JP2020105652A - Filter clogging detector of air jet loom - Google Patents

Abstract

To provide a filter clogging detector of an air jet loom in which a threshold for detecting clogging of an air filter can be easily set and which is capable of appropriately detecting clogging of the air filter even when there is only one pressure sensor.SOLUTION: The filter clogging detector of an air jet loom that takes in air compressed by a compressor and performs a weft insertion operation using the air taken in comprises an air filter 26 provided at an air taking-in part, a pressure sensor 27 provided in a downstream side of the air filter 26, and a clogging detection part 52 that detects clogging of the air filter 26 on the basis of a difference between a first air pressure detected by the pressure sensor 27 when air flows through the air filter 26 at a first flow rate and a second air pressure detected by the pressure sensor 27 when air flows through the air filter at a second flow rate that is greater than the first flow rate.SELECTED DRAWING: Figure 3

Description

The present invention relates to a filter clogging detection device for an air jet loom.

In an air jet loom, by jetting air from a weft inserting nozzle, a weft yarn is caused to fly in the longitudinal direction of the reed to insert the weft. The air jet loom has an intake section for taking in the air compressed by the air compressor. An air filter is provided in this intake section. Further, an air pipe is connected to the air filter. The air pipe is a pipe for supplying compressed air generated by the air compressor to the air jet loom. The air filter is for removing dust and the like contained in the air.

In an air jet loom, when the air filter is clogged, the pressure loss when the air passes through the air filter increases. Therefore, the air pressure on the downstream side of the air filter is lower than the air pressure on the upstream side of the air filter. When the air pressure decreases due to the clogging of the air filter in this manner, for example, weft insertion errors may occur, or the quality of the fabric may deteriorate.

Therefore, Patent Document 1 discloses a technique in which a pressure switch is provided on the downstream side of an air filter of an air jet loom, and the pressure switch is used to detect a pressure drop due to clogging of the air filter. In the technique disclosed in Patent Document 1, when the operation set value of the pressure switch is set as a threshold value in advance and the pressure at the detection position of the pressure switch is lower than the threshold value due to the pressure drop due to the clogging of the air filter. In addition, the operation of the air jet loom is automatically stopped.

Japanese Utility Model Publication No. 63-24145

However, the technique disclosed in Patent Document 1 has the following problems.
Generally, a large number of air jet looms are installed side by side in one factory (see, for example, FIG. 1 of Patent Document 1). On the other hand, the compressor, which is the source of compressed air, is shared by many air jet looms. For this reason, the air piping that connects the compressor and each air jet loom is installed in the factory in accordance with the installation position of each air jet loom. In such a case, the pipe length from the compressor to the air jet loom changes depending on where in the factory the air jet loom is installed. The pressure of the air supplied to the air jet loom through the air pipe becomes lower as the pipe length from the compressor to the air jet loom becomes longer due to the pressure loss due to the air pipe. Therefore, even if the pressure of the compressed air generated by the compressor is the same, there is a difference in the pressure of the air supplied to each air jet loom. In such a situation, in order to apply the technique disclosed in Patent Document 1, it is necessary to individually set a threshold value that is an operation set value of the pressure switch for each air jet loom having a different pipe length. However, it is difficult to properly set the threshold value for all the air jet looms installed in the factory, because how much the pressure loss due to the air piping occurs is different for each air jet loom. In addition, the pressure of compressed air generated by the air compressor (hereinafter, also referred to as “source pressure”) may change depending on the setting of the air compressor. When the source pressure changes, the pressure of the air supplied to each air jet loom changes, so it is necessary to change the operation set value of the pressure switch accordingly. Therefore, it becomes more and more difficult to set the threshold.

As means for solving such a problem, pressure sensors are provided on both the upstream side and the downstream side of the air filter, and based on the difference between the detected value of the upstream pressure sensor and the detected value of the downstream pressure sensor, It is possible to detect clogging of the filter. In this case, the difference in the air pressure and the change in the source pressure due to the pipe length affect both the detected value of the upstream pressure sensor and the detected value of the downstream pressure sensor, but they have almost no effect on the pressure difference. Don't give. Therefore, it is possible to appropriately detect the clogging of the air filter without setting the threshold individually for each air jet loom. However, since the number of pressure sensors required for one air jet loom increases, the cost increases.

The present invention has been made to solve the above problems, and an object of the present invention is to easily set a threshold value for detecting clogging of an air filter, and to use an air filter of a single pressure sensor. It is an object of the present invention to provide a filter clogging detection device for an air jet loom that can appropriately detect clogging.

The present invention is a filter clogging detection device for an air jet loom that takes in air compressed by a compressor and uses the taken in air to perform a weft insertion operation, including an air filter provided in an air intake section, and an air filter. A pressure sensor provided on the downstream side of the filter, a first air pressure detected by the pressure sensor when air is flowing through the air filter at a first flow rate, and an air filter having a first air pressure higher than the first flow rate. A clogging detection unit that detects clogging of the air filter based on a difference from the second air pressure detected by the pressure sensor when the air is flowing at the flow rate of 2.

In the filter clogging detection device for an air jet loom according to the present invention, the first flow rate may be an air flow rate when the weft insertion operation is stopped.

In the filter clogging detection device for an air jet loom according to the present invention, the second flow rate may be an air flow rate when the weft inserting operation is being performed.

A filter clogging detection device for an air jet loom according to the present invention includes a weft insertion nozzle and a plurality of sub-nozzles arranged downstream of the weft insertion nozzle in the weft transport direction, and the second flow rate is When the weft insertion operation is stopped, the air flow rate when a certain amount of air is flowing through the air filter by opening the valve corresponding to at least one nozzle of the weft insertion nozzle and the plurality of sub-nozzles. May be.

The filter clogging detection device for an air jet loom according to the present invention may include a warning unit that performs a warning process when the clogging detection unit detects clogging of the air filter.

According to the present invention, it is easy to set a threshold value for detecting clogging of an air filter, and it is possible to appropriately detect clogging of an air filter even with one pressure sensor.

It is a schematic diagram showing composition of an air jet loom concerning a 1st embodiment of the present invention. It is a figure which shows arrangement|positioning of the air filter and pressure sensor with which the air jet loom of FIG. 1 is equipped. It is a schematic diagram showing composition of a filter clogging detection device of an air jet loom concerning a 1st embodiment of the present invention.

<Air jet loom>
FIG. 1 is a schematic diagram showing a configuration of an air jet loom according to a first embodiment of the present invention.
In FIG. 1, a compressor 101 is shared by a plurality of air jet looms 1. A plurality of air jet looms 1 are installed side by side in one factory. A plurality of air jet looms 1 are connected to one compressor 101 via an air pipe 102. The compressor 101 is for generating compressed air used in the air jet loom 1. The air pipe 102 distributes and supplies the air compressed by the compressor 101 to the plurality of air jet looms 1. Therefore, the air pipe 102 is branched depending on the installation positions of the plurality of air jet loom 1. In FIG. 1, one of the plurality of air jet looms 1 is shown enlarged, but the configuration of each air jet loom 1 is common.

The air jet loom 1 includes a weft cheese 2, a weft storage device 4, a weft tension correction device 5, a tandem nozzle 6, a main nozzle 7, a plurality of sub-nozzles 8, a reed-beating reed 9, and a weft feeler. 10 are provided. The air jet loom 1 also includes a main valve 12, a tandem valve 14, a main tank 16, a main pressure gauge 17, a main regulator 18, a plurality of sub-valves 22, a sub-tank 23, a sub-regulator 24, and a sub-regulator 24. A pressure gauge 25, an air filter 26, a pressure sensor 27, a controller 31, and a function panel 32 are provided.

The weft cheese 2 supplies the weft 11 used for weft insertion to the weft storage device 4. The weft yarn storage device 4 stores the weft yarn before weft insertion. The weft yarn storage device 4 has a length measuring drum 41 and a locking pin 42. The weft storage device 4 winds and stores the weft 11 supplied from the weft cheese 2 to the weft storage device 4 around the measuring drum 41. The locking pin 42 is a pin capable of locking the weft 11 used for weft insertion. The locking pin 42 is driven by the electromagnetic solenoid 43 to move toward or away from the outer peripheral surface of the length measuring drum 41. The drive of the electromagnetic solenoid 43 is controlled by the control unit 31. The locking pin 42 grips the weft 11 by operating in a direction approaching the outer peripheral surface of the length measuring drum 41. Further, the locking pin 42 operates in a direction away from the outer peripheral surface of the length measuring drum 41 to release the grip of the weft thread 11.

The weft tension correction device 5 is a device that corrects the tension applied to the weft 11 so that excessive tension is not applied to the weft 11. The tandem nozzle 6 and the main nozzle 7 constitute a weft insertion nozzle. The tandem nozzle 6 and the main nozzle 7 are arranged upstream of the reed 9 in the weft transport direction. The plurality of sub nozzles 8 are arranged downstream of the main nozzle 7 in the weft transport direction. The plurality of sub nozzles 8 are arranged along the longitudinal direction of the reed 9.

The main nozzle 7 is connected to the main tank 16 via the main valve 12, and the tandem valve 14 is connected to the main tank 16 via the tandem valve 14. A main pressure gauge 17 and a main regulator 18 are connected to the main tank 16. The main regulator 18 adjusts the pressure of compressed air (hereinafter, also simply referred to as “air”) taken into the air jet loom 1 through the air filter 26. The main pressure gauge 17 measures the pressure of the air adjusted by the main regulator 18. The main tank 16 stores the air whose pressure is adjusted by the main regulator 18. The air stored in the main tank 16 is supplied to the main nozzle 7 via the main valve 12 and is also supplied to the tandem nozzle 6 via the tandem valve 14.

The tandem nozzle 6 injects or stops air according to the open/close state of the tandem valve 14. The main nozzle 7 injects or stops air according to the open/close state of the main valve 12. The main valve 12 and the tandem valve 14 are electrically connected to the control unit 31, respectively. The control unit 31 controls the opening/closing operation of the main valve 12 and the opening/closing operation of the tandem valve 14, respectively.

The plurality of sub-nozzles 8 are arranged along the flight path of the weft yarns that fly in the longitudinal direction of the reed 9 by the air injection from the tandem nozzle 6 and the main nozzle 7. Each of the sub-nozzles 8 imparts a carrying force to the weft 11 which is carried by the jet of air from the tandem nozzle 6 and the main nozzle 7 by the jet of air. The reed 9 performs a beating operation once each time the weft 11 is inserted for one pick. The beating operation is performed by the swinging movement of the reed 9.

The plurality of sub-nozzles 8 are provided as a set of sub-nozzles 8 adjacent to each other in the longitudinal direction of the reed 9. The number of sub-nozzles 8 is different depending on the weave width. The sub-nozzles 8 of each set are connected to the sub-tank 23 via the corresponding sub-valves 22. A sub regulator 24 and a sub pressure gauge 25 are connected to the sub tank 23. The main regulator 18 and the sub-regulator 24 adjust the air pressure. The sub pressure gauge 25 measures the pressure of the air adjusted by the sub regulator 24. The sub tank 23 stores the air whose pressure is adjusted by the sub regulator 24. The air stored in the sub tank 23 is distributed and supplied to each set of the sub nozzles 8 by opening the respective sub valves 22. Each sub valve 22 is electrically connected to the control unit 31. The control unit 31 controls the opening/closing operation of each sub valve 22. The sub-nozzles 8 of each set inject or stop air according to the open/closed state of the corresponding sub-valve 22.

The weft feeler 10 determines whether or not the weft 11 reaches a predetermined position when the weft 11 is weft-inserted by jetting air from the tandem nozzle 6, the main nozzle 7 and the plurality of sub-nozzles 8, respectively. Is to detect. The predetermined position is set in the longitudinal direction of the reed 9 on the weft insertion end side which is the side far from the main nozzle 7 in accordance with the width of the woven cloth.

The air filter 26 and the pressure sensor 27 are arranged in the air intake section 20 as shown in FIG. The intake part 20 is a part that takes in air compressed by the compressor 101 and supplied through the air pipe 102. One end of the air pipe 102 is connected to the air filter 26 provided in the intake section 20 using a joint 21. The air filter 26 is for removing dust and the like contained in the air supplied from the compressor 101 via the air pipe 102. The pressure sensor 27 is provided on the downstream side of the air filter 26. Specifically, as shown in FIG. 1, a pressure sensor 27 is provided in a pipe 28 that connects the air filter 26 and the main regulator 18. The pressure sensor 27 detects the pressure of air on the downstream side of the air filter 26.

The control unit 31 controls the operation of the air jet loom 1. The control unit 31 includes, for example, a central processing unit, a ROM (Read-Only Memory), a RAM (Random Access Memory), and the like. The function panel 32 is connected to the control unit 31 for inputting and outputting various information regarding weft insertion.

FIG. 3 is a schematic diagram showing the configuration of the filter clogging detection device for the air jet loom according to the first embodiment of the present invention.
As shown in FIG. 3, the control unit 31 includes a machine base state detection unit 51, a clogging detection unit 52, and a warning unit 53. The function panel 32 also includes a display unit 61 and an input unit 62. The display unit 61 is for displaying various kinds of information to the user or administrator of the air jet loom 1. The input unit 62 is used by a user or administrator of the air jet loom 1 to input various kinds of information.

The machine base state detection unit 51 detects the state of the machine base of the air jet loom 1. The machine base state detection unit 51 detects, as the machine base state of the air jet loom 1, whether or not the air jet loom 1 is performing a weft inserting operation. The clogging detection unit 52 is notified of the detection result of the machine state detection unit 51.

When the air jet loom 1 is performing the weft inserting operation, the tandem nozzle 6, the main nozzle 7 and the plurality of sub nozzles 8 each repeatedly inject and stop the air in accordance with the swing motion of the reed 9. It's time. On the other hand, when the air jet loom 1 is not performing the weft inserting operation is when the air jet loom 1 is not performing the weft inserting operation. The control unit 31 stops the weft insertion operation of the air jet loom 1 when, for example, a weft break occurs. When the air jet loom 1 stops the weft inserting operation, the swinging operation of the reed 9 is held in a stopped state, and the main valve 12, the tandem valve 14 and the sub valve 22 are held in respective closed states. .. Therefore, all of the tandem nozzle 6, the main nozzle 7, and the plurality of sub nozzles 8 are maintained in a state where the air injection is continuously stopped. However, a breeze circuit (not shown) is connected to the main nozzle 7, and the breeze circuit may cause a breeze to continue to flow from the main nozzle 7 even when the weft inserting operation is stopped. The breeze circuit is provided for the purpose of maintaining the attitude of the weft yarn 11.

The clogging detection unit 52 detects clogging of the air filter 26 based on the detection result of the pressure sensor 27. Here, the first air pressure detected by the pressure sensor 27 when the air is flowing through the air filter 26 at the first flow rate is set to P1, and the air filter 26 is set to the second flow rate higher than the first flow rate. The second air pressure detected by the pressure sensor 27 while the air is flowing is P2. In such a case, the clogging detection unit 52 detects clogging of the air filter 26 based on the difference between the first air pressure P1 and the second air pressure P2. A threshold for determining whether or not the air filter 26 is clogged is preset in the clogging detection unit 52. This threshold value is set according to the operating conditions of the air jet loom 1.

The warning unit 53 performs a predetermined warning process when the clogging detection unit 52 detects clogging of the air filter 26. As the warning process performed by the warning unit 53, for example, a warning message such as “The air filter is clogged” or a warning message such as “It is time to replace the air filter” is displayed on the display unit 61 of the function panel 32. It is possible to do this. The content of the warning message may be any content as long as the user or the administrator of the air jet loom 1 can recognize that the air filter 26 is clogged.

Next, the operation of the air jet loom according to the first embodiment of the present invention will be described.
First, when the air jet loom 1 is performing the weft inserting operation, the control unit 31 releases the grip of the weft yarn 11 by the locking pin 42 for each pick, and the main valve 12, the tandem valve 14, and the Each of the plurality of sub valves 22 is opened at a predetermined timing. As a result, air is jetted from the tandem nozzle 6, the main nozzle 7, and the plurality of sub-valves 22 at predetermined timings, and the weft 11 is conveyed in the longitudinal direction of the reed 9 by the jet of air. Then, when the tip of the weft 11 reaches the detection position of the weft feeler 10, weft insertion for one pick is completed. As described above, while the air jet loom 1 is performing the weft inserting operation, the tandem nozzle 6, the main nozzle 7, and the plurality of sub-valves 22 each repeatedly inject and stop air at a predetermined cycle. Further, the state in which the air jet loom 1 is performing the weft inserting operation is detected by the machine base state detection unit 51 by, for example, a signal output unit (not shown) of the control unit 31 outputting a machine base operation signal. Then, the detection result is notified from the machine base state detection unit 51 to the clogging detection unit 52.

On the other hand, for example, when the air jet loom 1 stops the weft insertion operation due to the occurrence of weft breakage, the control unit 31 closes the main valve 12, the tandem valve 14 and the plurality of sub valves 22 respectively. Hold the state. As a result, the tandem nozzle 6, the main nozzle 7, and the plurality of sub-valves 22 are all held in a state in which the injection of air is stopped. The state in which the air jet loom 1 has stopped the weft insertion operation is detected by the machine frame state detection unit 51 by, for example, the signal output unit (not shown) of the control unit 31 outputting a machine frame stop signal. Then, the detection result is notified from the machine base state detection unit 51 to the clogging detection unit 52.

On the other hand, the clogging detection unit 52 detects the first air pressure P1 detected by the pressure sensor 27 when the air jet loom 1 stops the weft insertion operation based on the detection result of the machine base state detection unit 51. , The second air pressure P2 detected by the pressure sensor 27 while the air jet loom 1 is performing the weft inserting operation. Either the first air pressure P1 or the second air pressure P2 may be read first.

Here, when the air jet loom 1 is stopping the weft insertion operation, the main valve 12, the tandem valve 14, and the plurality of sub valves 22 are each kept closed. Therefore, when the weft insertion operation is stopped, the flow rate of the air flowing through the air filter 26 becomes extremely small or becomes substantially zero. The situation in which the flow rate of the air flowing through the air filter 26 is low corresponds to the case where the air flows through the air filter 26 at the first flow rate. Then, when the air flows through the air filter 26 at the first flow rate, the influence of the pressure loss due to the air filter 26 becomes extremely small. Therefore, the air pressure on the upstream side of the air filter 26 and the air pressure on the downstream side of the air filter 26 become substantially the same pressure. Therefore, the first air pressure P1 detected by the pressure sensor 27 when the air jet loom 1 stops the weft insertion operation shows a pressure value equivalent to the air pressure on the upstream side of the air filter 26. ..

On the other hand, when the air jet loom 1 is performing the weft inserting operation, air is periodically jetted from each of the main valve 12, the tandem valve 14 and the plurality of sub valves 22. For this reason, the flow rate of the air flowing through the air filter 26 during the weft insertion operation is much larger than the air flow rate during the stop of the weft insertion operation. The situation in which the flow rate of the air flowing through the air filter 26 is high corresponds to the case where the air flows through the air filter 26 at the second flow rate. When the air flows through the air filter 26 at the second flow rate, the influence of the pressure loss due to the air filter 26 becomes very large. Therefore, the air pressure on the downstream side of the air filter 26 becomes lower than the air pressure on the upstream side of the air filter 26 due to the pressure loss due to the air filter 26. Therefore, the second air pressure P2 detected by the pressure sensor 27 while the air jet loom 1 is performing the weft inserting operation indicates a pressure value reduced by the pressure loss due to the air filter 26. Further, the pressure loss due to the air filter 26 becomes large when the air filter 26 is clogged. Therefore, the air pressure reduced due to the clogging of the air filter 26 can be detected using the pressure sensor 27.

Here, the first air pressure P1 and the second air pressure P2 will be described in more detail.
First, the first air pressure P1 is an air pressure obtained by subtracting a pressure loss amount according to the length of the air pipe 102 from the pressure of the compressed air generated by the compressor 101. Further, since the first air pressure P1 is the air pressure detected by the pressure sensor 27 when the flow rate of the air flowing through the air filter 26 is small due to the stop of the weft inserting operation, the air filter 26 is clogged. However, it is hardly affected by clogging. Therefore, the first air pressure P1 is determined by the pressure of the compressed air generated by the compressor 101 and the pressure loss according to the pipe length of the air pipe 102.

On the other hand, the second air pressure P2 is the air pressure detected by the pressure sensor 27 when the flow rate of the air flowing through the air filter 26 is large due to the weft insertion operation. Receive strongly. The second air pressure P2 is the air pressure obtained by subtracting the pressure loss of the air filter 26 from the air pressure on the upstream side of the air filter 26. Therefore, the second air pressure P2 is not only the pressure loss of the compressed air generated by the compressor 101 and the pressure loss according to the pipe length of the air pipe 102, but also the pressure loss of the air filter 26, and thus the air filter 26. Depends on the occurrence of clogging. Therefore, when the air filter 26 is clogged, the difference between the first air pressure P1 and the second air pressure P2 indicates the degree of pressure loss due to the clogging of the air filter 26.

Therefore, the clogging detection unit 52 performs the weft inserting operation of the air jet loom 1 and the first air pressure P1 detected by the pressure sensor 27 while the weft inserting operation of the air jet loom 1 is stopped. The difference ΔPa with the second air pressure P2 detected by the pressure sensor 27 when the pressure sensor 27 is present is determined by the arithmetic expression of ΔPa=P1−P2. Further, the clogging detection unit 52 compares the pressure difference ΔPa obtained by the calculation with a threshold value set in advance for clogging detection. Then, when the pressure difference ΔPa is equal to or more than the threshold value, the clogging detection unit 52 determines that the air filter 26 is clogged. The judgment result of the clogging detection unit 52 is notified to the warning unit 53.

The warning unit 53 performs a warning process when the clogging detection unit 52 detects clogging of the air filter 26. As a result, a warning message is displayed on the display unit 61 of the function panel 32. Therefore, the user or administrator of the air jet loom 1 confirms the warning message displayed on the display unit 61 to confirm that the air filter 26 is clogged, or the air filter 26 needs to be replaced. You can know that.

In the first embodiment of the present invention, the first air pressure P1 detected by the pressure sensor 27 when a small amount of air is flowing through the air filter 26 due to the stop of the weft inserting operation and the execution of the weft inserting operation. The clogging detection unit 52 reads from the pressure sensor 27 the second air pressure P2 detected by the pressure sensor 27 when a large amount of air is flowing through the air filter 26. Then, the clogging detection unit 52 is configured to detect clogging of the air filter 26 based on the difference ΔPa between the first air pressure P1 and the second air pressure P2. In this configuration, the difference ΔPa between the first air pressure P1 and the second air pressure P2 indicates the pressure loss due to clogging of the air filter 26. Moreover, when the pressure of the air compressed by the compressor 101 changes, the first air pressure P1 and the second air pressure P2 both change accordingly. Therefore, the difference ΔPa between the first air pressure P1 and the second air pressure P2 hardly changes even if the pressure of the air compressed by the compressor 101 changes. Further, the first air pressure P1 and the second air pressure P2 both include pressure loss according to the pipe length of the air pipe 102. Therefore, it is not necessary to change the threshold value for detecting clogging according to the length of the air pipe 102. Therefore, it becomes easy to set the threshold value for detecting the clogging of the air filter 26. Further, it is possible to properly detect clogging of the air filter 26 by using one pressure sensor 27.

Subsequently, a second embodiment of the present invention will be described.
In the second embodiment of the present invention, the second air flow rate applied when detecting the second air pressure is different from the first embodiment described above. That is, in the first embodiment, the flow rate of the air flowing through the air filter 26 when the air jet loom 1 is performing the weft inserting operation is the second air flow rate. On the other hand, in the second embodiment, when the air jet loom 1 has stopped the weft inserting operation, the tandem nozzle 6, the main nozzle 7, and the valve corresponding to at least one of the plurality of sub nozzles By opening, the air flow rate when a certain amount of air is flowing through the air filter 26 is set as the second air flow rate. The details will be described below.

First, in the second embodiment, when the air jet loom 1 stops the weft insertion operation, the control unit 31 controls the open/closed states of the main valve 12, the tandem valve 14, and the plurality of sub valves 22, The flow rate of the air flowing through the air filter 26 is switched from the first flow rate to the second flow rate or from the second flow rate to the first flow rate.

In that case, the control unit 31 keeps the main valve 12, the tandem valve 14, and the plurality of sub-valves 22 closed while the air jet loom 1 stops the weft insertion operation. The flow rate of the air flowing through the air filter 26 while the air is flowing. Therefore, the first flow rate is the flow rate of the air flowing through the air filter 26 when the tandem nozzle 6, the main nozzle 7, and the plurality of sub-nozzles 8 all stop the ejection of air. In this case, the first flow rate becomes very small or becomes substantially zero.

On the other hand, at the second flow rate, the control unit 31 opens at least one of the main valve 12, the tandem valve 14 and the plurality of sub-valves 22 in a state in which the weft inserting operation of the air jet loom 1 is stopped. The flow rate of the air flowing through the air filter 26 while the air is flowing. Therefore, the second flow rate is the air flow rate when a certain amount of air is flowing through the air filter 26 by the air injection from at least one of the tandem nozzle 6, the main nozzle 7, and the plurality of sub nozzles 8. Becomes In this case, the second flow rate is a constant air flow rate that is higher than the first flow rate and lower than during the weft inserting operation. Moreover, the second flow rate is higher than the first flow rate.

In the second embodiment, as a preferable example for flowing the air at the second flow rate through the air filter 26, in the second embodiment, the control unit 31 closes both the main valve 12 and the tandem valve 14, and the plurality of sub valves 22 are provided. Only some of the sub-valves 22 are opened. For example, among the six sub-valves 22 shown in FIG. 1, only three sub-valves 22 are opened. As a result, air is jetted only from the sub-nozzle 8 corresponding to the opened sub-valve 22, and a certain amount of air, which is smaller than that during the weft inserting operation, flows through the air filter 26 by this jet of air. Although only three sub-valves 22 are opened here, the present invention is not limited to this, and one, two, or four or more sub-valves 22 may be opened. Further, only the main valve 12 or only the sub valve 22 may be opened. Further, the opening degree of the valve to be opened may be adjusted to be smaller than that during the weft inserting operation.

On the other hand, the clogging detection unit 52 detects the pressure sensor 27 when the air flows at the first flow rate through the air filter 26 while the machine base state detection unit 51 detects the stop of the weft insertion operation. The first air pressure P11 and the second air pressure P12 detected by the pressure sensor 27 when the air flows at the second flow rate through the air filter 26 are read. At this time, the first air pressure P11 read by the clogging detection unit 52 is detected by the pressure sensor 27 when a very small amount of air is flowing through the air filter 26 or when almost no air is flowing through the air filter 26. It is the detected air pressure. The second air pressure P12 read by the clogging detection unit 52 is the air pressure detected by the pressure sensor 27 when a constant amount of air, which is smaller than that during the weft inserting operation, flows through the air filter 26. ..

Next, the clogging detection unit 52 obtains the difference ΔPb between the first air pressure P11 and the second air pressure P12 read as described above by the arithmetic expression of ΔPb=P11−P12. Further, the clogging detection unit 52 compares the pressure difference ΔPb obtained by the calculation with a threshold value set in advance for clogging detection. Then, when the pressure difference ΔPb is equal to or more than the threshold value, the clogging detection unit 52 determines that the air filter 26 is clogged. On the other hand, the warning unit 53 performs a warning process when the clogging detection unit 52 detects clogging of the air filter 26.

In the second embodiment of the present invention, when a certain amount of air is flowing through the air filter 26 by opening the valve corresponding to at least one of the tandem nozzle 6, the main nozzle 7 and the plurality of sub nozzles 8. The air flow rate is the second air flow rate. Then, the second air pressure P12 detected by the pressure sensor 27 when air is flowing through the air filter 26 at the second air flow rate is applied to detect clogging of the air filter 26. There is. In this configuration, the second air pressure P12 is detected when a certain amount of air is flowing through the air filter 26 regardless of the difference in the operating conditions of the air jet loom 1. Therefore, the clogging of the air filter 26 can be detected without being affected by the operating conditions of the air jet loom 1.

<Modifications, etc.>
The technical scope of the present invention is not limited to the above-described embodiments, and includes various modifications and improvements as long as a specific effect obtained by the constituent features of the invention or a combination thereof can be derived.

For example, in the above-described embodiment, as the warning process performed by the warning unit 53, the process of displaying a warning message on the display unit 61 of the function panel 32 is illustrated, but the present invention is not limited to this, and the warning message is output by voice, for example. Alternatively, the warning message may be displayed and the voice may be output in parallel. Further, the process of outputting the warning message by mail transmission may be applied to the mobile device carried by the user or the administrator of the air jet loom 1.

Further, in the above-described embodiment, an example in which the weft insertion operation is stopped when a weft break occurs is described, but the trigger for stopping the weft insertion operation is not limited to the weft break, and other factors (for example, warp break or Warp beam replacement).

1 air jet loom, 6 tandem nozzle (weft insertion nozzle), 7 main nozzle (weft insertion nozzle), 8 sub nozzle, 12 main valve, 14 tandem valve, 20 intake section, 22 sub valve, 26 air filter, 27 pressure sensor , 52 Clogging detection part, 53 warning part.

Claims (5)

A filter clogging detection device for an air jet loom that takes in air compressed by a compressor and uses the taken in air to perform weft insertion operation,
An air filter provided in the air intake section,
A pressure sensor provided on the downstream side of the air filter,
When air flows at a first flow rate through the air filter, a first air pressure detected by the pressure sensor and air at a second flow rate higher than the first flow rate flow through the air filter. A filter clogging detection device for an air jet loom, comprising: a clogging detection unit that detects clogging of the air filter based on a difference from the second air pressure detected by the pressure sensor. The filter clogging detection device for an air jet loom according to claim 1, wherein the first flow rate is an air flow rate when the weft insertion operation is stopped. The filter clogging detection device for an air jet loom according to claim 1 or 2, wherein the second flow rate is an air flow rate when the weft insertion operation is performed. Weft insertion nozzle,
A plurality of sub-nozzles arranged on the downstream side of the weft insertion nozzle in the weft transport direction,
When the weft insertion operation is stopped, the second flow rate is such that a certain amount of air is generated by opening a valve corresponding to at least one nozzle of the weft insertion nozzle and the plurality of sub-nozzles. The filter clogging detection device for an air jet loom according to claim 1, which is an air flow rate when flowing through the filter. The filter clogging detection device for an air jet loom according to claim 1, further comprising: a warning unit that performs a warning process when the clogging detection unit detects clogging of the air filter.

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