JP2020084341A - Air jet loom - Google Patents

Abstract

To provide an air jet loom that can adjust a position of a high pressure area and a position of a low pressure area in a weft insertion path by easily changing an ejection amount of air of each of multiple sub-nozzles.SOLUTION: An air jet loom 100 comprises: a main nozzle 15 ejecting weft to a weft insertion path 21; multiple sub-nozzles 14 that are disposed along the weft insertion path 21 and eject air; and an air tank 40 that is connected to the multiple sub-nozzles 14 and stores air inside. The multiple sub-nozzles 14 has a first sub-nozzle 14a that ejects air to a high pressure area H of the weft insertion path 21 and a second sub-nozzle 14b that ejects air to a low pressure area L of the weft insertion path 21. The flow path resistance of a first air flow path 16a between the first sub-nozzle 14a and the air tank 40 is smaller than the flow path resistance of a second air flow path 16b between the second sub-nozzle 14b and the air tank 40.SELECTED DRAWING: Figure 1

Description

The present invention relates to an air jet loom.

The air jet loom includes a main nozzle that ejects a weft and a plurality of sub nozzles that are arranged along the weft insertion path of the weft. By ejecting air from the sub-nozzle, the traction force for conveying the weft yarn is increased in the weft insertion path.

Here, on the inlet side of the weft insertion path of the weft, it is necessary to set a large amount of air jetted from the sub-nozzle in order to increase the traction force of the weft. Further, also on the exit side of the weft insertion path of the weft, in order to increase the tension of the weft, similarly, it is necessary to set a large amount of air jetted from the sub nozzle. On the other hand, in the vicinity of the central portion of the weft insertion path of the weft, the amount of air jetted from the sub nozzle may be smaller than that at the inlet side or the outlet side. Therefore, in order to improve energy-saving performance, the air jet loom shown in FIG. 1 of Patent Document 1 is provided with an air tank connected to a sub-nozzle provided near the center of the weft inserting path, and an inlet side and an outlet side of the weft inserting path. It is different from the air tank connected to the sub nozzle. Specifically, in the air jet loom shown in FIG. 1 of Patent Document 1, the air pressure of an air tank connected to a sub-nozzle provided near the center of the weft inserting path is provided on the inlet side and the outlet side of the weft inserting path. Lower than the air pressure of the air tank connected to the sub nozzle.

European Patent Specification No. 2163670

However, in the weft insertion path of the air jet loom illustrated in FIG. 1 of Patent Document 1, the position of a high pressure region where the amount of air ejected from the sub nozzle is large and the amount of air ejected from the sub nozzle are determined by the air tank to which the sub nozzle is connected. The positions of the low-pressure regions where there is little noise are fixed. Therefore, there is a problem that the positions of the high pressure region and the low pressure region of the weft insertion path cannot be changed according to the width of the woven cloth.

There is also a method of changing the pitch of the sub nozzle between the high pressure region and the low pressure region, but in this case also, it is difficult to change the position of the high pressure region and the position of the low pressure region of the weft inserting path. If the arrangement is irregular, there is also a problem that the arrangement of the pipes connected to the sub nozzles becomes complicated.

The present invention has been made to solve such a problem, and easily adjusts the air ejection amount of each of the plurality of sub-nozzles to adjust the positions of the high pressure region and the low pressure region of the weft insertion path of the weft. An object of the present invention is to provide an air jet loom that can be manufactured.

In order to solve the above problems, an air jet loom according to the present invention includes a main nozzle that ejects a weft into a weft insertion path, a plurality of sub-nozzles that are arranged along the weft insertion path and eject air, and a plurality of sub-nozzles. The sub-nozzle is provided with an air tank that stores air therein, and the plurality of sub-nozzles includes a first sub-nozzle that ejects air to a high-pressure area of the weft insertion path and a second sub-nozzle that ejects air to a low-pressure area of the weft insertion path. The flow path resistance of the first air flow path between the first sub nozzle and the air tank is smaller than the flow resistance of the second air flow path between the second sub nozzle and the air tank.

A first hose is provided between the first sub-nozzle and the air tank of the air jet loom according to the present invention, and a first sleeve is fitted inside the end of the first hose on the air tank side. A second hose is provided between the two sub-nozzles and the air tank, a second sleeve is fitted inside the end of the second hose on the air tank side, and the inner diameter of the second sleeve is the inner diameter of the first sleeve. May be smaller than.

Also, the length of the second hose may be longer than the length of the first hose.
The roughness of the inner surface of the second hose may be rougher than the roughness of the inner surface of the first hose.
Furthermore, the inner surface area of the second hose may be larger than the inner surface area of the first hose.

According to the air jet loom according to the present invention, it is possible to easily change the ejection amount of air from each of the plurality of sub-nozzles to adjust the positions of the high pressure region and the low pressure region of the weft insertion path of the weft.

1 is a schematic diagram of an air jet loom according to an embodiment of the present invention. It is sectional drawing which shows the structure of the connection part of the 1st hose or the 2nd hose of an air jet loom shown in FIG. 1, and an air tank. It is sectional drawing which shows the attachment structure of the end part by the side of the air tank of the 1st hose or the 2nd hose of the air jet loom shown in FIG. It is sectional drawing which shows typically the difference of the shape of the sleeve attached to the 1st hose or the 2nd hose of the air jet loom shown in FIG. 1, and FIG.4(a) is a 1st hose provided in the 1st hose. 4B shows the shape, and FIG. 4B shows the shape of the second sleeve provided on the second hose. It is sectional drawing which shows typically the difference of the shape of the 1st hose or the 2nd hose of the air jet loom which concerns on another embodiment of this invention, FIG.5(a) shows the shape of a 1st hose, FIG. 5B shows the shape of the second hose. It is sectional drawing which shows typically the difference of the shape of the 1st hose or the 2nd hose of the air jet loom which concerns on another embodiment of this invention, FIG.6(a) shows the shape of a 1st hose, FIG. 6B shows the shape of the second hose. It is sectional drawing which shows typically the difference of the shape of the 1st hose or the 2nd hose of the air jet loom which concerns on another embodiment of this invention, FIG.7(a) shows the shape of a 1st hose, FIG. 7B shows the shape of the second hose.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
As shown in FIG. 1, the air jet loom 100 includes a reed 20, a main nozzle 15 for injecting a weft into a weft insertion path 21 formed along the reed 20, and an arrangement 24 along the weft insertion path 21. It has one sub nozzle 14. The inlet side and the outlet side of the weft inserting path 21 are the high pressure region H. A low pressure region L is formed between the high pressure region H on the inlet side and the high pressure region H on the outlet side of the weft insertion path 21. Here, the sub-nozzle 14 arranged at a position corresponding to the high pressure region H and ejecting air to the high pressure region H is referred to as a first sub nozzle 14a, and is arranged at a position corresponding to the low pressure region L and ejects air to the low pressure region L. The sub nozzle 14 is referred to as a second sub nozzle 14b. The amount of air ejected from the first sub nozzle 14a is larger than the amount of air ejected from the second sub nozzle 14b. Further, the number of the first sub-nozzles 14a corresponding to the high pressure area H on the inlet side of the weft inserting path 21 is eight, and the number of the first sub nozzles 14a corresponding to the high pressure area H on the outlet side of the weft inserting path 21 is also. Similarly, there are eight.
By providing the high-pressure region H on the inlet side of the weft insertion path 21, the traction force for conveying the weft yarn can be increased. Further, since the high pressure region H is provided on the exit side of the weft inserting path 21, the tension applied to the weft can be increased.

One end of the first hose 13a is connected to each of the first sub nozzles 14a. The other end of the first hose 13a is connected to an air tank 40 that stores air inside. Further, one end of the second hose 13b is connected to each of the second sub nozzles 14b. The other end of the second hose 13b is also connected to the air tank 40. Further, one valve 30 is provided between the first hose 13a and the air tank 40 for each of the four first hoses 13a. Similarly, one valve 30 is provided between the second hose 13b and the air tank 40 for each of the four second hoses 13b. That is, six valves 30 are provided for the 16 first sub-nozzles 14a and the eight second sub-nozzles 14b.

More specifically, as shown in FIG. 2, the first hose 13 a or the second hose 13 b is connected to the air tank 40 via the fixing member 50. The ends of the first hose 13a or the second hose 13b are attached to the fixing member 50 by the connector 11. The fixing member 50 is formed with a connecting portion flow path 51 that connects the first hose 13a or the second hose 13b to the air tank 40. Further, the valve 30 is attached to the fixing member 50, and switches the connection passage 51 through which air flows between a communication state and a closed state, and adjusts the flow rate of air flowing through the connection passage 51. You can

As shown in FIG. 3, inside the end portion on the air tank 40 side of the first hose 13a or the second hose 13b inserted into the connecting portion flow path 51 of the fixing member 50, in order to prevent collapse of the hose, A cylindrical sleeve 12 is fitted. Here, as shown in FIG. 4A, the sleeve 12 fitted inside the end portion of the first hose 13a on the air tank 40 side is referred to as a first sleeve 12a. Further, as shown in FIG. 4B, the sleeve 12 fitted inside the end portion of the second hose 13b on the air tank 40 side is referred to as a second sleeve 12b. Here, the inner diameter D1 of the first sleeve 12a is larger than the inner diameter D2 of the second sleeve 12b. Thereby, the flow resistance of the first air flow passage 16a formed inside the first hose 13a between the first sub nozzle 14a and the air tank 40 is equal to the second hose between the second sub nozzle 14b and the air tank 40. It becomes smaller than the flow passage resistance of the second air flow passage 16b formed inside 13b. Here, the flow path resistance is a force that obstructs the flow of air due to the shapes of the first air passage 16a and the second air passage 16b.

As described above, in the air jet loom 100 according to this embodiment, the flow resistance of the first air flow passage 16a between the first sub nozzle 14a and the air tank 40 is the same as that between the second sub nozzle 14b and the air tank 40. It is smaller than the flow resistance of the two air flow paths 16b. Thereby, the amount of air ejected from the first sub-nozzle 14a to the high pressure region H of the weft inserting path 21 is made larger than the amount of air ejected from the second sub nozzle 14b to the low pressure region L of the weft inserting path 21. You can That is, by simply changing the flow path resistance of the air flow path between the sub-nozzle 14 and the air tank 40, the sub-nozzle 14 connected to the air flow path having a lower flow path resistance is the first sub-nozzle 14a having a large air ejection amount. Therefore, the sub-nozzle 14 connected to the air flow path having a higher flow path resistance becomes the second sub-nozzle 14b in which the air ejection amount is small. Thus, in the weft insertion path 21, the high pressure region H is set at the position corresponding to the first sub nozzle 14a, and the low pressure region L is provided at the position corresponding to the second sub nozzle 14b. Therefore, by appropriately changing the flow path resistance of the air flow path between the sub nozzle 14 and the air tank 40, the ejection amount of the air of the sub nozzle 14 can be easily changed, and the position and the low pressure of the high pressure region H of the weft insertion path 21 can be changed. By adjusting the position of the region L, it is possible to cope with a change in the thread width of the woven cloth. Further, regardless of the air tank 40 and the valve 30 to which the individual sub-nozzles 14 are connected, it is possible to adjust the ejection amount of air for each sub-nozzle 14.

Further, in the air jet loom 100, the sleeve 12 is selected between the first sleeve 12a having a large inner diameter D1 and the second sleeve 12b having a small inner diameter D2, and the sleeve 12 and the sub-nozzle 14 and the air tank 40 are appropriately replaced. The flow resistance of the air flow path between them can be changed. Therefore, it is possible to determine how much the amount of air jetted from the sub-nozzle 14 is reduced according to the size of the sleeve 12, and to easily change the positions of the high pressure region H and the low pressure region L of the weft inserting path 21. You can When adjusting the amount of air jetted from the sub-nozzle 14 by the difference in the dimensions of the sleeve 12, the rigidity of the hose between the sub-nozzle 14 and the air tank 40 is not affected by the difference in the flow resistance of the air flow passage. ..

Further, as shown in FIG. 5, in order to change the flow passage resistance of the air flow passage between the sub nozzle 14 and the air tank 40, the inner diameter of the first hose 13a and the inner diameter of the second hose 13b are different from each other. It may be one. At this time, the inner diameter of the first hose 13a shown in FIG. 5(a) is larger than the inner diameter of the second hose 13b shown in FIG. 5(b), and the flow resistance of the second air flow passage 16b is equal to that of the first air. It is larger than the flow path resistance of the flow path 16a.

Further, in order to change the flow path resistance of the air flow path between the sub nozzle 14 and the air tank 40, the length of the second hose 13b is made longer than the length of the first hose 13a, and the second air flow path 16b is formed. The flow path resistance of 1 may be greater than the flow path resistance of the first air flow path 16a. Here, when the length of the second hose 13b and the length of the first hose 13a are changed, it is possible to use hoses having the same diameter and the same material, and thus it becomes easier to supply the components.

Further, as shown in FIG. 6, in order to change the flow passage resistance of the air flow passage between the sub nozzle 14 and the air tank 40, the second hose 13b may be subjected to a treatment for roughening the inner surface. .. Specifically, by attaching an abrasive to the inner surface of the second hose 13b, the roughness of the inner surface of the second hose 13b shown in FIG. 6(b) can be compared with the first hose shown in FIG. 6(a). It is made rougher than the roughness of the inner surface of 13a. As a result, the flow resistance of the second air flow passage 16b is made higher than that of the first air flow passage 16a.

Further, as shown in FIG. 7, in order to change the flow passage resistance of the air flow passage between the sub nozzle 14 and the air tank 40, the cross-sectional shape of the first hose 13a and the cross-sectional shape of the second hose 13b are mutually different. It may be different. Specifically, while the cross-sectional shape of the inner surface of the first hose 13a shown in FIG. 7(a) is circular, the cross-sectional shape of the inner surface of the second hose 13b shown in FIG. 7(b) is uneven. have. That is, the surface area of the inner surface of the second hose 13b is larger than the surface area of the inner surface of the first hose 13a. Therefore, as a result, the flow passage resistance of the second air flow passage 16b becomes larger than the flow passage resistance of the first air flow passage 16a.
The cross-sectional shape of the inner surface of the first hose 13a and the cross-sectional shape of the inner surface of the second hose 13b can be made different by changing the extrusion die for forming the hose.

Further, in order to make it easier to distinguish between the first hose 13a and the second hose 13b, the color of the first hose 13a and the color of the second hose 13b may be different.

12a 1st sleeve, 12b 2nd sleeve, 13a 1st hose, 13b 2nd hose, 14 sub nozzle, 14a 1st sub nozzle, 14b 2nd sub nozzle, 15 main nozzle, 16a 1st air flow path, 16b 2nd air flow path , 21 weft insertion path, 100 air jet loom.

Claims (5)

A main nozzle that injects weft into the weft insertion path,
A plurality of sub-nozzles arranged along the weft insertion path and ejecting air,
An air tank connected to the plurality of sub-nozzles and storing air therein,
The plurality of sub nozzles,
A first sub-nozzle for ejecting air into the high pressure region of the weft insertion path,
A second sub-nozzle for ejecting air into the low pressure region of the weft insertion path,
An air jet loom in which a flow passage resistance of a first air flow passage between the first sub nozzle and the air tank is smaller than a flow passage resistance of a second air flow passage between the second sub nozzle and the air tank. A first hose is provided between the first sub-nozzle and the air tank, and a first sleeve is fitted inside an end portion of the first hose on the air tank side,
A second hose is provided between the second sub-nozzle and the air tank, and a second sleeve is fitted inside the end portion of the second hose on the air tank side,
The inner diameter of the second sleeve is smaller than the inner diameter of the first sleeve,
The air jet loom according to claim 1. A first hose is provided between the first sub-nozzle and the air tank,
A second hose is provided between the second sub nozzle and the air tank,
The length of the second hose is longer than the length of the first hose,
The air jet loom according to claim 1. A first hose is provided between the first sub-nozzle and the air tank,
A second hose is provided between the second sub nozzle and the air tank,
The roughness of the inner surface of the second hose is rougher than the roughness of the inner surface of the first hose,
The air jet loom according to claim 1. A first hose is provided between the first sub-nozzle and the air tank,
A second hose is provided between the second sub nozzle and the air tank,
The inner surface area of the second hose is larger than the inner surface area of the first hose,
The air jet loom according to claim 1.

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