JPS5874463A - Suction and exhaust device of yarn winding machine - Google Patents

Abstract

PURPOSE:To reduce consumption power by coupling a plurality of blowers of yarn winding machines by a coupling pipe and stopping some blowers when the blowers have some scope because there is a few breaks in a yarn. CONSTITUTION:In case where each yarn winding machine is used with respective blowers thereof coupled to one another, a shutter 6 on suction side is opened, and each blower is coupled to a coupling pipe 3. When a push-botton switch PB3 for opening a suction shutter is pushed, the suction shutter is opened to its full width to couple the blowers. If the yarn breaks decrease in number, and the blowers have much energy in reserve, the load of the blower motor is electrically detected, or the static pressure and the dynamic pressure of air flow in a suction pipe 4 or a waste yarn chamber 31 are detected to stop some blowers by the electric signal.

Description

DETAILED DESCRIPTION OF THE INVENTION When a plurality of winding machines each consisting of a large number of unit winding devices Vt each having an intake pipe are installed, the present invention provides an air intake blower that can The present invention relates to a suction and exhaust device for a yarn winding machine which adjusts the suction volume of the winding machine.

In an automatic winder, one blower is used for each winding machine.
The suction power of this blower can be used to suck out the yarn end with a suction tube and tie the yarn when the yarn is broken during winding or when the yarn is replaced. The total amount is designed so that each unit winding device can tie the yarn even if the yarn is tied. Therefore, depending on the type and quality of the yarn, the number of yarn breaks may be reduced and the blower capacity may be freed.

In the present invention, the blowers of a plurality of thread winding machines are connected by a connecting pipe, and when the number of yarn breaks is small and there is room for the blowers, some of the blowers are stopped.

Embodiments of the device of the present invention will be described with reference to the drawings.

In Figure 1, fl) is the unit winding device & i2) is the prime mover section where the blower is installed, (3) is the connecting pipe that connects the blowers of each winding machine, and (4) is the intake pipe of the needle thread machine. show.

FIG. 2 shows a unit winding device, and the unit winding device winds up the yarn threads of the tube yarn a at the supply position using a balloon breaker (1
11), yarn filler (112), tension device (11, running yarn detector (114), brazing device (115)
), the thread is wound up through the grooved traversing drive drum (116) and onto the package (117) that rotates in contact with the drum (116), and when the yarn breaks midway during winding (what is mid-break? The operating cam (which is activated by engaging the driving shaft) is actuated by the switching operation of the clutch in response to a signal from the traveling yarn detector (114) which detects this condition (referring to the state in which the yarn to be wound up is not traveling in the yarn running path). 118) as a driving source, and if the middle breakage is a cut of the thread, the thread on the package side, that is, the needle thread, is moved to the needle thread suction tube (118) as the drive source.
20), take the supply side thread, that is, the bobbin thread, to the bobbin thread suction tube (12).
After suctioning with 1) and tying the yarn, start the winding operation again, and also use the operation cam (1) when the mid-break occurs when the supply tube yarn runs out.
The thread emptied by the rotation of step 18) is discharged from the supply position and replaced with the preparation thread, and the opening thread and needle thread of this new thread are carried to the knotter, tied, and winding is restarted. In addition, when the winding progresses and the package (/N7) reaches a predetermined length, number, or diameter, that is, when the package is full, the winding operation is automatically stopped.

In FIG. 6, (5) is a muffler formed above the driving part, (6) is an intake side shutter device installed between the muffler and the connecting pipe (3), (7) is an exhaust side shutter device W, (8) is an exhaust pipe. (9) is the intake pipe that connects to the connecting pipe, 00) is the shutter that electrically operates the hydraulic cylinder or electric cylinder (III), and the lever (
14, rotate the shutter QO) via the shaft 03) to close the intake port I.

(21) is electrically operated by the hydraulic cylinder or electric cylinder of the exhaust side shutter device.
The shutter 04) is rotated via C) to close the exhaust holes C. (To) Blower 1O1) is a waste thread chamber that stores thread waste in the intake air, and (3z is an air filter).

FIG. 5 shows a motor circuit for four motors, of which only one blower motor M1' is started and stopped when the other five motors are loaded. Note that the blower motor is originally operated with star-delta startup, but to simplify the circuit diagram, it was changed to direct startup.

Fl is a short-circuit protection fuse for the blower motor circuit 1M1/engine M1', MO1; MO1' is an electromagnetic switch, and ThR is a heater for a thermal relay for overload burnout protection. T
hR' is a thermal relay heater that closes when the load current of the blower motor exceeds the set value to start the resting blower motor, and stops it when the load current falls below the set value. Start and stop.

F2 is the short circuit protection fuse for the exhaust shutter circuit, 0RF
1 is an electromagnetic relay contact for opening the shutter, and QRR1 is an electromagnetic relay contact for opening the shutter.

CP is a circuit protector that protects the exhaust shutter motor and intake shutter motor from overload burnout.

M2 is a motor for opening and closing the exhaust shutter, and M3 is a motor for opening and closing the intake shutter.

F6 is the short circuit protection fuse for the intake shutter circuit, OR1
4 is an electromagnetic relay contact for opening the intake shutter, and 0RR2 is an electromagnetic relay contact for opening.

Figure 6 shows the operating circuit of the machine that starts and stops the blower motors depending on the load condition a of the three blower motors, and the thermal relay contact ThR' which turns ON and OFF depending on the load condition of the blower mortar. are connected to both ends of SWl. (Dot chain line) F4 is the short-circuit protection fuse for the operating circuit, PBl is the push button switch that starts the machine, PB2
is a push button switch that stops.

ThR is a thermal relay contact that stops the machine when the blower motor becomes overloaded to prevent motor burnout.

OR1 is a start/stop relay, swl is a switch that is turned off when the blower motor is stopped in advance,
MO1' is an electromagnetic switch for the blower motor.

ThR' is displayed several times on the other three machines, and the blower
This is a contact that closes when the motor exceeds the set load and opens when the motor falls below the set load.

LSF1 is a limit switch on the forward side of the exhaust shutter, that is, the actuator of the limit switch is pressed when the shutter is fully opened, and LSR1 is a limit switch on the backward side, and the actuator of the limit switch is pressed when the shutter is fully closed.

0RF1 is an electromagnetic relay that operates when the exhaust shutter is opened, and 0RR1 is an electromagnetic relay that operates when the shutter is closed.

OR8 is an electromagnetic relay that operates when the exhaust shutter is fully opened, and operates other circuits via the auxiliary relay OR2 after the exhaust shutter is fully opened. That is, it is used to operate the winding child knit.

LSIF2 is a limit switch on the forward side of the intake shutter, and the actuator is pressed when the shutter is fully opened. PB3 is a push button switch that is pressed to fully open the intake shutter, and 0RIP2 is an electromagnetic relay for opening the intake shutter. LSR2 has a limit switch on the backward side of the intake shutter, and the actuator is pressed when the shutter is fully opened.

PB4 is a push button switch that is pressed to fully close the intake shutter, and 0RR2 is an electromagnetic relay for closing the intake shutter.

Next, I will talk about the effect.

When each winding machine is operated independently by its respective blower, each suction side shutter device is closed and the exhaust side shutter device is opened and operated.

In the electrical circuit shown in Figure 6, each winding machine has its own blower.
When operating independently, press the intake shutter closing push button switch PB4, fully open the intake shutter,
Close SWl to make the blower motor ready for operation, and insert the start push button switch PB1. The air from the intake pipe (4) passes through the waste thread chamber 6υ and two filters, enters the blower (to), and enters the room from the exhaust side via the muffler (5), the exhaust side shutter system M (71, and the exhaust pipe (8)). When the blowers are connected and used, the suction side shutter device (6) of each winding machine is opened and each blower is connected to the connecting pipe G. That is, the suction side shutter device (6) is connected. It operates to open and connect the waste thread chamber (2) to the connecting pipe (3).
) of the driving parts other than ), open the front shutter device M (6) and connect the intake side of each blower to the connecting pipe (3).

In the electric circuit shown in FIG. 6, when the intake shutter opening push button switch PB3 is pressed, the intake shutter is fully opened and the blower is connected. When the number of yarn breaks decreases and there is surplus capacity in the blower, the load on the blower motor is detected electrically, or the static pressure and dynamic pressure of the air flow in the intake pipe (4) or waste yarn chamber 01) is detected. If SWl is opened in the electrical circuit of Figure 6, the load on the blower motor M1' of Figure 5 is reduced by the electrical signal of the blower motor M1' of the other three blower motors. The thermal relay's contact ThR', which turns ON and 0 to 1F, starts and stops due to condition m. For example, in Fig. 1, when the blower at drive unit +2f' is stopped, the exhaust side shutter device (2) is activated at the same time as the blower is stopped, the shutter is rotated to the position at, and the exhaust port C) is activated. 51 to prevent intake of outside air, and in the electric circuit shown in FIG. 6, when the b contact of MO1' closes, the exhaust shutter opens.

The relay is energized, the relay contact 0RR1 in FIG. 5 is closed, and the shutter is fully closed. On the other hand, when the number of thread breaks increases and a drop in suction pressure in the intake pipe is detected, the blower in the driving unit (2) is operated and the exhaust side shutter device M (7) is activated to open the exhaust port Qω. However, in the electric circuit of FIG. 6, when the a contact of MO1' closes, the exhaust shutter opening electromagnetic relay is energized, and the relay contact 0RIF1 of FIG. 5 closes to fully close the shutter. In addition, when winding yarn with a small number of yarn breakages by connecting multiple winding machines, some of the blowers must be stopped in advance because there is surplus capacity in the 7"7-. Exhaust side shutter device (7) of a specific winding machine
) is used with the switch closed, and SW1 of a specific weight is opened in the electric circuit shown in FIG.

As described above, the present invention connects the intake pipes of a plurality of thread winding machines,
When using yarn with a small number of yarn breaks, the blower of some winding machines can be stopped and used to reduce and rationalize power consumption.

[Brief explanation of drawings]

Fig. 1 is a plan layout of the device of the present invention, Fig. 2 is a side view of the unit winding device, Fig. 6 is a side view of a part of the device of the present invention with a part cut away, and Fig. 4 is a plan view thereof. 5 and 6 are electrical circuit diagrams illustrating the present invention in detail. (1) Unit winding device (2) Prime mover section (3) Connecting pipe (4) Intake pipe (711, Exhaust pipe shutter device (8) Exhaust Pipe diagram CRR2 Procedural amendment (spontaneous) 1. Indication of the case 1981 Patent Application No. 171318 2, Name of the invention Kairiiso intake and exhaust device 3, Person making the amendment Relationship to the case Patent applicant Kozu Co., Ltd. Manufacturing telephone number 5a3-ys 11 (Main) Me 5, Date: Showa, Month, Day 6, ``Detailed explanation of the invention'' column of the specification subject to the amendment and Drawing 7, Contents of the amendment (IJ Specification, page 4, 15) 〜Correct "Direct input" in line 16 to "Indicates direct startup without using star delta."
is corrected to "being pushed." (3) Correct "fully open" to "fully closed" on page 7, line 14 and page 8, line 6. (4) On page 9, line 16, ``1 prevent,'' is amended to ``prevent, i.e.,''. (5) On page 10, line 2, “release,” is replaced with “release.”
and correct it. (6) Correct “fully closed” in line 6 of page 10 to “fully open”. : (7) Attachment Aq drawing @”2 drawing-J ← Code and drawer not provided in the attached copy drawing We would like to make corrections to add lines, so we kindly ask for your help. (8) Correct figures 4, 5, and 6 as shown in the attached sheet. Correction location: Refer to the attached attached copy of the figure.” Figure 5 Figure 6

Claims (1)

[Claims] The air intake and extraction system for a winding machine consists of a connecting pipe that connects the intake pipes of multiple winding machines, and a shutter device for the blower exhaust pipe that opens and closes in conjunction with the operation and stop of the winding machine's blower.