KR830002725B1 - Implantation apparatus in jet room - Google Patents

Abstract

No content.

Description

Implantation apparatus in jet room

1 is a schematic view showing the entire enumeration apparatus.

2 is a cross-sectional front view of a conversion valve supplying a fluid.

3 is a sectional view taken along line A-A in FIG.

4 is a sectional view taken along line B-B in FIG.

5 is a sectional front view of the conversion valve in which the fluid supply is stopped.

6 is a cross-sectional view taken along line C-C of FIG.

7 is a sectional view taken along the line D-D in FIG.

8 is a diagram showing changes in fluid pressure in the main nozzle according to the present invention.

9 is a diagram showing changes in fluid pressure in a conventional main nozzle.

FIG. 10 is a cross-sectional front view of the conversion valve of another embodiment, showing a weft insertion time. FIG.

FIG. 11 is an E-E cross section and an F-F cross section of FIG. 10, respectively.

FIG. 13 shows that supply of pressure fluid is stopped and discharged, similar to that of FIG.

14 and 15 are G-G and H-H cross-sectional views of FIG. 13, respectively.

The present invention relates to an entrapped apparatus in a jet room.

In the jet room, as is well known, a pressure fluid is injected from a fluid injection nozzle installed next to a base, and the weft is infiltrated into the guide passage provided on the sleigh by the fluid, and the inlet is made. The injection of the fluid in the main nozzle is controlled by the injection valve connected to the pressure fluid source separately installed. As shown in the fluid injection state of the main nozzle, as shown in FIG. 9, when the conversion valve communicates with the flow path during the upwelling time, the time required to reach a predetermined pressure after a delay is slightly delayed in the main nozzle. After this elapses, fluid spraying is performed. When the weft insertion time elapses, the fluid supply is stopped from the pressure fluid source because the changeover valve closes the flow path, but the pressure drop slows down because the pressure fluid is narrowed in the main nozzle part from the changeover valve to the main nozzle. It takes a long time t until the fluid emission from the nozzle is substantially stopped. Therefore, even after the end of gastric injection, fluid is injected from the main nozzle and strong pressure is generated on the weft yarn which is stopped by the braking device, resulting in dissolution of the weft yarn, and moreover, a serious defect such as cutting of the weft yarn is caused.

According to the present invention, the supply of pressure fluid is stopped by the switching valve, and at the same time, the pressure fluid between the switching valve and the main nozzle is actively discharged, thereby reducing the fluid pressure in the main nozzle and not delaying the stop of fluid injection from the nozzle. This prevents the effect on the weft yarn which stops after entering the stomach.

EMBODIMENT OF THE INVENTION Hereinafter, it demonstrates in detail based on Example 1 which shows this invention. FIG. 1 is a schematic diagram of the indentation apparatus, in which a guide member 3 which forms a guide passage for the body 2, a fluid and a weft thread on the sleigh 1, and an auxiliary nozzle 4 having an auxiliary fluid jet port directed to the guide passage of the guide member 3 are respectively installed. have. In addition, a main nozzle 5 directed to the guide passage is fixedly installed at the end of the slay 1, and the main nozzle 5 is connected to a pressure fluid source (not shown) via a changeover valve 6. Meanwhile, the weft yarn 9 drawn out by the measuring device 8 in the fixed weft supply unit 7 is temporarily stored in the weft storage device 10 and then inserted into the main nozzle 5 through the braking device 11. Therefore, when the communication valve communicates with the pressure fluid source, the pressure fluid is injected from the main nozzle 5, and the weft yarn 9 is conveyed by this fluid, and the entrainment is performed. When the filling is completed, the changeover valve 6 closes the passage, and the braking device 11 brakes the weft and body stroke is performed. Furthermore, the above configuration shows an embodiment of the indentation apparatus, for example, the main nozzle 5 may be fixed to the base, and the guide passage by the guide member 3 may be configured by deforming the body, and is half as shown in FIG. The auxiliary nozzle 4 can be eliminated at the same time as the cylindrical passage is formed by the substantially circular guide member rather than the spherical passage.

2 to 7 show the structure of the conversion valve of Embodiment 1 of the present invention. The housing 12 fixed to the loom has a cylindrical space therein, in which the rotating body 14 rotated via the driven gear 13 is attenuated. As shown in FIG. 2, the housing 12 is provided with an outlet 15 in the upper center, and an inlet 16 and an outlet 17 in the lower part. The outlet 15 is connected to the main nozzle 5 via a pipe 18 as shown in FIG. 1, the inlet 16 is connected to a pressure fluid source (not shown), and the outlet 17 is open. The rotating body 14 is contracted by metals 21 and 22 in the bearing parts 19 and 20 fixed to both ends thereof. In addition, labyrinths 23 and 24 are formed on both sides of the rotating body 14 to seal the inner space of the housing 12. In this closed space, the rotating body 14 has a small diameter portion 25 at its center portion, and a space 26 is always formed in communication with the outlet 15 around it. In FIG. 2, the right large diameter portion 27 of the small diameter portion 25 is rotated to be in close contact with the inner wall portion of the housing 12, and a part of which corresponds to the time required for indentation, as can be seen from the AA section view of FIG. The space 28 is formed. The space 28 communicates with the space 26 corresponding to the outlet 15, and is configured to communicate with the inlet 16 at a timing at the time of entering by the rotation of the arrow in FIG. In addition, in FIG. 2, the left large diameter portion 29 of the small diameter portion 25 is rotated almost in close contact with the inner wall portion of the housing 12, similar to the large diameter portion 27, and a part thereof has a fan shape as shown in FIG. The space 30 is formed. The space 30 communicates with the space 26 corresponding to the outlet 15, and is configured to communicate with the outlet 17 at the end of the entrainment by rotation. In addition. The time in which the space 30 communicates with the outlet 17 is set according to the capacity of the pressure fluid existing between the switching valve and the main nozzle 5, and the positions for forming the space 30 are 3rd, 4th and 6th degrees. As shown in FIG. 7, the space 28 is not in communication while the space 28 is in communication with the inlet 16, and the space 28 and the inlet 16 are not in communication while the space 30 is in communication with the outlet 17.

Referring to the operation of the conversion valve according to the present invention formed as described above, the rotary body 14 is rotated at the same time along the rotation of the loom, and when the upper inlet time reaches the space 28 on the large diameter 27 side in communication with the inlet 16 As such, the fluid supplied from the pressure fluid source reaches main nozzle 5 through inlet 16, space 28, space 26, outlet 15 and pipe 18 where the fluid is injected. Fluid injection is performed while the space 28 is in communication with the inlet 16, during which the weft insertion time shown in FIG. At the same time, the communication between the space 28 and the inlet 16 is interrupted and the supply of pressure fluid is stopped, but the space 30 on the large diameter 29 side communicates with the outlet 17 as shown in FIG. . As a result, the pressure fluid present in the main nozzle 5, the pipe 18, the outlet 15, and the space 26 is immediately discharged through the outlet 17, and the pressure in the main nozzle 5 is rapidly lowered. At the same time, the fluid injection in the main nozzle 5 stops, and the pressure fluid cannot act on the weft yarn 9 stopped by the braking device 11.

Moreover, the pressure fluid discharged through the outlet 17 may be discharged to the atmosphere as it is, but the pressure fluid discharged from the outlet 17 to the braking device 11 or the weft tensor (not shown) or the cutter (not shown) is passed through the pipe. The lower surface can be used to remove the wind surface attached to these devices.

10 to 15 show a conversion valve structure of a separate embodiment embodying the same invention. The housing 31 fixed to the loom has a cylindrical space 38 formed by two discs 37, 37 'each sealed with a seal member 36 therein, and a driven gear (not shown) is inserted into the cylindrical space 38. The rotating body 32 that is rotated as a medium is shielded.

In the housing 31, an outlet 33 and an inlet 34 and an outlet 35 are installed in the lower part of the center, respectively, as shown in FIG. The outlet 33 is connected to the main nozzle 5 via a pipe 18, the inlet 34 is connected to a pressure fluid source (not shown), and the outlet 35 is open. The disc 37 is provided with an input hole 39, and the disc 37 'is provided with an exhaust hole 40. The seal members 36 and 36 'are provided with spaces 41 and 42 which always communicate with each other in correspondence with the input port 34 and the discharge port 35, respectively. The disks 37 and 37 'are rotated in close contact with the inner wall of the housing 31, and the input hole 39 formed in the disk 37 has an angle θ corresponding to the time required for indentation, as can be seen in the EE section of FIG. _Has a size of ₁ . The input hole 39 is configured to communicate with the space 41 in the timing shown at the time of entering by the rotation in the direction of the arrow of the disc 37 in FIG. In addition, the exhaust hole 40 formed in the disc 37 'is configured to communicate with the space 42 at the time of entering the entrance by rotation of the rotating body as shown in the HH cross-sectional view of FIG.

In addition, the time that the exhaust hole 40 and the space 42 communicate is set by the capacity of the pressure fluid existing during the time from the changeover valve to the main nozzle 5, and the position of forming the exhaust hole 40 is shown in FIGS. As can be seen in FIGS. 14 and 15, the input hole 39 is in a non-communication state while communicating with the space 41, and the input hole 39 and the space 41 are not in communication while the exhaust hole 40 is in communication with the space 42. It is.

Referring to the action of the conversion valve of the separate embodiment set as described above, the rotating body 32 is rotated at the same time along the rotation of the loom, and when reaching the up-entry time, because the input hole 39 is in communication with the space 41, the pressure fluid supply source The fluid supplied at reaches the main nozzle 5 through the inlet 34, the space 41, the input hole 39, the space 38, the outlet 38 and the pipe 18, where the fluid is injected. The fluid injection is performed while the input hole 39 is in communication with the space 41, and this time is the weft insertion time shown in FIG. When the set weft insertion time elapses, the communication between the input hole 39 and the space 41 is cut off at the same time, and the supply of the pressure fluid is stopped. At this time, the exhaust hole 40 communicates with the space 42 as shown in FIG. Therefore, the pressure fluid existing in the main nozzle 5, the pipe 18, the outlet 33, and the space 38 is immediately discharged through the outlet 35, and the pressure in the main nozzle 5 is rapidly lowered. At the same time, the fluid injection in the main nozzle 5 stops, and the pressure fluid cannot act on the weft yarn 9 stopped by the braking device 11. In addition, although the pressure fluid discharged from the discharge port 35 may be discharged to the atmosphere as it is, it can be used to remove the wind surface as in Example 1 above.

In any of the above embodiments, the pressure fluid outlet is installed in the conversion valve itself. However, if the pressure fluid outlet is installed in the spirit of the present invention, the outlet must be installed in the conversion valve itself. good. Moreover, the opening and closing of this outlet may be mechanical or electrical. For example, in the case of a mechanical type, the movement of the loom and the cam may be linked to open the outlet after inserting the weft, and in the case of the electric type, the solenoid valve may be opened and closed.

As described above, when the fluid supply from the pressure fluid supply source is stopped, the present invention actively discharges the pressure fluid existing from the switching valve to the main nozzle, thereby rapidly decreasing the fluid pressure in the main nozzle. At the same time as the stop, the fluid injection from the main nozzle can be stopped, and as a result of the pressure fluid not acting on the weft existing in the main nozzle after braking by the braking device, Can be prevented.

Furthermore, the discharged pressure fluid can be guided through a pipe from the outlet to a brake, a weft tensor, or a cutter, and can be used to remove the wind surface attached to these devices.

Claims (1)

A plurality of guide members are installed on the slay to form guide passages for the fluid and weft yarns, and install the fluid injection main nozzles toward the guide passages, which spray the fluid at the inlet and stop the fluid spray after the inlet. In a jet room connected to a changeover valve, the pressure fluid from the changeover valve to the main nozzle is actively discharged while the fluid is injected from the main nozzle at the time of entrainment and the injection of the fluid is stopped after the time required for entrainment has elapsed. The entrainment apparatus in a jet room, characterized in that to rapidly reduce the fluid pressure in the main nozzle.

Images