CS261787B1 - Pneumatic threading device for a spindle of a two-for-one twister - Google Patents

Abstract

The invention relates to a pneumatic threading-in device for spindles of a two-for-one twisting machine, in which each spindle is of hollow design and is adapted for the passage of the thread by means of a compressed-air stream. The object of the invention is to design the device in a simple way, so that it introduces the thread without the assistance of the operator. The essence of the invention is that the device is formed by a body which is pivotable out of its position of rest into its working position by means of a journal mounted pivotably in a fork, that the device is formed at the end of a hollow holder fastened at its other end to a bracket which is advantageously fastened to a compressed-air conduit, into which there opens a flexible hose connected to the body by means of a valve, there being fastened to the flexible hose a tube provided with a vertically arranged nozzle having an outlet orifice, that there is mounted in the hollow holder displaceably under the pressure of the compression spring a displaceable piston, in the axis of which there is fastened to the piston an actuating cord connected to an actuating device, and that connected pivotably to the other end of the piston is a pull rod which is fastened to the body by means of a further journal so as to be capable of pivoting out.

Description

BACKGROUND OF THE INVENTION The present invention relates to a pneumatic threading device of a spindle of a twist-twisting twisting machine, each spindle of which is hollow and adapted to pass a thread with a compressed air flow.

At present, a manual air gun is used to thread the threads into the spindle of two-twist twisting machines, whose compressed air outlet channel is terminated by a screw spring connection. This connection is intended both to connect the air gun to the mouth of the spindle feed tube and to introduce the free thread end into the inlet opening of the spindle feed tube from the master spool. When using a hand-held air gun, the yarn is first sucked through the gap between the threads of the connection and is then introduced into the spindle inlet through the compressed air stream and its channels through a continuous compressed air stream towards the end spool for winding the twisted twisted thread.

The disadvantage of this threading device is the necessity of manually fitting the nozzle feed tube mouth and its connection with it, which makes it possible to damage the functional part of the spindle feed tube mouth and thus to distort the twisting process.

Further, a threading device is known comprising a connection for supplying compressed air to a stationary duct disposed parallel to the hollow shaft of a twin-twist spindle where the injector nozzle is. Under the action of the injector, the thread is sucked into the spindle inlet tube and is then carried by a compressed air stream. *

When threading the spindle with this device, it is necessary to attach the connection to the mouth of the stationary channel, which makes operation difficult and makes the unwinding of the thread from the master spool difficult.

In another known threading device, the compressed air is supplied via a connection to a radial channel formed in the bottom of the protective jacket and directed towards the injector nozzle, by means of which the yarn is sucked into the hollow shaft of the spindle and then carried by the compressed air stream.

The disadvantage of this solution is the relatively complicated air supply to the hollow shaft of the spindle requiring perfect sealing of all transition points of the parts forming the air ducts.

All known spindle threading devices controlled by compressed air have the common disadvantage that compressed air from the source is supplied to the hollow shaft of the spindle with a differently provided connection or an air gun, which is connected to its supply tube during the threading of the spindle. This can in some cases cause damage to the mouth of the spindle inlet tube or impair operating conditions. Some of these devices are complex and thus quite expensive.

These drawbacks and drawbacks are eliminated by the penumatic threading device of the twin-twisting twisting machine according to the invention, which consists of a working body mounted pivotably on a pivot which is mounted pivotably in a fork formed at one end of the hollow holder which is connected to the bracket to a compressed air supply duct into which a pressure hose is connected to the working body with an opposite end, to which a pipe terminated by a perpendicular air nozzle with an outlet opening is fixed, the plunger is slidably mounted in the hollow bracket under pressure of a compression spring a control cable connected to the plunger is inserted through the opposite end into the actuating device, while a rod pivotally mounted on the pivot in the working body is pivotably attached to the opposite end of the plunger.

According to the invention, the axis of the air nozzle in the operating position may coincide with the axis of the inlet pipe of the spindle or form an angle of up to 60 ° therewith.

An advantage of the pneumatic threading device according to the invention is that the supply of compressed air is effected by a simple nozzle with a gap between its outlet opening and the inlet opening of the spindle tube in the working position, advantageous for threading the thread into the hollow spindle. the spindle tube, so that the functional part of the lance cannot be damaged.

An exemplary embodiment of a pneumatic threading device is shown in the drawings, wherein Fig. 1 is an axial sectional view of a spindle of a twin-twisting twisting machine in a front view with the pneumatic threading device associated therewith in its rest position; FIG. 3 shows an axial section of a portion of the spindle feed tube and the air nozzle in a threaded position arranged on a common axis; and FIG. 4 shows the same axial section, but the air nozzle is deflected from the spindle feed tube axis.

A hollow support shaft 6 is mounted in the spindle pulley 4 of a twist twist machine (not shown), on which a disk 6 is fixedly mounted, to which the plate 6 is attached. On the support shaft 2, the protective sleeve 4 of the master coil 7 is rotatably supported by means of a hub 6 and bearings 8, 6 arranged between the hub 6 and the support shaft 6. A hollow push-in sleeve 60 is axially mounted on the hub 8, at the end of which a supply tube 11 with an inlet 12 is inserted. The pulley 8, the support shaft 4, the disk 4 and the plate 4 form the spindle rotor of a two-twisting twisting machine. A cylindrical balloon restrictor 13 is provided coaxially, but spaced from the protective jacket 4 of the master spool 4, with a permanently attached permanent magnet 65 to cooperate with another permanent magnet 14 fixedly attached to the bottom of the protective jacket 8. By interaction of the permanent magnets 4, 15, the protective sheath 4 is secured in a stationary position. A twisted thread guide 16 is rotatably connected to the socket 10.

A pneumatic threading device arranged laterally above the level of the spindle and formed by an air nozzle 17 and an outlet aperture 52, which is connected to the body 22 with a valve (not shown), by an elbow 20 and a pipe 21 connected thereto, is associated with the spindle described. A flexible hose 23 is connected to the working body 22 and connected to the pipe 24 connected to a compressed air source (not shown) and attached to a two-twisting twisting machine frame (not shown). The working body 22 is pivotally supported by a pin 27 in a fork 25, which terminates in a vertically oriented hollow bracket 26 connected by its opposite end to a bracket 28 clamped to a pipe 24. A plunger 31 is slidably mounted in the hollow bracket 26 a rod 30 extending with its opposite end into a cutout 29 in the working body 22 to which it is connected by a further pin 38. Underneath the plunger 31, there is a compression spring 24 in the hollow bracket 32, in the axis of which the cable 35 is connected by one end to the plunger 31 and the other end to a control device (not shown).

Prior to threading the threads 36 into the spindle, the operator normally brakes the spindle rotor (not shown) which, by means of the control cable 35, pulls the plunger 31 against the action of the compression spring 34. in which the air nozzle 17 with its outlet opening 18 is directed against the inlet opening 12 of the lance 11. With this swivel movement, a valve (not shown) is opened inside the working body 22 and the compressed air flows from the pipe 24 through the flexible hose 23 into the lance 11. In the working position of the pneumatic threading device, there is a gap between the outlet opening 18 of the air nozzle 17 and the inlet opening 12 of the inlet pipe 11, through which a cone-shaped compressed air stream 9 passes through exactly into the inlet opening 12p. 3, either directly if the x-axis of the air nozzle 17 coincides with the axis у of the lance, as shown in FIG. 3, or at an angle of up to 60 ° when the x-axis of the air nozzle 17 is clamped with the axis θ of the feed tube 11, the angle φ 1 as shown in Fig. 4

The operator then inserts thread 36 into the inlet opening 12 of the feed tube 11, unwound from the master spool 7 and threaded through the guide 60. The air cone 19 causes the thread 36 to be drawn into the lance 11, from which it is carried by the compressed air stream through the hollow push-in sleeve 48, the hollow support shaft 8, the channel in the disc 6 and the space between the protective sheath 5 and the balloon limiter 13 to a double-twisted twist winding device (not shown) of £ 6. The operator then engages the free end of the yarn 36, connecting it to the yarn end (not shown) of the end spool (not shown), and actuating the actuator (not shown) to release the control cable 15. This allows the compression spring 34 to return the plunger 31 to its position, 30 returns the working body 22 to its original rest position in which the pressure air valve (not shown) in the body 22 is simultaneously closed.

At the same time, the control device (not shown) releases the spindle rotor and sets it in twisting rotation.

The pneumatic threading device according to the invention of spindles of two-twist twisting machines with a vertical one can be used for threading the thread into the horizontal and inclined axis.

Claims (3)

Pneumatic spindle threading device of a twin-twisting twisting machine, each spindle of which is hollow and adapted to pass a thread with a compressed air flow, characterized in that it consists of a working body (22) pivotally mounted on a pivot (27) which is pivotally mounted in a fork (25) formed at one end of a hollow bracket (26) which is connected at the opposite end to a bracket (28) attached to a pressurized air supply pipe (24) into which a flexible hose (23) is connected a body (22) to which is attached a pipe (21) terminated by a perpendicularly arranged air nozzle (17) with an outlet opening (18), the plunger (31) being slidably mounted in the hollow holder (26) under pressure of the compression spring (34); in the axis of which a control cable (35) connected to the plunger (31) is inserted, inserted through the opposite end into the actuating device, while the other end of the plunger (31) is pivotable a tie rod (30) rotatably mounted on a pin (33) in the working body (22) is connected. Pneumatic threading device according to claim 1, characterized in that the axis (x) of the air nozzle (17) is identical to the axis (y) of the spindle inlet tube (11). Pneumatic threading device according to claim 1, characterized in that the axis (x) of the air nozzle (17) forms an angle (phi) of up to 60 ° with the axis (y) of the spindle feed tube (11).