JP6747279B2 - Water jet loom weft insertion nozzle - Google Patents

Description

The present invention relates to a weft insertion nozzle for a water jet loom.

The water jet loom inserts the weft yarn into the warp yarn opening by pumping water with a pump and jetting the water from the weft inserting nozzle.
For example, as shown in FIG. 7, the weft inserting nozzle of Patent Document 1 includes a cylindrical nozzle body 101, an extending portion 102 integrally formed with the nozzle body 101, and a coupling 103 on the extending portion 102. And a pipe 104 connected through the pipe 104. The extending portion 102 extends in a direction orthogonal to the axial direction of the nozzle body 101. The extending part 102 has a first water supply channel 102a. The coupling 103 has a second water supply passage 103a communicating with the first water supply passage 102a.

The end of the pipe 104 is coupled to the coupling 103 while being inserted inside the coupling 103. The pipe 104 is supported by the nozzle joint 106 by attaching the coupling 103 to the nozzle joint 106 with the bolt 105. Further, the nozzle body 101 is attached to the nozzle joint 106 by screwing a bolt 107 penetrating the extending portion 102 into the nozzle joint 106 with the coupling 103 inserted inside the extending portion 102. There is. Therefore, the nozzle body 101 and the coupling 103 are directly connected.

A needle 108 is inserted in the nozzle body 101. The nozzle body 101 and the needle 108 include an annular groove 109 that extends around the needle 108 and communicates with the first water supply passage 102a, an annular chamber 110 that is located downstream of the annular groove 109 in the water flow direction, and an annular shape. A plurality of water supply holes 111 that communicate the groove 109 and the annular chamber 110 are formed in cooperation with each other. A commutator 112 is arranged in the annular chamber 110. The commutator 112 has a through hole 112a. The needle 108 passes through the inside of the through hole 112a. Between the inner peripheral surface of the through hole 112a and the outer peripheral surface of the needle 108, there is an acceleration flow channel (orifice flow channel) whose flow channel cross-sectional area decreases toward the downstream side so as to squeeze and accelerate the high-pressure water flow. ..

In the pipe 104, water pumped by a pump not shown flows. The water flowing in the pipe 104 is supplied to the first water supply passage 102a via the second water supply passage 103a, and the water supplied to the first water supply passage 102a is the annular groove 109, the plurality of water supply holes 111, It is jetted together with the weft from the nozzle body 101 through the annular chamber 110 and the through hole 112a. The jetted weft yarns fly in the warp shed due to the water flow. As a result, the weft thread is inserted into the warp opening.

By the way, if foreign matter accumulates inside the nozzle body 101, weft insertion failure may occur. Therefore, the bolt 107 is removed, and the extension portion 102 is separated from the nozzle joint 106 while pulling out the extension portion 102 from the coupling 103. The inside of the main body 101 is cleaned.

JP, 2005-163235, A

As described above, in the weft insertion nozzle of Patent Document 1, the nozzle body 101 and the coupling 103 are directly connected. Therefore, when the nozzle body 101 is separated from the nozzle joint 106 in order to clean the inside of the nozzle body 101, the extending portion 102 is pulled out from the coupling 103 and separated from the nozzle joint 106. When the nozzle body 101 is attached to the nozzle joint 106 again after cleaning the inside of the nozzle body 101, the nozzle body 101 is attached to the nozzle joint 106 while inserting the coupling 103 inside the extending portion 102. .. When the work of attaching and detaching the nozzle joint 106 in the nozzle body 101 is repeatedly performed, the coupling 103 may be damaged. If the coupling 103 is damaged, water leakage may occur, so it is necessary to replace the coupling 103. However, when the coupling 103 is replaced, the pipe 104 connected to the coupling 103 is also replaced. Since it has to be replaced, it takes time and effort to replace the parts.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a weft insertion nozzle for a water jet loom that can reduce the time and effort required for component replacement work.

A weft insertion nozzle for a water jet loom that solves the above-mentioned problems is a nozzle main body having a nozzle internal flow passage, a nozzle joint having the nozzle main body attached and having a nozzle joint internal flow passage, and an internal attachment provided to the nozzle joint. Is connected to the nozzle joint internal flow path, a pipe coupled to the coupling, an adapter internal flow that is inserted into the nozzle body and connects the nozzle joint internal flow path and the nozzle internal flow path. An adapter having a channel.

This eliminates the need to directly connect the nozzle body and the coupling. Then, for example, when the nozzle body is separated from the nozzle joint in order to clean the inside of the nozzle body, the insertion state of the adapter into the nozzle body is released to separate the nozzle body from the nozzle joint. When the nozzle body is attached to the nozzle joint again after cleaning the inside of the nozzle body, the adapter is inserted into the nozzle body and the nozzle body is attached to the nozzle joint. Even if the work of attaching/detaching the nozzle joint to/from the nozzle body is repeatedly performed, the adapter may be damaged, but the coupling attached to the nozzle joint is not damaged. Therefore, there is no need to replace the coupling, and there is no need to replace the pipe connected to the coupling. Therefore, even if the adapter is damaged, only the adapter needs to be replaced, so that the labor of parts replacement work can be reduced.

In the water jet loom weft insertion nozzle, the nozzle main body has a needle insertion hole into which a needle for guiding a weft thread is inserted, and the extending direction of the needle insertion hole is an axial direction of the nozzle main body. It is preferable that the insertion direction of the adapter with respect to the cross direction intersects with the axial direction. According to this, for example, compared with the case where the insertion direction of the adapter with respect to the nozzle body is parallel to the axial direction of the nozzle body, the structure of the flow path in the nozzle can be simplified.

The weft insertion nozzle of the water jet room may include a plurality of nozzle units each having the nozzle body, the nozzle joint, the coupling, the pipe, and the adapter.

In each nozzle unit, when the nozzle body is separated from the nozzle joint in order to clean the inside of the nozzle body, for example, the adapter is pulled out from the nozzle body to separate the nozzle body from the nozzle joint. Then, the separation direction of the nozzle body with respect to the nozzle joint is not limited to the insertion direction of the adapter with respect to the nozzle body, and when separating the nozzle body from the nozzle joint, the nozzle bodies of the plurality of nozzle units interfere with each other. There is no end. Therefore, the attachment/detachment work for the nozzle joints of the nozzle bodies of the plurality of nozzle units can be independently performed.

In the above weft insertion nozzle of the water jet room, it is preferable that the two nozzle units are provided, and the insertion directions of the adapter with respect to the nozzle body are opposed to each other between the two nozzle units.

If the insertion direction of the adapter with respect to the nozzle body is opposed to each other between the two nozzle units, the two nozzle bodies interfere with each other when the nozzle body is moved in the insertion direction of the adapter. Therefore, by pulling out the adapter from the nozzle body before moving the nozzle body, the separation direction of the nozzle body from the nozzle joint is not limited to the insertion direction of the adapter into the nozzle body. When separating, the two nozzle bodies do not interfere with each other. Therefore, even if the inserting directions of the adapter with respect to the nozzle body are opposed to each other between the two nozzle units, the attachment/detachment work with respect to the nozzle joints of the nozzle bodies of the plurality of nozzle units can be independently performed.

According to the present invention, it is possible to reduce the time and effort required for component replacement work.

The perspective view which shows the weft insertion nozzle of the water jet room in embodiment. FIG. 3 is a side sectional view of the weft insertion nozzle. Sectional drawing along line 3-3 in FIG. The sectional side view which shows the state which separated the 2nd nozzle main body from the 2nd nozzle joint. FIG. 6 is a plan sectional view of a weft insertion nozzle according to another embodiment. The sectional side view of the weft insertion nozzle in another embodiment. Sectional drawing which shows the weft insertion nozzle in a prior art example.

Hereinafter, an embodiment in which a weft insertion nozzle of a water jet loom is embodied will be described with reference to FIGS.
As shown in FIG. 1, the weft insertion nozzle 10 of the water jet loom includes a first nozzle unit 11 and a second nozzle unit 12 as nozzle units. Therefore, the weft inserting nozzle 10 includes a plurality of nozzle units, and in the present embodiment, includes two nozzle units. The first nozzle unit 11 and the second nozzle unit 12 are arranged side by side in the moving direction of the warp W corresponding to the multicolor weft insertion.

The first nozzle unit 11 includes a first nozzle body 21 as a nozzle body, a first nozzle joint 31 as a nozzle joint, a first coupling 41 as a coupling, a first pipe 51 as a pipe, and a first pipe 51 as an adapter. 1 adapter 61, and. The second nozzle unit 12 includes a second nozzle body 22 as a nozzle body, a second nozzle joint 32 as a nozzle joint, a second coupling 42 as a coupling, a second pipe 52 as a pipe, and a second pipe as an adapter. 2 adapters 62 and.

Each of the first nozzle joint 31 and the second nozzle joint 32 is a block body. The first nozzle joint 31 is attached to the first nozzle adjuster 13a. The second nozzle joint 32 is attached to the second nozzle adjuster 13b. The first nozzle adjuster 13 a and the second nozzle adjuster 13 b are attached to the frame 14. The mounting angle of the first nozzle joint 31 with respect to the first nozzle adjuster 13a can be adjusted. The mounting angle of the second nozzle joint 32 with respect to the second nozzle adjuster 13b can be adjusted.

Next, the configuration of the first nozzle unit 11 will be described in detail.
As shown in FIG. 2, the first nozzle joint 31 has a first mounting surface 31 a to which the first nozzle body 21 is mounted, a first mounting hole 31 b to which the first coupling 41 is mounted, and a first adapter 61. The first adapter insertion hole 31c is formed.

The first mounting surface 31a is a flat surface that extends horizontally. The first mounting surface 31a is continuous with the side surface 311 of the first nozzle joint 31 where the first nozzle joint 31 and the second nozzle joint 32 face each other in the direction X1 in which the first nozzle joint 31 and the second nozzle joint 32 are arranged side by side. ing. The side surface 311 extends in the up-down direction Y1 which is a direction orthogonal to the juxtaposed direction X1.

The first nozzle joint 31 has an inclined surface 312 that is continuous with the side surface 311 opposite to the first mounting surface 31a. The inclined surface 312 inclines toward the second nozzle unit 12 side in the juxtaposed direction X1 as it moves away from the side surface 311 to the side opposite to the first mounting surface 31a. Further, the first nozzle joint 31 has an opening side surface 313 continuous to the side of the inclined surface 312 opposite to the side surface 311. The opening side surface 313 inclines toward the side opposite to the second nozzle unit 12 in the juxtaposed direction X1 as it moves away from the inclined surface 312. The first mounting hole 31b opens on the opening side surface 313. The first mounting hole 31b is a female screw hole extending in a state of being inclined with respect to the juxtaposed direction X1.

The first coupling 41 has a tubular shape. A male screw 41 a is formed on the outer peripheral surface of one end of the first coupling 41. Then, the male screw 41a is screwed into the first mounting hole 31b, so that the first coupling 41 is mounted in the first mounting hole 31b. The inside of the first coupling 41 communicates with the first mounting hole 31b.

One end of the first pipe 51 is connected to the first coupling 41 by welding, for example, in a state of being inserted in the other end of the first coupling 41. The first pipe 51 is prevented from interfering with the second nozzle joint 32 by extending so that one end thereof is inclined with respect to the juxtaposed direction X1. The other end of the first pipe 51 is connected to a pump (not shown), and water is supplied from the pump into the first pipe 51.

A seal member 311b is provided on the inner peripheral surface of the first mounting hole 31b to prevent water from leaking to the outside from between the inner peripheral surface of the first mounting hole 31b and the outer peripheral surface of the first coupling 41. There is.

The first nozzle joint 31 has a side surface 314 that is continuous with an edge portion of the first mounting surface 31a opposite to the side surface 311. The side surface 314 extends in the vertical direction Y1.
The first adapter insertion hole 31c extends from the side surface 315 located on the opposite side of the second nozzle joint 32 in the juxtaposed direction X1 to the juxtaposed direction X1 and penetrates to the side surface 314. Therefore, both ends of the first adapter insertion hole 31c are open to both side surfaces 314 and 315. An end portion of the inner peripheral surface of the first adapter insertion hole 31c on the side surface 315 side is a female screw hole 311c.

The first nozzle joint 31 has a first nozzle joint inner channel 31d which is a nozzle joint inner channel. The first nozzle joint internal passage 31d includes a first attachment hole 31b, a first communication passage 311d that communicates with the first attachment hole 31b, a second communication passage 312d that communicates with the first adapter insertion hole 31c, and a first attachment passage 31d. It is composed of an adapter insertion hole 31c. One end of the first communication passage 311d communicates with the first mounting hole 31b, and the other end of the first communication passage 311d communicates with the second communication passage 312d. The first communication passage 311d extends in the same direction as the first mounting hole 31b. Therefore, the first communication passage 311d extends in a state of being inclined with respect to the juxtaposed direction X1. The second communication passage 312d is formed in the first adapter insertion hole 31c so as to extend in the vertical direction Y1 from the lower surface 316, which is a surface of the first nozzle joint 31 located on the side opposite to the first adapter insertion hole 31c in the vertical direction Y1. It is a hole drilled toward. One end of the second communication passage 312d communicates with the first adapter insertion hole 31c. The other end of the second communication passage 312d is closed by a sealing plug 313d.

The first adapter 61 is a shaft member. The first adapter 61 is inserted into the first adapter insertion hole 31c from the opening on the side surface 315 side. The first adapter 61 is a cylindrical insertion portion 61b that is continuous with the shaft portion 61a arranged in the first adapter insertion hole 31c and that is continuous with the shaft portion 61a and that projects from the opening of the first adapter insertion hole 31c on the side surface 314 side. And have. A male screw 61c screwed into the female screw hole 311c is formed on the outer peripheral surface of the end portion of the shaft portion 61a opposite to the insertion portion 61b. The first adapter 61 is attached to the first nozzle joint 31 in a state of being inserted into the first adapter insertion hole 31c by screwing the male screw 61c into the female screw hole 311c. An annular recess 61d is formed in a portion of the outer peripheral surface of the shaft portion 61a facing one end of the second communication passage 312d.

The first adapter 61 has a first adapter internal flow passage 61e as an adapter internal flow passage. The first adapter internal flow path 61e includes a plurality of holes 61f penetrating in the recess 61d in a direction orthogonal to the axial direction of the first adapter 61, and an axial passage 61g extending in the axial direction of the first adapter 61. It is configured. One end of the in-shaft passage 61g opens at the tip of the insertion portion 61b, and the other end communicates with the plurality of holes 61f.

A seal member 312c is provided between a portion of the outer peripheral surface of the shaft portion 61a closer to the male screw 61c than the recess 61d and the inner peripheral surface of the first adapter insertion hole 31c. A seal member 313c is provided between the portion of the outer peripheral surface of the shaft portion 61a closer to the insertion portion 61b than the recess 61d and the inner peripheral surface of the first adapter insertion hole 31c.

The first nozzle body 21 is attached to the first attachment surface 31a with a plurality of (two in the present embodiment) bolts 15. The first nozzle body 21 has an insertion hole 21a into which the insertion portion 61b is inserted, a needle insertion hole 21b, and an internal flow path 21c that connects the insertion hole 21a and the needle insertion hole 21b. The internal flow channel 21c and the needle insertion hole 21b constitute a first in-nozzle flow channel 21d as a nozzle internal flow channel. Therefore, the first nozzle internal flow path 21d includes the needle insertion hole 21b.

The internal flow passage 21c connects the in-shaft passage 61g and the needle insertion hole 21b. Therefore, the internal flow passage 21c connects the first adapter internal flow passage 61e and the needle insertion hole 21b. A seal member 21s is provided between the inner peripheral surface of the insertion hole 21a and the outer peripheral surface of the insertion portion 61b.

The internal flow path 21c extends in the same direction as the insertion hole 21a. The needle insertion hole 21b extends in a direction orthogonal to the internal channel 21c. When the extending direction of the needle insertion hole 21 b is the axial direction of the first nozzle body 21, the insertion direction of the insertion portion 61 b of the first adapter 61 with respect to the insertion hole 21 a is orthogonal to the axial direction of the first nozzle body 21. There is.

Next, the configuration of the second nozzle unit 12 will be described in more detail.
The second nozzle joint 32 has a second mounting surface 32a on which the second nozzle body 22 is mounted, a second mounting hole 32b on which the second coupling 42 is mounted, and a second adapter insertion hole into which the second adapter 62 is inserted. 32c.

The second mounting surface 32a is a flat surface that extends horizontally. The second mounting surface 32a is at the same position (height) as the first mounting surface 31a in the vertical direction Y1. The second mounting surface 32a is continuous with the side surface 321 of the second nozzle joint 32 where the first nozzle joint 31 and the second nozzle joint 32 face each other in the juxtaposed direction X1. The side surface 321 extends in the vertical direction Y1.

The second mounting hole 32b is opened in the side surface 322 of the second nozzle joint 32 located on the side opposite to the first nozzle joint 31 in the juxtaposed direction X1. The second mounting hole 32b is a female screw hole extending in the juxtaposed direction X1.

The second coupling 42 has a tubular shape. A male screw 42a is formed on the outer peripheral surface of one end of the second coupling 42. And the 2nd coupling 42 is attached to the 2nd attachment hole 32b by screwing the male screw 42a into the 2nd attachment hole 32b. The inside of the second coupling 42 communicates with the second mounting hole 32b.

One end of the second pipe 52 is connected to the second coupling 42 by welding, for example, in a state of being inserted into the other end of the second coupling 42. The second pipe 52 extends on the side opposite to the first nozzle joint 31 in the arranging direction X1. The other end of the second pipe 52 is connected to a pump (not shown), and water is supplied from the pump into the second pipe 52.

A seal member 321b is provided on the inner peripheral surface of the second mounting hole 32b to prevent water from leaking to the outside from between the inner peripheral surface of the second mounting hole 32b and the outer peripheral surface of the second coupling 42. There is.

The second nozzle joint 32 has a side surface 323 that is continuous with the edge of the second mounting surface 32a opposite to the side surface 321. The side surface 323 extends in the vertical direction Y1. The second nozzle joint 32 has a side surface 324 located on the side opposite to the side surface 323 in the juxtaposed direction X1. The side surface 324 is located closer to the first nozzle joint 31 in the juxtaposed direction X1 than the side surface 322 where the second mounting hole 32b is open.

The second adapter insertion hole 32c extends from the side surface 323 in the juxtaposed direction X1 in the juxtaposed direction X1 and penetrates to the side surface 324. Therefore, both ends of the second adapter insertion hole 32c are open to both side surfaces 323 and 324. An end of the inner peripheral surface of the second adapter insertion hole 32c on the side surface 324 side is a female screw hole 321c.

The second nozzle joint 32 has a second nozzle joint inner channel 32d which is a nozzle joint inner channel. The second nozzle joint flow path 32d includes a second mounting hole 32b, a first communication path 321d that communicates with the second mounting hole 32b, a second communication path 322d that communicates with the second adapter insertion hole 32c, and a second communication path 322d. It is composed of an adapter insertion hole 32c. One end of the first communication passage 321d communicates with the second mounting hole 32b, and the other end of the first communication passage 321d communicates with the second communication passage 322d. The first communication passage 321d extends in the same direction as the second mounting hole 32b. Therefore, the first communication passage 321d extends in the juxtaposed direction X1. The second communication passage 322d is formed in the second adapter insertion hole 32c so as to extend in the vertical direction Y1 from the lower surface 325 that is a surface of the second nozzle joint 32 that is located on the side opposite to the second adapter insertion hole 32c in the vertical direction Y1. It is a hole drilled toward. One end of the second communication passage 322d communicates with the second adapter insertion hole 32c. The other end of the second communication passage 322d is closed by a sealing plug 323d.

The second adapter 62 is a shaft member. The second adapter 62 is inserted into the second adapter insertion hole 32c from the opening on the side surface 324 side. The second adapter 62 is a cylindrical insertion portion 62b that is continuous with the shaft portion 62a arranged in the second adapter insertion hole 32c and that projects from the opening of the second adapter insertion hole 32c on the side surface 323 side. And have. A male screw 62c screwed into the female screw hole 321c is formed on the outer peripheral surface of the end portion of the shaft portion 62a opposite to the insertion portion 62b. The second adapter 62 is attached to the second nozzle joint 32 in a state of being inserted into the second adapter insertion hole 32c by screwing the male screw 62c into the female screw hole 321c. An annular recess 62d is formed in a portion of the outer peripheral surface of the shaft portion 62a that faces one end of the second communication passage 322d.

The second adapter 62 has a second in-adapter flow path 62e as an in-adapter flow path. The second adapter internal flow path 62e is formed by a plurality of holes 62f penetrating in the recess 62d in a direction orthogonal to the axial direction of the second adapter 62 and an axial passage 62g extending in the axial direction of the second adapter 62. It is configured. One end of the in-shaft passage 62g opens at the tip of the insertion portion 62b, and the other end communicates with the plurality of holes 62f.

A seal member 322c is provided between a portion of the outer peripheral surface of the shaft portion 62a closer to the male screw 62c than the recess 62d and the inner peripheral surface of the second adapter insertion hole 32c. A seal member 323c is provided between a portion of the outer peripheral surface of the shaft portion 62a closer to the insertion portion 62b than the recess 62d and the inner peripheral surface of the second adapter insertion hole 32c.

The second nozzle body 22 is attached to the second attachment surface 32a by a plurality (two in the present embodiment) of bolts 16. The second nozzle body 22 has an insertion hole 22a into which the insertion portion 62b is inserted, a needle insertion hole 22b, and an internal passage 22c that connects the insertion hole 22a and the needle insertion hole 22b. The internal flow path 22c and the needle insertion hole 22b form a second nozzle flow path 22d as a nozzle flow path. Therefore, the second nozzle internal flow path 22d includes the needle insertion hole 22b.

The internal passage 22c connects the axial passage 62g and the needle insertion hole 22b. Therefore, the internal flow path 22c connects the second adapter internal flow path 62e and the needle insertion hole 22b. A seal member 22s is provided between the inner peripheral surface of the insertion hole 22a and the outer peripheral surface of the insertion portion 62b.

The internal channel 22c extends in the same direction as the insertion hole 22a. The needle insertion hole 22b extends in a direction orthogonal to the internal channel 22c. When the extending direction of the needle insertion hole 22b is the axial direction of the second nozzle body 22, the insertion direction of the insertion portion 62b of the second adapter 62 into the insertion hole 22a is orthogonal to the axial direction of the second nozzle body 22. There is. Between the first nozzle unit 11 and the second nozzle unit 12, the insertion direction of the insertion portion 61b of the first adapter 61 into the insertion hole 21a of the first nozzle body 21 and the second adapter 62 into the insertion hole 22a of the second nozzle body 22. And the insertion direction of the insertion portion 62b of each of them is opposite to each other.

Next, the internal structure of each needle insertion hole 21b, 22b will be described.
As shown in FIG. 3, the needles 17 for guiding the weft Y are housed inside the needle insertion holes 21b and 22b, respectively. The needle 17 has a yarn guide hole 17a for guiding the weft Y. The needle 17 has a flange 17b, a male screw portion 17c, a large diameter portion 17d, a small diameter portion 17e, a plurality of supporting portions 17f, and a needle portion 17g from one end to the other end. Each of the needles 17 is attached to each of the needle insertion holes 21b and 22b by screwing a male screw portion 17c into the female screw holes 211b and 221b formed in the needle insertion holes 21b and 22b. A seal member 17s is provided between each large diameter portion 17d and each needle insertion hole 21b, 22b.

The plurality of support portions 17f extend radially around the axis of the needle 17. A water supply hole 170 is provided between the plurality of adjacent support portions 17f. An annular water supply passage 171 is formed between the outer peripheral surface of each small diameter portion 17e and the inner peripheral surface of each needle insertion hole 21b, 22b. Each water supply passage 171 communicates with each internal flow passage 21c, 22c. An annular rectifying member 18 is housed around each needle portion 17g in each needle insertion hole 21b, 22b. The rectifying member 18 has radial fins 18a extending toward the outer peripheral surface of the needle portion 17g.

Further, a tubular cover member 19 is housed in each of the needle insertion holes 21b and 22b on the downstream side of the flow regulating member 18 in the water flow direction. The tip portion of the needle portion 17g passes inside the cover member 19. The inner diameter of the inner peripheral surface of the cover member 19 is reduced toward the downstream side. An annular nozzle hole 19a is formed between the inner peripheral surface of the cover member 19 and the outer peripheral surface of the needle portion 17g.

The water supplied to the first pipe 51 passes from the inside of the first pipe 51 through the inside of the first coupling 41 to the first attachment hole 31b, the first communication passage 311d, the first communication passage 311d, It flows through the second communication path 312d and the first adapter insertion hole 31c. The water flowing out into the first adapter insertion hole 31c is passed through the plurality of holes 61f forming the first adapter internal passage 61e and the axial passage 61g to the internal passage 21c forming the first nozzle internal passage 21d. It flows out and is supplied to the water supply passage 171 of the needle insertion hole 21b through the internal flow passage 21c. Therefore, the first adapter internal channel 61e connects the first nozzle joint internal channel 31d and the first nozzle internal channel 21d. Then, the water supplied to the water supply path 171 passes through the plurality of water supply holes 170, is rectified by the plurality of fins 18a of the rectifying member 18, and then is squeezed by the nozzle holes 19a to accelerate and accelerate with the weft Y and the first. It is ejected from the nozzle body 21. The injected weft yarn Y flies in the warp yarn opening W1. As a result, the weft Y is inserted into the warp opening W1.

The water supplied to the second pipe 52 passes from the inside of the second pipe 52 through the inside of the second coupling 42 to the second mounting hole 32b, the first communication passage 321d, and the second communication hole 321d that form the second nozzle joint internal passage 32d. It flows through the second communication passage 322d and the second adapter insertion hole 32c. The water flowing out into the second adapter insertion hole 32c is passed through the plurality of holes 62f forming the second adapter internal passage 62e and the axial passage 62g to the internal passage 22c forming the second nozzle internal passage 22d. It flows out and is supplied to the water supply passage 171 of the needle insertion hole 22b via the internal flow passage 22c. Therefore, the second adapter internal passage 62e connects the second nozzle joint internal passage 32d and the second nozzle internal passage 22d. Then, the water supplied to the water supply passage 171 passes through the plurality of water supply holes 170, is rectified by the plurality of fins 18a of the rectifying member 18, and then is squeezed by the nozzle holes 19a to accelerate while accelerating to the second weft Y. It is ejected from the nozzle body 22. The injected weft yarn Y flies in the warp yarn opening W1. As a result, the weft Y is inserted into the warp opening W1. In this way, multi-color weft insertion is performed by the weft insertion nozzle 10 of the present embodiment.

Next, the operation of this embodiment will be described.
As shown in FIG. 4, for example, when foreign matter has accumulated inside the second nozzle body 22, the second nozzle body 22 is separated from the second nozzle joint 32, and the inside of the second nozzle body 22 is cleaned. When separating the second nozzle body 22 from the second nozzle joint 32, first, the plurality of bolts 16 are removed. Subsequently, the male screw 62c is screwed back into the female screw hole 321c, and the second adapter 62 is pulled out from the second adapter insertion hole 32c. As a result, the insertion portion 62b of the second adapter 62 is pulled out from the insertion hole 22a, the insertion state of the insertion portion 62b into the insertion hole 22a is released, and the second nozzle body 22 can be separated from the second nozzle joint 32. Become.

At this time, the separation direction of the second nozzle body 22 from the second nozzle joint 32 is not limited to the insertion direction of the second nozzle body 22 into the insertion hole 22a of the insertion portion 62b of the second adapter 62. Accordingly, when the second nozzle body 22 is separated from the second nozzle joint 32, the second nozzle body 22 does not interfere with the first nozzle body 21.

Then, after the second nozzle body 22 is cleaned, when the second nozzle body 22 is attached to the second nozzle joint 32 again, the second nozzle body 22 is arranged on the second attachment surface 32 a, and the second adapter 62 is attached. The second adapter 62 is inserted into the second adapter insertion hole 32c so that the insertion portion 62b is inserted into the insertion hole 22a. Then, the second nozzle body 22 is attached to the second nozzle joint 32 by attaching the second nozzle body 22 to the second attachment surface 32 a with the plurality of bolts 16.

In the above embodiment, the following effects can be obtained.
(1) The weft inserting nozzle 10 is a first adapter that is inserted into the first nozzle main body 21 and has a first adapter internal passage 61e that connects the first nozzle joint internal passage 31d and the first nozzle internal passage 21d. 61 is provided. In addition, the weft inserting nozzle 10 is inserted into the second nozzle body 22, and has a second adapter 62 having a second adapter internal passage 62e that connects the second nozzle joint internal passage 32d and the second nozzle internal passage 22d. Equipped with. According to this, it is not necessary to directly connect the first nozzle body 21 and the first coupling 41, and it is not necessary to directly connect the second nozzle body 22 and the second coupling 42. Even if the attachment/detachment work for the first nozzle joint 31 in the first nozzle body 21 and the attachment/detachment work for the second nozzle joint 32 in the second nozzle body 22 are repeatedly performed, the first adapter 61 and the second adapter 62 are attached. Although there is a risk of scratches, the first coupling 41 and the second coupling 42 are not scratched. Therefore, there is no need to replace the first coupling 41 and the second coupling 42, and the first pipe 51 and the second pipe 52 connected to the first coupling 41 and the second coupling 42 are not required. There is no need to replace it. Therefore, even if the first adapter 61 and the second adapter 62 are damaged, only the first adapter 61 and the second adapter 62 need to be replaced, so that the labor of the parts replacement work can be suppressed.

(2) For example, the insertion direction of the first adapter 61 with respect to the first nozzle body 21 is parallel to the axial direction of the first nozzle body 21, or the insertion direction of the second adapter 62 with respect to the second nozzle body 22 is the second nozzle. Consider a case where the body 22 is parallel to the axial direction. In this case, the internal flow path 21c of the first nozzle body 21 that connects the first adapter internal flow path 61e and the needle insertion hole 21b is set to the insertion direction of the first adapter 61 with respect to the first nozzle main body 21 and the first nozzle main body 21. It must be formed so as to extend in a direction intersecting with the axial direction. Similarly, the internal flow path 22c of the second nozzle body 22 that connects the second adapter internal flow path 62e and the needle insertion hole 22b is defined by the insertion direction of the second adapter 62 with respect to the second nozzle main body 22 and the second nozzle main body 22. It must be formed so as to extend in a direction intersecting with the axial direction. Therefore, the structures of the first in-nozzle passage 21d of the first nozzle body 21 and the second in-nozzle passage 22d of the second nozzle body 22 are complicated.

Therefore, in the present embodiment, the insertion direction of the first adapter 61 with respect to the first nozzle body 21 is orthogonal to the axial direction of the first nozzle body 21, and the insertion direction of the second adapter 62 with respect to the second nozzle body 22 is the first. It is orthogonal to the axial direction of the two-nozzle body 22. According to this, the internal flow path 21c of the first nozzle body 21 that connects the first adapter internal flow path 61e and the needle insertion hole 21b is formed in the same direction as the insertion direction of the first adapter 61 with respect to the first nozzle body 21. it can. Furthermore, the internal flow path 22c of the second nozzle body 22 that connects the second adapter internal flow path 62e and the needle insertion hole 22b can be formed in the same direction as the insertion direction of the second adapter 62 into the second nozzle main body 22. Therefore, it is possible to simplify the structures of the first in-nozzle channel 21d of the first nozzle body 21 and the second in-nozzle channel 22d of the second nozzle body 22.

(3) The weft inserting nozzle 10 includes a first nozzle unit 11 and a second nozzle unit 12. In the first nozzle unit 11 and the second nozzle unit 12, when the second nozzle body 22 is separated from the second nozzle joint 32 to clean the inside of the second nozzle body 22, the second adapter 62 is removed. The second nozzle body 22 is separated from the second nozzle joint 32 by pulling it out from the two-nozzle body 22. Then, the separation direction of the second nozzle body 22 from the second nozzle joint 32 is not limited to the insertion direction of the second adapter 62 into the second nozzle body 22, and the second nozzle body 22 is separated from the second nozzle joint 32. At the time of separation, it does not interfere with the first nozzle body 21 of the first nozzle unit 11. Therefore, the attachment/detachment work for the first nozzle joint 31 in the first nozzle body 21 and the attachment/detachment work for the second nozzle joint 32 in the second nozzle body 22 can be independently performed.

(4) Between the first nozzle unit 11 and the second nozzle unit 12, the insertion direction of the first adapter 61 into the first nozzle body 21 and the insertion direction of the second adapter 62 into the second nozzle body 22 are opposed to each other. Then, for example, when the second nozzle body 22 is moved in the insertion direction of the second adapter 62, the second nozzle body 22 interferes with the first nozzle body 21. Therefore, by pulling out the second adapter 62 from the second nozzle body 22 before moving the second nozzle body 22, the direction of separation of the second nozzle body 22 from the second nozzle joint 32 is the second adapter 62. It is no longer limited to the insertion direction of the second nozzle body 22 in. Therefore, when the second nozzle body 22 is separated from the second nozzle joint 32, the second nozzle body 22 does not interfere with the first nozzle body 21. Therefore, the insertion direction of the first adapter 61 with respect to the first nozzle body 21 and the insertion direction of the second adapter 62 with respect to the second nozzle body 22 are opposed to each other between the first nozzle unit 11 and the second nozzle unit 12. Also, the attachment/detachment work with respect to the first nozzle joint 31 in the first nozzle body 21 can be independently performed. Similarly, the attachment/detachment work for the second nozzle joint 32 in the second nozzle body 22 can be independently performed.

The above embodiment may be modified as follows.
As shown in FIG. 5, the insertion direction of the first adapter 61 with respect to the first nozzle body 21 is parallel to the axial direction of the first nozzle body 21, and the insertion direction of the second adapter 62 with respect to the second nozzle body 22 is also: It may be parallel to the axial direction of the second nozzle body 22.

The internal flow passage 21c of the first nozzle body 21 that connects the first adapter internal flow passage 61e and the needle insertion hole 21b is arranged in the insertion direction of the first adapter 61 with respect to the first nozzle main body 21 and in the axial direction of the first nozzle main body 21. It extends in a direction intersecting with each other. The internal flow passage 22c of the second nozzle body 22 that connects the second adapter internal flow passage 62e and the needle insertion hole 22b is arranged in the insertion direction of the second adapter 62 with respect to the second nozzle main body 22 and in the axial direction of the second nozzle main body 22. It extends in a direction intersecting with each other.

In the embodiment shown in FIG. 5, for example, by removing the plurality of bolts 16 and moving the second nozzle body 22 in the insertion direction of the second adapter 62 with respect to the second nozzle body 22, the second nozzle body 22 can be moved to the first nozzle body 22. The second nozzle body 22 can be separated from the second nozzle joint 32 without interfering with the 1-nozzle body 21. Therefore, it is not necessary to pull out the second adapter 62 from the second nozzle joint 32 when separating the second nozzle body 22 from the second nozzle joint 32.

As shown in FIG. 6, the insertion direction of the first adapter 61 with respect to the first nozzle body 21 may be the same as the vertical direction Y1, and the insertion direction of the second adapter 62 with respect to the second nozzle body 22 is also vertical. It may match the direction Y1.

The first adapter 61 is inserted into the first nozzle body 21 so as to penetrate the first nozzle body 21 in the up-down direction Y1, and the tip end portion is inserted into the second communication passage 312d. The in-shaft passage 61g communicates with the second communication passage 312d. The plurality of holes 61f communicate with the internal flow path 21c. A male screw 61A is formed on the outer peripheral surface of the tip portion of the first adapter 61. A female screw 313e with which the male screw 61A is screwed is formed on the inner peripheral surface of the second communication passage 312d. The first adapter 61 is inserted into the first nozzle body 21, and the male screw 61A at the tip end is screwed into the female screw 313e, thereby attaching the first nozzle body 21 to the first nozzle joint 31. That is, in the embodiment shown in FIG. 6, the first adapter 61 plays a role of a mounting member for mounting the first nozzle body 21 to the first nozzle joint 31.

Similarly, the second adapter 62 is inserted into the second nozzle body 22 so as to penetrate the second nozzle body 22 in the up-down direction Y1, and the tip end portion is inserted into the second communication passage 322d. The shaft passage 62g communicates with the second communication passage 322d. The plurality of holes 62f communicate with the internal flow channel 22c. A male screw 62A is formed on the outer peripheral surface of the tip portion of the second adapter 62. A female screw 323e with which the male screw 62A is screwed is formed on the inner peripheral surface of the second communication passage 322d. The second adapter 62 is attached to the second nozzle joint 32 by being inserted into the second nozzle body 22 and having the male screw 62A at the tip end screwed into the female screw 323e. That is, in the embodiment shown in FIG. 6, the second adapter 62 plays a role of a mounting member for mounting the second nozzle body 22 to the second nozzle joint 32.

In the embodiment, the weft inserting nozzle 10 may be configured to include only one nozzle unit, or may be configured to include three or more nozzle units.

DESCRIPTION OF SYMBOLS 10... Weft insertion nozzle, 11... 1st nozzle unit as a nozzle unit, 12... 2nd nozzle unit as a nozzle unit, 17... Needle, 21... 1st nozzle body as a nozzle body, 21b, 22b... Needle insertion hole , 21d... a first nozzle flow path as a nozzle flow path, 22... a second nozzle body as a nozzle body, 22d... a second nozzle flow path as a nozzle flow path, 31... a first nozzle joint Nozzle joint, 31d... 1st nozzle joint internal flow path which is a nozzle joint internal flow path, 32... 2nd nozzle joint as a nozzle joint, 32d... 2nd nozzle joint internal flow path which is a nozzle joint internal flow path, 41... First coupling as coupling, 42... Second coupling as coupling, 51... First pipe as pipe, 52... Second pipe as pipe, 61... First adapter as adapter, 61e... Adapter 1st adapter internal flow path as an internal flow path, 62... 2nd adapter as an adapter, 62e... 2nd adapter internal flow path as an adapter internal flow path.

Claims (3)

A needle insertion hole extending in the axial direction of the nozzle, an insertion hole extending in a direction intersecting the axial direction of the nozzle, a nozzle body having an internal flow path that communicates the needle insertion hole and the insertion hole ,
A nozzle joint having the nozzle main body attached and having a flow path inside the nozzle joint,
A coupling which is attached to the nozzle joint and which communicates with the flow path inside the nozzle joint,
A pipe coupled to the coupling,
A shaft portion arranged in the adapter insertion hole of the nozzle joint, an insertion portion which continuously protrudes from the opening of the adapter insertion hole in the shaft portion is inserted into the insertion hole of the nozzle body, the nozzle joint A weft insertion nozzle for a water jet loom, comprising: an adapter having an internal flow passage and an adapter having an internal flow passage connected to the internal flow passage . The weft insertion nozzle for a water jet room according to claim 1, further comprising a plurality of nozzle units each having the nozzle body, the nozzle joint, the coupling, the pipe, and the adapter. Two nozzle units are provided,
The weft insertion nozzle of the water jet loom according to claim 2 , wherein insertion directions of the adapter with respect to the nozzle body are opposed to each other between the two nozzle units.

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