the prior art of Patent Document 1 only displays whether or not a weft insertion failure has occurred, in the content display of that level, the cause of the abnormality appearing in the statistical value is determined. As a result, it takes time to determine the cause.
JP 2006-9233 A

Therefore, the problem of the present invention is that, in a display device having a display function for graphically displaying the magnitude of a statistical value related to the weft insertion status in a loom on the time axis, if the statistical value is abnormal, the cause It is to facilitate discrimination.

Under the above-mentioned problems, the present invention displays information related to the switching of the yarn feeder as a factor that fluctuates the weft travel on the same screen as the statistical value display screen related to the arrival time of the weft. ing. Specifically, the weft insertion status display method for a loom according to the present invention calculates a statistical value related to the arrival time for each predetermined sampling period based on the arrival time of the weft yarn detected for each weft insertion, and weaving A loom comprising a display device for storing the statistical values sequentially calculated with the passage of time in a time-series manner and graphically displaying the size of the stored statistical values over time on the time axis In the above, the loom is provided between a package sensor for detecting that the remaining yarn amount of the yarn supplying body has become a predetermined amount or less, or between two yarn supplying bodies in which the end and the start end of the weft yarn are tied together. comprising a pick tail sensor for detecting the switching of yarn supplier is information regarding the switching of the yarn supplier as factors varying the Hihashi weft detection signal of the package sensor or the pick tail sensor Information about the switching of the yarn supplier is detection information about the switched time of the weft package based on the on the display screen on the same screen of the statistics.

The above-mentioned “factors that vary the weft travel” can cause the weft travel (flying speed, state of flight, etc.) to fluctuate within the warp opening, in other words, This may cause fluctuation in the arrival time of the weft affected by flying. Then, information on the “factor that causes the weft yarn to fluctuate” is displayed on the same screen on the time axis together with a graphic display of a statistical value related to the arrival time of the weft yarn on the counter feed yarn side. Such information, for example, the above-mentioned (1) weft package changeover information about other (2) weft insertion conditions (in particular, the weft insertion start timing and the like) information on reset, and (3) above Information other than (1) and (2) above, and information regarding changes in weaving conditions (for example, weft insertion pattern, warp opening pattern, weft density, loom rotation speed, etc.) that may cause the weft flight to fluctuate In the present invention, among the information (1) to (3) above, at least (1) information relating to the switching of the yarn feeder is used as the information relating to the “factor causing fluctuation of the weft yarn” as the statistics. Display on the same screen as the value display screen.

(1) The information related to the switching of the yarn supplying body is detection information related to the switching time of the weft supplying body detected by the sensor. More specifically, in a weaving machine in which a sensor such as a package sensor or a pick tail sensor is attached to the yarn feeder, the remaining yarn amount of the yarn feeder becomes less than or equal to a preset predetermined amount during weaving. In other words, when it is time to replace the yarn feeder, this is detected by the sensor. The information related to the switching of the yarn supplying body as described above is information related to detection by the sensor that it is time to replace such a yarn supplying body.

In addition, the above “display on the same screen” means that the above weft is displayed on a graphic display of a statistical value related to the arrival angle of the weft to the counter-feeding side (hereinafter also referred to as “statistic value display”). When displaying the information related to factors that fluctuate flight (hereinafter also referred to as “variation factor information”), the display screen of the statistical value display and the variation factor information are displayed on the display device screen. Including the case where the display screen is displayed side by side. In addition, a display mode including a statistical value display and a display of variation factor information in one display is also included.

When the loom is a multi-color weft insert loom, the display of the statistical value on the display device is performed for each color of weft, and information regarding the switching of the yarn feeder is supplied to the sensor corresponding to the sensor that generates the detection signal. You may display only on the display screen of the above-mentioned statistics about the weft color of the thread.

In addition to (1) information related to the switching of the yarn feeder, (2) information related to the resetting of the weft insertion conditions and (3) changes in the weaving conditions At least one of the information may be displayed on the same screen as the statistical value display screen.

(2) Information related to resetting the weft insertion condition is a reset operation that returns the changed weft insertion condition to the initial value in a loom that executes weft insertion control that changes the weft insertion condition in accordance with the arrival angle of the weft. It is information about what has been broken.

That is, in the loom, automatic control for changing the weft insertion condition based on the detected actual weft arrival angle is widely adopted for the purpose of making the weft arrival angle constant. On the other hand, the arrival angle of the weft varies depending on the change (decrease) in the winding diameter of the yarn feeder as weaving proceeds. For this reason, when the weft insertion conditions are constant, the arrival angle changes sequentially with the progress of weaving even if there is no change in the weft insertion device or the like. Therefore, in the loom equipped with the automatic control described above, the weft insertion conditions are sequentially changed due to the decrease in the winding diameter of the yarn feeder as the weaving progresses. Then, when the yarn feeder is replaced with exhaustion of the yarn feeder, etc., a reset operation for returning the weft insertion condition changed according to the decrease in the winding diameter of the yarn feeder to the initial value as described above. Is done. The information related to the resetting of the weft insertion condition is information indicating that such a weft insertion automatic control reset operation has been performed.

Incidentally, as the above-mentioned weft insertion conditions, for example, the weft insertion start timing, that is, the injection start timing of the main nozzle for weft insertion (if the loom has an auxiliary main nozzle, the injection start timing of the auxiliary main nozzle is also And / or unwinding timing of the engagement pin in the length measuring storage device. In addition to this, the injection pressure and injection end timing of the main nozzle (auxiliary main nozzle), the injection pressure and injection start / end timing of the weft insertion sub-nozzles (sub-nozzles for each group) are also included. Furthermore, in the case of a loom equipped with a weft brake, the operation timing of the weft brake is also included in the weft insertion conditions.

Note that, as described above, the weft insertion condition resetting operation is performed as the yarn feeder is switched. Accordingly, it can be said that the information regarding the resetting of the weft insertion condition (2) belongs to the information regarding the switching of the yarn feeder (1).

(3) Information related to changes in weaving conditions is information other than the above (1) and (2), and indicates that the weaving conditions that may cause the change in the weft flight have changed. Say. Examples of such weaving conditions include those related to the weaving mode such as the weft density, the warp opening pattern, and the number of rotations of the loom. In addition, the weft insertion pattern may be changed during the weaving of the same fabric, and this weft insertion pattern is also included in the above weaving conditions.

Incidentally, regarding the change of the above-mentioned weft insertion pattern (weft insertion order), specifically, in the multi-color weft insertion loom, while weaving the same fabric, each weft and weft insertion system (main The relationship between the nozzle and the length measuring storage device is interchanged, and the weft insertion pattern is changed accordingly. For example, for C1 weft, no. 1 from the storage device No. 1 No. 1 was inserted by the main nozzle. 2 from the storage device No. 2 In some cases, the weft insertion pattern is set so as to be inserted by the two main nozzles. In this case, the weft insertion pattern set as the operation of the weft insertion system is also replaced. In this case, the main nozzle no. 1, no. 2 is different, and the weft flying position in the weft guide groove of the kite changes, so the replacement of the weft insertion pattern is also a factor that affects the weft flying.

Further, regarding the change of the weaving mode such as the warp opening pattern, the weft density, the number of rotations of the loom, basically, for example, when changing from a pile weaving to a ground weaving in a towel loom, a preset weaving is used. This is done automatically based on the pattern. However, although it is not actually performed, it may be changed by an operator during weaving, and information in that case is also included as information on the change of the weaving conditions.

According to the present invention, in addition to the statistical display of the weft arrival time on the time axis in a time-sequential graphic display, the yarn feeder as a factor that fluctuates the above-mentioned weft flight on the same screen . Information about switching is displayed. Therefore, when an abnormality in the statistical value is confirmed on the same display screen, it can be easily determined whether or not the cause is due to the above information to be displayed.

Specifically, when an abnormality appears in the statistical value related to the arrival time of the weft yarn at a certain point in time or continuously at that point, the cause is not limited to one, but various causes Can be considered. As described in the Background Art section, it is desirable to determine the cause early, but it takes time and effort to check every possible factor one by one.

In contrast, according to the present invention, at the time the abnormal statistics is confirmed, the abnormality near changes that affect the flight of the weft run in, in particular made off a drop-in replacement Riga yarn feeding member It can be easily confirmed on the screen of the display device. Accordingly, it can be determined whether or not the cause of the abnormality in the statistical value is due to the switching of the yarn feeder , and the cause can be easily determined in a shorter time.

In particular, weft flight tends to fluctuate when the yarn feeder is switched, but the cause of the fluctuation and the graphic display of the statistical value related to the arrival time can be compared in time series on the time axis. Since the relationship can be read visually, the causal relationship can be easily identified.

FIG. 1 shows a main part of an air jet loom as a fluid jet loom to which the present invention is applied. The illustrated air jet loom includes a two-color weft insertion device 1 as an example. In the weft insertion device 1 of FIG. 1, the wefts 4 of the collars C1 and C2 are pulled out from the yarn feeder 3 supported by the holder 2, and are, for example, inside the rotating yarn guide 6 of the drum-type length measuring storage device 5. It is guided and wound around the outer peripheral surface of the drum 7 by the rotational movement of the rotary yarn guide 6 while being locked by the locking pin 8 on the outer peripheral surface of the drum 7 in a stationary state. Accordingly, the weft 4 having a length necessary for one weft insertion is wound around the outer peripheral surface of the drum 7 and stored until the weft 4 is inserted.

The length measuring storage device 5 (rotational movement of the rotary yarn guide 6 and forward / backward movement of the locking pin 8) and the main nozzle 10 for weft insertion described later are connected to the weft 4 by the weft insertion control unit 31 inside the control device 20. Operates based on selection order. The package sensor 39 is installed near the yarn supplying body 3 and detects that the remaining yarn amount of the weft 4 in the corresponding yarn supplying body 3 is equal to or less than a predetermined amount. At that time, the detection signal S4 is output. Occur.

At the weft insertion start timing, the locking pin 8 corresponding to the weft thread 4 selected by the weft insertion control unit 31 is driven by the operating device 9 and retracted from the outer peripheral surface of the drum 7 so that it is wound around the outer periphery of the drum 7. The weft 4 having a length necessary for one weft insertion is in a state where it can be unwound on the drum 7. When the main nozzle 10 for weft insertion performs an injection operation, the weft yarn 4 passed through the main nozzle 10 is unwound from the drum 7 and inserted. In this example, the main nozzle 10 is configured as a duplex type in which the auxiliary main nozzle 10a and the main main nozzle 10b are arranged in series in the direction of the weft yarn 4.

The main nozzle 10 corresponding to the selected weft 4 starts the injection of the pressure air 12 toward the opening 14 of the warp 13 at the set weft insertion start timing, and continues the injection over the set injection period. Thus, the weft 4 having a predetermined length is inserted into the opening 14. By this weft insertion operation, the weft 4 travels along the weft travel path in the opening 14. The pressure air 12 is set to an appropriate pressure value for weft insertion from a pressure air source 26 by a common pressure regulating valve 27, and then passes through each electromagnetic on-off valve 28 and the auxiliary main nozzle 10a and the main nozzle 10 as the main nozzle 10. It is supplied to the main nozzle 10b. Each electromagnetic on-off valve 28 operates based on the weft selection order under the control of the weft insertion control unit 31.

As described above, the weft insertion device 1 of FIG. 1 is a two-color weft insertion, but in the case of a multi-color weft insertion of two or more colors, the yarn feeder 3, the length measuring storage device 5 and the main nozzle 10 are These are installed according to the number of multiple colors and are inserted according to the weft selection order. Of course, in the case of one color weft insertion, only one length measuring storage device 5 and main nozzle 10 are provided.

In the process in which the wefts 4 inserted in the weft travel along the travel path in the opening 14, the plurality of groups of sub-nozzles 11 simultaneously inject the pressurized air 15 toward the travel direction of the weft 4 along the weft travel path. Or, the pressurized air 15 is relay-injected in harmony with the traveling speed of the weft yarn 4, thereby energizing the weft yarn 4 traveling in the opening 14 in the weft insertion direction. The pressure air 15 is supplied from the pressure air source 26, set to an appropriate pressure value by the pressure adjustment valve 29, and then supplied to the sub nozzles 11 of each group through the electromagnetic on-off valves 30 for each group. The electromagnetic on-off valves 28 of each group are under the control of the weft insertion control unit 31 at the time of weft insertion, and perform simultaneous injection or relay injection to the sub nozzles 11 of a plurality of groups to weft the weft yarns 4 in flight. Energize in the direction.

When the weft 4 is inserted normally by the injection operation of the main nozzle 10 and the sub nozzles 11 of a plurality of groups, the weft 4 is beaten on the pre-weaving 18 of the woven fabric 17 by the beating motion of the reed 16 and the weaving 4 After being woven into the cloth 17, it is cut by the yarn feeding cutter 19 on the weft insertion side, and cut off from the weft 4 inside the main main nozzle 10b.

Whether or not the weft insertion is normally performed is detected by the first weft feeler 21 and its sensor 24, the second weft feeler 22 and its sensor 25. The sensor 24 of the first weft feeler 21 faces the weft runway in the vicinity of the woven end portion of the woven fabric 17 on the side opposite to the weft insertion side, and is provided at a position where the weft 4 that has been inserted normally can reach. Therefore, the front end of the weft 4 that is normally inserted is detected. This detection is performed by comparing the level of the detection signal generated in the sensor 24 with the reference signal level within the normal arrival time (set detection period) of the weft 4. Therefore, according to the sensor 24 of the first weft feeler 21, a weft insertion failure (show topic, ben topic, etc.) in which the tip of the weft 4 does not reach the position of the sensor 24 despite the weft insertion is detected. . The detection period is usually set on the rotation angle of the main shaft 33.

In the detection period, when the sensor 24 detects the arrival of the weft 4, it generates an output signal corresponding to the arrival. At that time, the first weft feeler 21 generates a yarn signal S1 corresponding to normal weft insertion based on the output signal from the sensor 24, and this yarn signal S1 is sent to the main control unit 36 inside the control device 20 and This is sent to the statistical value calculation means 40. The main control unit 36 continues the operation of the loom (weaving) on condition that the yarn signal S1 corresponding to normal weft insertion exists. The statistical value calculation means 40, together with the calculation means 54, constitutes a statistical value calculation section 38. In order to display the weft insertion status, as will be described in detail later, the statistical value calculation means 40 from the yarn signal S1 to the weft yarn for each predetermined sampling period. The statistical value about the arrival time (arrival angle) of 4 is calculated.

During the detection period, when the yarn signal S1 is not generated, that is, when the weft insertion failure occurs and the sensor 24 cannot detect the arrival of the weft 4, the first weft feeler 21 is When it is determined that the insertion is abnormal, a weft stop signal S2 is output, and this weft stop signal S2 is sent to the main control unit 36 and the calculation means 54.

Upon receiving the weft stop signal S2, the main control unit 36 immediately executes stop control to stop the loom at a predetermined angle. The stop of the loom at this time is a stop due to a weft insertion abnormality of the weft 4, and corresponds to a display “horizontal stop” in FIGS. 3 and 4 to be described later. Further, as will be described in detail later, the calculation means 54 displays the weaving machine 4 detected by the first weft feeler 21 in order to display the stoppage of the loom generated during a predetermined sampling period in a visible state. The number of stops due to a weft insertion error is integrated.

Further, the sensor 25 of the second weft feeler 22 has a position farther in the weft insertion direction than the sensor 24 on the weft end portion of the woven fabric 17 on the opposite weft insertion side, that is, the weft 4 that has been normally inserted. It faces the weft runway at a position where it does not reach and is provided to detect a weft insertion failure such as a blowout of the weft 4 or a long pick. This detection is performed by comparing the level of the detection signal generated in the sensor 25 with the reference signal level at the abnormal arrival time (arrival angle) of the weft 4 within the detection period. The detection period is usually set on the rotation angle of the main shaft 33. During this detection period, when the output signal from the sensor 25 is input, the second weft feeler 22 determines that the weft insertion is abnormal, generates a weft stop signal S3, and controls the weft stop signal S3. To the unit 36 and the computing means 54.

When receiving the weft stop signal S3, the main control unit 36 immediately stops the loom at a predetermined angle in the same manner as when receiving the weft stop signal S2. The loom stop at this time is also a stop due to an abnormality of the weft 4, and corresponds to a display “horizontal stop” in FIGS. 3 and 4 to be described later. Further, as will be described in detail later, the calculation means 54 displays the weaving machine 4 detected by the second weft feeler 22 in order to display the stoppage of the loom generated during a predetermined sampling period in a visible state. The number of stops due to a weft insertion error is integrated.

The calculation means 54 of the statistical value calculation unit 38 is based on the number of stops due to the weft insertion abnormality of the weft 4 detected by the first weft feeler 21 and the weft insertion abnormality of the weft 4 detected by the second weft feeler 22. In addition to accumulating the number of stops separately, the sum of both is accumulated as necessary.

On the other hand, the yarn breakage of the warp yarn 13 is detected by the dropper device 50, and the abnormality such as the yarn breakage of the leno tissue forming ear yarn 51 at the woven end is detected by the ear knitting device 52 at the both woven ends. . The dropper device 50 has droppers (not shown) corresponding to the number of warps 13, and each warp 13 is passed through a corresponding dropper so that the dropper is suspended and each dropper is held at a predetermined height. doing. Further, the ear braiding device 52 forms a leno structure for holding the ends of the weft yarns 4 by twisting the plurality of ear yarns 51 every weft insertion.

When yarn breakage occurs in any warp 13 during weaving, the dropper at the yarn breakage position falls, and an electrical closed circuit is formed between the dropped dropper and an electrode (not shown). The dropper drop is detected from the energized state of the closed circuit, a warp stop signal S10 is generated, and this is sent to the main controller 36 and the calculation means 54.

Further, when yarn breakage occurs in the ear thread 51 during weaving, an ear thread sensor (not shown) provided in the ear assembling device 52 detects the thread breakage of the ear thread 51 and generates a warp stop signal S11. This is sent to the main control unit 36 and the calculation means 54.

When receiving the warp stop signal S10 or the warp stop signal S11, the main control unit 36 immediately stops the loom at a predetermined angle in the same manner as when the weft 4 is abnormal. The stop of the loom at this time is a stop caused by an abnormality in the warp 13 or the ear yarn 51, and corresponds to a display “vertical stop” in FIGS. 3 and 4 to be described later. Further, as will be described in detail later, the calculation means 54 displays the stoppage number of the loom and the stoppage signal based on the stoppage signal S10 in order to display the stoppage state of the loom generated in a predetermined sampling period in a visible state. The number of stops based on S11 is integrated separately, and the sum of those stops is integrated.

The control device 20 controls the loom in a state synchronized with the rotation of the main shaft 33 of the loom, displays the weft insertion status, and performs other necessary controls in order to perform the weft insertion control unit 31 and the main control unit. 36, a statistical value calculation unit 38, a setting / display unit 41, and a weft selection signal generation unit 42. In order to detect the rotation angle of the main shaft 33, an encoder 34 is connected to the main shaft 33. During the weaving, the encoder 34 generates a signal of the rotation angle θ of the main shaft 33, and this signal is transmitted to the weft insertion controller 31 and the main shaft 33. This is sent to the control unit 36, the weft selection signal generation unit 42, the statistical value calculation means 40, and the like.

The main control unit 36 performs control of the main movement of the loom and control at the time of stopping based on the signal of the rotation angle θ of the main shaft 33. The weft selection signal generator 42 detects the amount of rotation of the main shaft 33 from the rotation angle θ, generates a weft selection signal S8 based on a preset weft selection order, and uses the weft selection signal S8 as a weft insertion control unit. 31, and is sent to the statistical value calculation means 40 and the calculation means 54. The weft insertion control unit 31 selects the weft 4 corresponding to the weft selection signal S8 in synchronization with the rotation of the main shaft 33, and the weft insertion device 1 in the weft insertion device 1 based on the rotation angle θ appropriate for the selected weft 4. The operations of the length measuring storage device 5, the main nozzle 10, and the sub nozzle 11 are controlled, and the weft insertion operation of the selected weft 4 is performed.

The statistical value calculating means 40 calculates a statistical value related to the arrival time of the weft 4 for each predetermined sampling period based on the arrival time of the weft 4 detected for each weft insertion. While passing the rotation angle (0 °), the number of picks (the number of weft insertions) is counted, and the yarn signal S1 is input on the rotation angle θ over a preset sampling period (the number of picks). The rotational angle θ at which the weft reaches from the time point, that is, the arrival angle of the weft 4, is detected, and a statistical value of the weft arrival time is calculated for each sampling period. The statistical value of the weft arrival time is calculated separately for each yarn type by the input of the weft selection signal S8.

The statistical values here are the minimum value (rotation angle θ when the weft 4 arrives) on the opposite weft insertion side (rotation angle θ when the weft 4 arrives), maximum value (when the latest weft arrival time) 1 or more of the standard deviation of the weft arrival time and the average value (rotation angle θ) of the weft arrival time. As described above, these values are calculated for each yarn type.

The difference between the two values of the maximum value and the minimum value indicates the range of variation in the weft arrival time, and each value indicates the actual value of the variation range in the sampling period. Since this is an actual value, it is useful for adjusting the loom as much as the range of variation can be seen compared to the standard deviation.

According to these maximum and minimum values, the fluctuation range thereof can be known, which is advantageous in that the pressure of the weft insertion nozzles (the main nozzle 10 and the sub nozzle 11) can be changed, for example, in adjusting the loom. The standard deviation displays the degree of variation numerically and corresponds to the degree of dispersion in the binomial distribution, the so-called peak height. On the other hand, the average value is literally the average value of the weft arrival angle at a predetermined number of picks in one sampling period, for example, 1000 picks, and from this, a rough variation in the weft arrival angle can be seen.

As will be described later with reference to FIG. 2, the setting / display unit 41 is a display device for displaying information relating to factors that cause fluctuations in statistical value display and weft flight, and for setting the number of samples in one sampling period. For example, has a touch panel type setting input means 37. In calculating the statistical value, the number of samples in one sampling period can be selected and set from a plurality of settings on the setting / display unit 41.

In the setting work before weaving starts, the operator selects and sets an appropriate number of sampling picks from the setting screen displayed by the setting / display unit 41. The number of samplings here is the number of measured values of the weft arrival timing that are used when calculating the statistical value of the weft arrival timing during one sampling period. As will be described later, when the number of sampling picks is set to 1000 picks, the statistical value calculation means 40 calculates the statistical values during one sampling period based on the measured values of the weft arrival timing for 1000 picks. Will do. In addition, the storage capacity of the statistical value is the number of sampling picks corresponding to at least one package yarn feeder 3.

The statistical value calculation means 40 receives the weft selection signal S8 from the weft selection signal generator 42 in order to calculate a statistical value based on the data sampled for each weft color, and receives the maximum weft arrival time for each weft color. The minimum value of the weft arrival time, one or more of the standard deviations of the weft arrival time, and the average value of the weft arrival time are calculated, and a display data signal S9 for displaying these statistical values is set / displayed 41 Output to.

In addition, the calculation means 54 inputs the weft selection signal S8 to calculate the number of stops for each weft color, and inputs the weft stop signals S2, S3 and the warp stop signals S10, S11 in each sampling period. The number of stops of the loom is integrated while identifying the cause of the stop, and a display data signal S12 is generated for each weft color based on the integration result. This display data signal S12 is output to the setting / display unit 41 in order to display the number of stops as a display of the occurrence status of the stop of the loom.

As described above, the setting / display unit 41 is provided for graphic display of statistical values related to weft insertion and information regarding factors that cause the flying of the weft 4 to fluctuate, that is, variation factor information. The statistical value calculation unit 38 (the statistical value calculation unit 40 and the calculation unit 54) receives a command necessary for graphic display from the setting / display unit 41 and outputs display data signals S9 and S12 to the setting / display unit 41. . The setting / display unit 41 exchanges the data for setting the condition for calculating the statistical value, the statistical value display and the variable factor information regarding the weft insertion, and the data for changing the setting of the other weaving conditions. In order to exchange graphic display data such as statistical values to the unit 36 and the weft selection signal generation unit 42, it is possible to communicate with the statistical value calculation means 40 and the calculation means 54 in a bidirectional manner. .

The setting / display unit 41 receives the display data signals S9 and S12 at the end of each sampling period, and is sequentially calculated by the statistical value calculation means 40 with the progress of weaving based on the data of the display data signal S9. A plurality of statistical values are stored in time series, and the size of the stored statistical values is graphically displayed over time on the time axis of the display screen, and the statistical value graphic is displayed based on the data of the display data signal S12. On the same time axis as the display time axis, the occurrence state of the loom stops occurring during each sampling period, that is, the number of stops is displayed in a visible state.

FIG. 2 shows an internal configuration example of the setting / display unit 41. In FIG. 2, the setting / display unit 41 includes a storage unit 46, a touch panel screen display 47, a port 48, and a processing unit 49. The port 48 receives a display data signal S9 for displaying a statistical value, a display data signal S12 for displaying the number of stops, and the like, an external statistical value calculating means 40 and a calculating means 54, an internal screen display 47, and a processing unit. Signals and data are exchanged with 49.

The storage unit 46 is rewritable, and stores a plurality of statistical value data of the display data signal S9 and data of the number of stops of the display data signal S12 in association with the sampling number. The storage unit 46 stores a program for controlling the touch panel screen display 47, a program for displaying a statistical value and the number of stops, and other necessary software.

The screen display 47 is a display device, and displays a plurality of statistical values over time on the time axis of the display screen based on the display data signal S9 and also displays the statistical values based on the display data signal S12. On the same time axis as the graphic display time axis, the number of loom stops occurring in each sampling period is displayed as a visible state. The screen display 47 also serves as a touch panel type setting input means 37 in a part of the display screen, and can input a display request, various commands, sample number data, etc. by a touch operation on the display screen. It is configured. Sample number data and the like are sent to the statistical value calculation means 40 and the calculation means 54 via the port 48.

The setting / display unit 41 has a first display function and a second display function as display functions. The first display function is a function for displaying statistical values relating to the arrival time of the weft 4 and information relating to factors that cause the flying of the weft 4 to fluctuate, that is, fluctuation factor information on the same screen. This variation factor information, which will be described in detail later with reference to FIGS. 3 and 4, is displayed in the “operation information” column. Further, as will be described later, the first display function also includes a function of displaying the stop state separately for a stop caused by an abnormality of the weft 4 and a stop caused by an abnormality of the warp 13.

In addition, the second display function is a function for displaying a part of a specified period on the time axis in an enlarged manner and displaying the occurrence status of the stop in the extension period for each stop cause. Further, at the time of this enlarged display, a function of displaying a list of information indicating setting changes of the weaving conditions made during the enlarged display period as an input history on the same screen is also included.

The processing unit 49 is constituted by a CPU, a so-called microprocessor, and controls input / output at the port 48 according to predetermined software stored in the storage unit 46, and controls the screen display 47, and sets / displays. In response to a screen display request from 41, a plurality of statistical values and the number of stops are read from the storage unit 46, and a graphic display corresponding to the size of the plurality of statistical values and the number of stops are displayed on the screen display 47. Let

As described above, the statistical value calculation unit 38 and the setting / display unit 41 calculate the statistical values, accumulate the number of stops, store these values, and display the size of the stored statistical values and the number of stops on the display screen. Although the graphic display is performed over time on the axis, this function can be realized by using the control computer of the main control unit 36 or a computer such as a dedicated microcomputer and by software processing thereof. .

In the configuration example shown in FIG. 1 and FIG. 2, the blocks are configured by function, but they can also be configured as one block by using a computer. The function of the control device 20 can be realized by a program using a computer. Therefore, the functional block portion of the control device 20 can be replaced by computer input / output means, storage means, calculation (control), and display means.

Next, FIGS. 3 and 4 show an example of a statistical value display screen 61 by the screen display 47. The display screen 61 in FIG. 3 shows a statistical value, the number of stops, and variation factor information for each sampling period of the weaving process on one screen. The time-dependent graphic display on the time axis (hereinafter also referred to as “statistic value display”) about the size of the statistical value of the arrival time (arrival timing) of the weft 4 is the horizontal axis (X axis) / vertical It is displayed as a graph of the axis (Y axis). One unit of the horizontal axis in the graph is one sample period. The scale on the horizontal axis is the number of picks, and the number of picks is proportional to the time elapsed during weaving. For this reason, the horizontal axis can be said to be a time axis.

The sampling number (the number of picks) in the sampling period can be selected and set by touching the selection buttons 43 of “32”, “100”, and “1000” in the display frame 57 as the setting input means 37. The portion of the selection button 43 “1000” is hatched, which indicates that the number of samplings in one sampling period is set to 1000 picks.

The display “−” (minus) on the horizontal axis in the illustrated graph indicates that the current time of “0” is past. Therefore, “−10” is 10 sampling periods before the current time of “0”, and indicates the weft insertion time before 10,000 picks by the calculation of 10 × 1000 (sampling number) = 10000. Thus, the graph represents the period of the weaving time of the past sampling number 100 from “0” to “−100” on the horizontal axis, and the total number of picks in this period is 100,000 picks. Become. Such a display period can be arbitrarily moved on the time axis as needed by a touch operation on the scroll button 44 with a triangular mark in the left-right direction.

In the graph of the display screen 61, of the left and right vertical axes (Y axis), the left vertical axis indicates the arrival time of the weft 4 by the angle (°) of the rotation angle θ, and the right vertical axis is the standard. The magnitude of the deviation is shown.

In the graph on the display screen 61, the broken line graph A shows the average value of the weft arrival time (weft arrival angle) during the 1000 picks with the angle (°) of the left vertical axis on the time axis as a reference scale. Is displayed graphically. In addition, the discontinuous bar-shaped graph B has a maximum value and a minimum value of the weft arrival time (weft arrival angle) during 1000 picks with the angle (°) on the left vertical axis on the time axis as a reference scale. Are graphically displayed as a state where the lines are connected by a line segment in the vertical axis direction. Furthermore, a broken line graph C shows the standard deviation of the weft arrival time (weft arrival angle) with the right vertical axis as a reference scale on the time axis.

The yarn feeder mark 45 at the top of the display screen 61 indicates the thread type of the weft 4 being displayed together with the thread type of the weft 4, that is, the colors C1 and C2. The yarn feeder mark 45 of “1” is hatched, which indicates that the screen is displayed for the color C1. In the case of a multi-color weft insertion loom, the thread type (color) of the weft 4 can be selected by touching the yarn feeder mark 45 on the display screen 61, and the display is switched to a graph display of the weft arrival time of the selected thread type. You can also. By the way, the screen display 47 is multi-colored (color) display, the display colors of each graph (A, B, C), horizontal axis, left and right vertical axes, etc. are different, and the display color is different for each thread type. If it is configured to display differently at the same time, the visibility is further improved.

Further, in the illustrated example, in the display screen 61, the setting / display unit 41 displays stop information as the occurrence state of the loom stop above the graph display regarding the statistical value in the screen based on the first display function. Is divided into a “horizontal stop” due to an abnormality of the weft 4 and a “vertical stop” due to an abnormality of the warp 13 or the ear thread 51, and these are graphically displayed on the horizontal axis. Fluctuation factor information, which is information relating to factors that fluctuate the weft flight, is displayed in the “driving information” column.

Regarding the display of the stop information, in the example shown in the figure, the display mode is such that the number of stops can be easily visually determined from the display form, that is, the number of stops can be visually recognized. Is displayed. In this display example, the sum (the total number of stops) of “horizontal stop” and “vertical stop” is not displayed, but can be displayed in an appropriate display mode as necessary. Moreover, it is also possible to display only the sum of both without being divided into “horizontal stop” and “vertical stop”.

For “horizontal stop”, the number of stops due to a weft insertion failure that occurs when the selected color is inserted is displayed for each weft color (thread type). For this reason, the number of stops can be recognized for each thread type.

Further, the display mode of the stop information will be described in detail. On the display screen 61, “horizontal stop” and “vertical stop” are displayed on the time axis (X axis) for displaying the magnitude of the statistical value in a graphic form. The number of stops occurring during the sampling period (1000 picks) is displayed for each sampling period on the auxiliary axis corresponding to the scale of the time axis. The time scale (pick) of the auxiliary axis here is a scale of the same interval as the time scale (pick) “−10”, “−20”, “−30”. The number of cars ("horizontal stop" and "vertical stop") is considered to be displayed on the same time axis as the time axis for displaying the statistical values. However, if a margin for displaying a stop can be secured on the time axis (X axis) for graphic display, an auxiliary axis parallel to the time axis (X axis) should be used for the number of stops. Alternatively, it can be displayed directly in the margin on the time axis.

Incidentally, “horizontal stop” is the sum (total) of the weft stop signal S2 from the first weft feeler 21 and the weft stop signal S3 from the second weft feeler 22. As described above, the content of the “horizontal stop” is due to a poor weft insertion, but may include a stop due to a yarn breakage. In the case of including a stop due to a yarn breakage, although not shown, a yarn breakage sensor is installed on the path of the weft 4 between the yarn feeder 3 and the length measuring storage device 5 and the supply of these sensors is not shown. The signal of the thread break sensor is integrated in the same manner as the signals of the first weft feeler 21 and the second weft feeler 22.

The “vertical stop” is the sum (total) of the stop signal S <b> 10 from the dropper device 50 and the stop signal S <b> 11 from the ear assembly device 52. A stop by cutting the warp (ground warp) 13 is also called a dropper stop, and a stop by cutting the ear thread (Leno yarn) 51 is also called a Leno cut stop. On looms with catch cords, catch cord breaks are also included in the “Vertical Stop”.

As described above, the setting / display unit 41 displays the stop occurrence state in a state in which the number of stop occurrences is visible by the first display function. By this display, it is possible to easily determine whether or not the cause of the abnormality in the statistical value is due to the stop. In addition, since the occurrence state of the stop (the number of stops) is displayed separately for the stop caused by the abnormality of the weft 4 and the stop caused by the abnormality of the warp 13, the influence of the cause of the stop on the statistical value is exerted. By considering the difference, the operator can more accurately determine whether the cause of the abnormality in the statistical value is due to the stoppage.

In addition, according to the display mode of the stop information shown in FIGS. 3 and 4, the number of stops for each sampling period is graphically displayed in a bar line shape, and the number of stops is shown in the circle auxiliary illustrated in FIG. As can be seen in the enlarged explanatory diagram of the part, it can be visually judged by the number (thickness) of the bar lines. Specifically, in the illustrated bar-line graphic image, when the number of stops is two or more, one bar is arranged in the horizontal axis direction (X-axis direction) as many times as it is without a gap. Therefore, it is visually recognized as a form in which the thickness of the bar line is increased visually when the number of stops is one time and when it is two times or more. However, when the number of stops is two or more, bar-like displays corresponding to one stop may be arranged at intervals, and in that case, the number of stops may be Will be confirmed as a number.

In the example shown in the figure, the range that can be displayed within each sample period on the display screen 61 is limited, and a maximum of 3 divisions (3 dots) in the time axis direction, that is, up to 3 times of display is possible. It has become. For this reason, even if the number of stops is 4 times or more, the display remains the same as 3 times. Specifically, the display range corresponding to each sampling period (1000 picks) is 3 dots (dots) in the X-axis direction (time passage direction), and the display corresponding to one stop (bar line) ) Is a graphic image of 1 dot in the horizontal axis (X-axis) direction and 17 dots in the height (Y-axis) direction. Therefore, in the display examples of FIGS. 3 and 4, the display range can display up to three times as the maximum number of stops.

As such, in the illustrated example, the maximum number of stops can be displayed only up to three times. However, in actual weaving, in one sampling period of 1000 picks at the maximum, a stop that exceeds 3 times due to the same stop (horizontal stop or vertical stop) is abnormal in the first place and is almost always generated. There is no problem in practical use.

Regarding the display of the number of stops, block-shaped graphic images having the same width as the display range corresponding to the sampling period are stacked in the Y-axis direction according to the number of stops and displayed as a bar graph according to the change in height. The number of stops may be displayed as a number. In this way, it is possible to display a large number of stops without narrowing the displayed time axis range.

Accordingly, regarding the display of the number of stops, it is possible to display a large number of stops without setting the maximum number of stops as described above, and display the actual number of stops as it is. Thus, the display in the state where the number of stops described above is visible includes both cases where the number of stops that can be displayed is limited and when the number of stops that can be displayed is not limited.

Next, regarding the display of the variation factor information on the display screen 61 shown in the figure, in the example shown in the figure, the display indicating “driving information” between the display column of the statistical value graph and the display column of “vertical stop”. A column is provided, and the above-described variation factor information, which is information relating to factors that vary the flying of the weft yarn 4, is displayed in this display column. The display column labeled “operation information” is provided on an auxiliary time axis parallel to the time axis (horizontal axis), and there are symbols “P”, “R”, “W” is displayed. The meaning of these symbols can be understood by touching the legend button 32 in FIG. 3 to open a small window as shown in FIG.

In the notation of the operation information explanation screen 35, “P” (package sensor) is information relating to the switching of the yarn feeder 3, and the time point when the yarn feeder 3 is replaced based on the detection signal S 4 from the package sensor 39. Represent. “R” (horizontal control reset) changes the weft insertion condition (for example, weft insertion start timing) according to the arrival angle of the weft 4 by executing the weft insertion control, and then sets the changed weft insertion condition to the initial value. This is information related to performing a reset operation for returning to, and represents a point in time when the weft insertion condition is returned to the initial value. Furthermore, “W” (pattern change) represents a point in time when the opening pattern of the warp 13 is changed as an example of information related to the change of the weaving conditions.

The weft insertion control will be described in detail. Depending on the loom, the weft insertion start timing (timing pin 8 release timing and / or main nozzle 10 injection start timing) or the like is determined based on the detected arrival angle of the weft yarn 4. Some have a function of automatic control that controls the weft insertion conditions and makes the arrival timing of the weft 4 almost constant. Further, as described above, since the arrival timing of the weft 4 tends to change according to the decrease in the winding diameter of the yarn feeder 3 as the weaving progresses, in the loom having the automatic control function as described above, The weft insertion conditions are controlled according to the decrease in the winding diameter of the thread body 3.

In the weft insertion control reset operation (reset of the weft control), as the weaving progresses, the remaining yarn amount of the yarn feeder 3 becomes a predetermined amount or less, or the weft yarn 4 of the yarn feeder 3 is exhausted. Thus, it refers to an operation of returning the weft insertion condition changed by the automatic control to the initial value when the yarn feeder 3 is switched to another new yarn feeder 3.

The detection signal S4 from the package sensor 39 is an input to the main control unit 36, and the main control unit 36 executes stop control of the loom with the input of the detection signal S4. Then, the yarn feeder 3 is replaced by an operator or automatically, and then the main control unit 36 restarts the loom to resume weaving. At this time, the reset operation for returning the weft insertion start timing changed by the automatic control to the initial value is performed by operating the reset button by the operator in the loom in which the yarn feeder 3 is replaced by the operator. Is called.

Further, in a loom having a function of automatically replacing the yarn feeder 3, the reset operation is performed by internal processing of the weft insertion controller 31 by inputting the detection signal S4 to the weft insertion controller 31. Here, since the reset operation of the weft insertion start timing is performed in accordance with the generation of the detection signal S4 from the package sensor 39, the detection signal S4 is information relating to factors that cause the flying of the weft 4 to vary, that is, variation factor information. Can be considered. The detection signal S4 as the variation factor information is also input to the setting / display unit 41 in addition to the main control unit 36 and the weft insertion control unit 31.

In addition, as shown by an imaginary line in FIG. 1, a feed that enables continuous weft insertion as a so-called pick tail state in which the end and the start of the weft 4 of two or more yarn feeders 3 that are used in sequence are tied together. When the yarn body 3 is used, a pick tail sensor (seam sensor) 39a provided between the two yarn feeding bodies 3 in the pick tail state is used instead of the package sensor 39 described above. The detection signal of the pick tail sensor 39a is a signal indicating the switching of the yarn feeder 3, instead of the detection signal S4 from the package sensor 39, and is input to the main controller 36 and the like as variation factor information.

The above-described variation factor information is not limited to that shown in the figure, and other weaving conditions such as weft insertion pattern, weft density, and information regarding changes in the number of rotations of the loom may be symbolized and displayed. Further, the symbols displayed as the variation factor information are not limited to those using one alphabetic character as illustrated, but may be other identifiable symbols or character strings. Further, the symbol of the variation factor information may be displayed on an enlarged display screen 62 in FIGS. 5 and 6 to be described later. As shown in the display screen 61 of FIGS. 3 and 4, when the statistical value display and the display of the variation factor information are displayed on the single display screen 61, the statistical value is displayed on the display screen 61. Even when the variation factor information is displayed on the operation information explanation screen 35 of another window opened in the display screen 61, the statistical value display and the variation factor information are displayed on the same screen.

Next, FIG. 5 to FIG. 7 show examples of the enlarged display screen 62 in a specific range of the display screen 61 by the second display function of the setting / display unit 41. When the operator specifies a period on the time axis on the display screen 61 of FIG. 3 or FIG. 4, the setting / display unit 41 displays the arrival timing statistics and the number of stops in the period set by the designation. 5 to 7 as shown in FIG. 5 to FIG. 7, it has a function (second display function) for displaying it on another enlarged display screen 62. In the example shown in the figure, information about the factors that cause the flying of the weft 4 to fluctuate (variation factor information) is not described on the enlarged display screen 62, but the display is also displayed on the enlarged display screen 62. Also good.

In the example of FIGS. 5 to 7, the display screen 61 before the enlarged display is replaced with another enlarged display screen 62 and displayed. However, the enlarged display screen 62 may be displayed in a state of being shifted on the screen while leaving the display screen 61 before the enlargement, or as a two-divided screen side by side with the display screen 61 before the enlarged display. It may be displayed. Further, in the enlarged display shown in the figure, the number of stops indicating the occurrence state of the stop is displayed for each stop cause, that is, for each type of detector (sensor) that detected the stop cause. However, the illustrated display period is merely an example, and if the display period on the time axis is narrowed and the scale interval in the X-axis direction is increased, more detailed display can be performed. Note that the enlarged display screen 62 in FIG. 5 returns to the display screen 61 in FIG. 3 by touching the close button 55 in the lower right.

As described above, the screen display 47 is a touch panel type and also serves as the setting input means 37. For this reason, the operator touches a specific position on the display screen 61 to set a range to be enlarged on the time axis. At this time, the touch portion of the display screen 61 functions as the setting input unit 37. Specifically, on the time axis, when the operator touches the screen near the middle part of the portion to be enlarged, one corresponding time point is designated, and the designated time point is used as a reference. An enlargement period consisting of a preset period before and after is set.

However, the setting of this period is not limited to specifying the midpoint of the period to be enlarged as the reference time point, but the beginning or end of the period is specified as the reference time point and the user wants to enlarge the display based on it. A period may be set. In addition, instead of setting a period to be enlarged based on one designated time point and a preset period, the period is set by designating two time points, the beginning and end of the period. Also good. Furthermore, the specification of the time point (intermediate point, start point, end point) that is the basis for setting the period is not limited to touching the display screen with a touch panel type, and is specified (set) by inputting a numerical value such as a pick number. It may be a thing.

Here, the designation operation (period setting operation) for setting a period also serves as an enlargement display operation at the same time. In other words, enlarged display is automatically performed simply by performing a period setting operation. However, the period setting operation and the enlargement display operation can be performed as separate operations, and further, the enlargement ratio setting can be arbitrarily changed during the enlargement display operation.

Further, the period for the enlarged display is set based on the time point arbitrarily designated by the operator as described above. In other words, the period to be enlarged is not limited to be arbitrarily settable, but a predetermined period, for example, a predetermined period before the current time as a starting point is set in the setting / display unit 41 (a past time value). (Alternatively, the number of picks in the past) may be set in advance, and the display in the set predetermined period may be enlarged and displayed by performing the enlarged display operation without performing the period setting operation. Is possible. In this case, the enlarged display operation simultaneously serves as the period setting operation.

Further, in FIG. 5, when the operator touches the legend button 53 labeled “legend” at the upper right of the enlarged display screen 62, a small window for explanation is displayed on the same screen as shown in FIG. An explanation screen 58 appears in the window, and necessary items are displayed there. Specifically, in the display frame 59 of the number of stops in the explanation screen 58, the correspondence between each display symbol indicating the number of stops displayed in different display modes and each stop cause is displayed. The

In the illustrated example, each stop cause is displayed by the name (H1 feeler, H2 feeler, dropper and Reno) of the detector (sensor) for detecting each stop cause. Incidentally, the H1 feeler described above corresponds to the first weft feeler 21 and the sensor 24, and the loom stop based on the detection result of the H1 feeler is also called H1 stop. The H2 feeler corresponds to the second weft feeler 22 and the sensor 25, and the loom stop based on the detection result of the H2 feeler is also called H2 stop.

Further, in the reaching angle display frame 60 of the explanation screen 58, a statistical value, that is, a correspondence relationship between each line type for graph display and the maximum value / minimum value, average, and standard deviation is described. In FIG. 6, the explanation screen 58 is closed by touching a close button 56 at the lower right.

In this way, the range specified on the time axis is enlarged and displayed, and the occurrence status of the stop is displayed for each stop cause, so that the operator can easily visually check for abnormal statistical values. Therefore, the cause can be determined more accurately because the specific cause of the stoppage can be taken into consideration.

As a result of checking the display contents, if the operator can easily determine that the cause of the statistical value abnormality is due to the stoppage of the loom, it can be determined that it will not have much impact on the future weaving and can be overlooked. is there. On the other hand, if there is no stop for the number of times that affects the statistical value during the sampling period even though there is an abnormality in the statistical value, it can be determined that the cause is not a stop, and the weft is 4 or an abnormality of the apparatus can be inferred. According to such a display, it is possible to easily determine whether or not the cause that appears as an abnormality in the statistical value is a stop, and based on this, the cause can be identified in a shorter time.

Next, FIG. 7 is an example in which information related to a change in the setting value of the weaving conditions (particularly, weft insertion conditions) is displayed as “input history”. When the operator touches the input history button 63 on the upper right of the enlarged display screen 62 on the enlarged display screen 62 of FIG. 5, a small input history display window is displayed on the same screen as shown in FIG. In the input history display screen 64 in the window, “input history” relating to a change in the setting value of the weaving conditions (in the example shown, weft insertion conditions as an example) is displayed. In the display screen 64, the history indicating that the information indicating the change in the setting value of the weft insertion condition made by the operator input during the enlarged display period is located at the bottom of the screen as it is older in time. Is displayed. However, as will be described later, regarding the display of information indicating the change of the setting value of the weft insertion condition (hereinafter also referred to as “setting change information”), “enlarged display” and “period specification” are not essential, It is done as needed.

In FIG. 5, if one sampling period is set to 1000 picks as shown at the bottom of the screen, the weft insertion of the weft 4 of the color C1 is performed during the enlarged display period in FIG. Is a period from the present to 11 sampling periods before, in other words, a period during which 11,000 picks of the weft 4 of the color C1 are inserted. In terms of the weaving period of the loom, for example, if wefts 4 of four colors are selected evenly, the period is a period in which weft insertion of 44000 picks is performed in the loom. The weft insertion condition setting change information included in the displayed input history includes the weft insertion condition set during the weaving period of the loom according to the period during which the weft insertion of 11000 picks by the weft 4 of the color C1 is performed. This is information indicating a change in the setting value.

In the example of FIG. 7, the input history display screen 64 is displayed on a separate window from the statistical value display screen 62 in a state of being superimposed on the display screen 62. As described above, in the example of FIG. 7, another window is opened on the enlarged display screen 62 of FIG. 5, and the input history is displayed on the display screen 64 of the window as setting change information of the weft insertion condition. It can be said that the display mode displays the statistical value display and the input history on the same screen. Note that the display screen 64 for displaying the input history can be displayed on the same screen side by side with the enlarged display screen, instead of being displayed on the enlarged display screen 62 as described above. Furthermore, it is possible to specify a period on the display screen 61 of FIG. 3 or FIG. 4 and display the input history during the specified period on the same screen as the display screen 61.

Incidentally, on the input history display screen 64, the button 23 is a button for scrolling the screen being displayed, and is used to move the screen downward. The close button 65 is used to close the window of the input history display screen 64 and return only to the previous display screen 62.

About the display example regarding the illustrated input history, the contents of each display are as follows. “Sub 1”, “auxiliary main”, “main”, and “locking pin” in the display screen 64 represent target devices whose settings have been changed, and represent the first group of sub nozzles 11, auxiliary main nozzles 10a, main mains. The nozzle 10b and the locking pin 8 are shown respectively. The sub nozzles 11 in each group are first, second,... From the group close to the main nozzle 10.

“C 1” and “C 2” correspond to color 1 and color 2, respectively, and indicate the set value for which weft among a plurality of wefts 4 to be inserted by the multi-color weft inserting device 1. . When weft insertion is performed using three or more main nozzles 10 (including the case where the same weft 4 is inserted from two or more main nozzles 10), “C3”, “C4”,.

“ON” and “OFF” represent the injection start timing and the injection end timing, respectively, in the case of a weft insertion nozzle (main nozzle 10 and sub nozzle 11). In the case of the locking pin 8, “ON” is a timing at which the weft 4 can be unwound by moving backward, and “OFF” is a timing at which the weft 4 is advanced to the drum 7 and can be locked. Represent.

Further, in the notations such as “65 → 70”, “185 → 190”, etc., each number represents the rotation angle θ (crank angle) of the main shaft 33 of the loom, and the set value is changed from the crank angle 65 ° to 70 °. This indicates that the angle has been changed from 185 ° to 190 °.

[-2], [-6], etc. on the rightmost side indicate the time when the setting is changed, and [-2] indicates that the setting is changed in the sampling period two times before the present time. . That is, when displaying a plurality of change information in a historical manner, it is necessary to be able to grasp at which point the setting change was made. It includes not only the device and its set value, but also information (time information) about the time (time) when the change was made.

From the above definition, for example, “Sub 1 C1 ON 65 → 70 [−2]” indicates that when weft 4 of color 1 is wefted before 2 sampling periods of statistical values related to color 1, This represents that the injection start timing of the sub-nozzle 11 group is changed from the crank angle 65 ° to 70 °.

By the way, in the illustrated input history display, the setting change information of the weft insertion conditions for different wefts 4 is mixed, not for each color of the wefts 4, and the setting values of the weft insertion conditions set during the above-described period are mixed. All of the information representing the change is displayed as a history. As described above, the displayed input history is not limited to the display of only the change information of the setting value of the weft insertion condition for the weft insertion of the weft 4 corresponding to the displayed statistical value display. It may include change information of weft insertion conditions for weft insertion. Further, as will be described later, setting change information of weaving conditions other than those relating to weft insertion (weft insertion conditions) may be included in the input history and displayed.

However, as described above, in the input history display screen 64, when the change information of the setting value of the weaving condition that is not related to the displayed statistical value display is also displayed, the operator has mistakenly displayed the display item. It may be possible to make a judgment. For example, when an input history is displayed because an abnormality is found in the statistical value display on the weft 4 of the color C1, we want to check only the change information of the weft insertion condition for the weft insertion of the weft 4 of the color C1. Nevertheless, if a lot of other change information is displayed on the same display screen, it may take time to confirm the change information. Further, if the weft insertion condition for the weft insertion of another weft 4 has been changed during the same sampling period in which the statistical value is abnormal, the change information is mistaken as being related to the weft 4 of color C1. There is also a fear. Therefore, in order to prevent misperception, the setting change information of the weaving condition displayed as the input history is only information corresponding to the weft insertion of the weft 4 corresponding to the displayed statistical value display, or other information The change information of the setting value of the weaving condition for the weft insertion of the weft 4 may not be displayed. In addition, specific weaving conditions (for example, injection timings of the main nozzle 10 and the sub nozzle 11) can be specified to reduce the number of displays, and only the input history related to the change information of the set values of the specified weaving conditions is displayed. It may be.

According to the above specific example, during weaving operation, an abnormality appears in the statistical values (average value, maximum value / minimum value, standard deviation) regarding the arrival time (arrival angle) of the weft 4 on the display screen 61 in FIG. The operator displays abnormal graph characteristics on the time axis of the display screen 61 (average line graph A, bar graph B connecting the maximum and minimum values, standard deviation line graph C). From the operation information column on the same screen, information on factors that cause the weft 4 to fluctuate (variation factor information), that is, “P” (package sensor), “R” (Horizontal control reset), “W” (pattern change) is checked for presence / absence, and these are compared on the time axis.

Whether the cause of the statistical value abnormality is due to the displayed information of “P” (package sensor), “R” (horizontal control reset) or “W” (pattern change) Whether or not can be easily identified. In this way, in addition to the statistical value related to the arrival time (arrival angle) of the weft 4, the variation factor information can be directly compared on the time axis of the same display screen 61, so that there are various ways of specifying the causal relationship of the statistical value abnormality Even if the cause of the above is not assumed, a lot of labor is not required, and the display screen 61 can be visually confirmed reliably.

In particular, when the yarn feeder 3 is switched or when the weft insertion condition (weft insertion start timing) is reset, the flying of the weft 4 tends to fluctuate. Since the graphic display of values can be compared in time series on the time axis, and the correspondence between the two can be read visually, the causal relationship can be easily identified in a short time.

In this comparison, when the correspondence on the time axis is not sufficiently specified, the operator designates the period on the display screen 61 and displays the enlarged screen display 62 of the sampling period as shown in FIG. Can be checked, and if necessary, the legend button 53 and the input history button 63 are touched to display the explanation screen 58 and the input history display screen 64, and stop from those screens. Check information (horizontal and vertical stops) and input history (change of weft insertion conditions) information.

From these pieces of information, the operator changed the set value of the weft insertion condition of the weft 4 in accordance with the abnormal statistical value during the sampling period when the statistical value related to the arrival angle of the weft 4 appeared. In this case, it can be inferred that there was a problem in changing the set value (set value after change). In particular, during the sampling period, the loom stop that can be confirmed from the display about the stop state described above, information on the switching of the weft 4 (yarn feeder 3), and the weft insertion conditions (such as the weft insertion start timing) are reset. If there is no cause that may cause a problem in the variable factor information such as information about the cause, the cause is a change in the setting value of the weaving condition (weft insertion condition) performed by the operator from the input history information as a cause other than the above variable factor information The input history display screen 64 is referred to as necessary to find the cause of the abnormality.

In this way, according to the illustrated example, in addition to the statistical value regarding the arrival time (arrival angle) of the weft 4 and the variation factor information, stop information (horizontal stop / vertical stop) is displayed at the same time. Further, if necessary, the input history (weft insertion condition) can be visually confirmed. Therefore, the cause of the statistical value abnormality can be comprehensively identified on the time series from the viewpoint of the fluctuation factor information, the stop information, and the input history.

It should be noted that the display mode such as the input history shown in the above specific example can be modified as follows.

In the above specific example, a period is set for enlarged display, and the input history within the set period is displayed. Instead, any time point can be specified on the time axis, and the specification is made. The information regarding the set number of setting changes may be displayed as the input history in order from the setting change made at the time closest to the time set by. In this case, only the setting change made before the designated time point may be displayed, or the number of settings related to the setting change made before and after that may be displayed as the input history.

In addition, regarding the designation of the period, in the illustrated example, the period is designated starting from the present, but an arbitrary past period may be designated, and the input history during that period may be displayed. Also, omitting the designation of a period or a specific time point, for example, by operating the history display button, a specific period before the current time or a specific number of change information is displayed as an input history You can also

In addition, regarding the display of the input history, in the example shown in the figure, only the information related to the change in the setting value of the weaving condition relating to weft insertion is displayed as the input history. Information related to setting changes such as the pattern, the weft density, and the loom speed may be included in the display items of the input history display screen 64. That is, the information included in the information related to the change of the weaving condition among the information related to the factor that fluctuates the flying of the weft yarn in the present invention and the information whose setting is changed by the operator is included in the input history and displayed. You may make it do.

In addition, regarding the display of the input history, in the above-described specific example, each setting change information displayed as the input history in the specified range is information (time information) indicating when the setting change was performed (sampling period). ) Is included. However, this time information can be omitted if the designated period is a narrow range, for example, a specific one sampling period. Moreover, the information regarding the changed setting value may be omitted, and only the weaving conditions may be displayed as information. In this case, detailed information (setting value, detailed time, changed worker, etc.) may be displayed on another display screen.

The present invention is applicable not only to an air jet loom but also to a water jet loom. Further, the present invention can be applied not only to the fluid jet loom but also to other plain looms such as a rapier loom.

It is explanatory drawing of the principal part of the weft insertion apparatus 1 of an air injection type loom. 3 is a block diagram of a configuration example of a setting / display unit 41. FIG. It is explanatory drawing of the example of a display of the statistical value by the setting and display part 41 display screen, the number of stops, and driving | operation information. It is explanatory drawing of the state which opened the window of the driving information on the display screen of FIG. It is explanatory drawing of the display screen of the state which expanded the specific period on the display screen of FIG. It is explanatory drawing of the state which opened the window of the legend on the display screen of FIG. It is explanatory drawing of the state which opened the window of the input history on the display screen of FIG.

DESCRIPTION OF SYMBOLS 1 Weft insertion apparatus 2 Holder 3 Feed body 4 Weft 5 Length measuring storage apparatus 6 Rotating thread guide 7 Drum 8 Locking pin 9 Operator 10 Main nozzle 10a Auxiliary main nozzle 10b Main main nozzle 11 Sub nozzle 12 Pressure air 13 Warp 14 Open DESCRIPTION OF SYMBOLS 15 Pressure air 16 筬 17 Woven cloth 18 Pre-weaving 19 Yarn feeding cutter 20 Control device 21 First weft feeler 22 Second weft feeler 23 Scroll button 24 Sensor 25 Sensor 26 Pressure air source 27 Pressure adjustment valve 28 Electromagnetic on-off valve 29 Pressure adjusting valve 30 Electromagnetic on-off valve 31 Weft insertion control unit 32 Legend button 33 Spindle 34 Encoder 35 Operating information explanation screen 36 Main control unit 37 Setting input means 38 Statistical value calculation unit 39 Package sensor 40 Statistical value calculation unit 39a Pick tail sensor 41 Setting / display section 42 Weft selection signal generator 4 Selection button 44 Scroll button 45 Feeder mark 46 Storage unit 47 Screen display 48 Port 49 Processing unit 50 Dropper device 51 Ear thread 52 Ear assembly device 53 Legend button 54 Calculation means 55 Close button 56 Close button 57 Display frame 58 Explanation screen 59 Display frame for number of stops 60 Display frame for reaching angle 61 Display screen 62 Enlarged display screen 63 Input history button 64 Input history display screen 65 Close button

A Line graph of average value B Bar graph connecting maximum value and minimum value C Line graph of standard deviation Rotation angle C1, C2 Color S1 Normal weft insertion thread signal S2, S3 Weft stop signal S4 Detection signal S8 Weft selection signal S9 Display data signal

Claims (2)

Based on the weft arrival time detected for each weft insertion, a statistical value related to the arrival time for each predetermined sampling period is calculated, and the statistical values sequentially calculated with the progress of weaving are stored in time series. In a loom equipped with a display device that graphically displays the size of the stored statistical value over time on a time axis,
The loom is a package sensor that detects that the remaining yarn amount of the yarn supply body has become a predetermined amount or less, or a yarn supply body that is provided between two yarn supply bodies in which the end and the start of the weft yarn are tied together. It has a pick tail sensor that detects the switching of
Information relating to the switching of the yarn feeder as a factor that fluctuates the weft yarn travel, which is detection information relating to the switching timing of the yarn feeder based on the detection signal of the package sensor or the pick tail sensor A method for displaying a weft insertion status of a loom, characterized in that information on switching of the loom is displayed on the same screen as the display screen of the statistical value. The loom is a multicolor weft insert loom, and the display of the statistical value in the display device is performed for each color of the weft,
The information related to the switching of the yarn feeder is displayed only on the display screen of the statistical value for the weft color of the yarn feeder corresponding to the sensor that generates the detection signal. The weft insertion status display method for the loom described.

Images