CS241428B1 - Thread feeder for textile machines especially for ring twisters - Google Patents

Abstract

The subject of the invention is a yarn-feed device for textile machines, especially ring twisting machines. The device contains a magnetically conductive coupling element (7) which is mounted axially adjustably on a shaft (2) between a driving wheel (6) and a brake lining (15), behind which an electromagnet (17) is arranged. The magnetically non-conductive brake lining (15) is arranged between the pole pieces of a permanent magnet (11), the end faces of which lie in one plane with the end face of the brake lining (15). The diameter of the coupling element (7) is larger than the outside diameter of the brake lining (15). …<IMAGE>…

Description

The subject of the solution is a yarn feeding device for textile, especially ring twisting machines. The device comprises a mgantically conductive clutch element which is axially displaceably mounted on the drive wheel and the brake lining behind which an electromagnetic bearing is mounted. The magnetically non-conductive brake lining is mounted between the pole pieces of the permissible magnet, whose front surfaces are flush with the front surface of the brake lining. The diameter of the clutch element is larger than the outer diameter of the brake lining. A magnetic conductive auxiliary ring is rotatably mounted on the clutch element and secured against axial displacement.

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BACKGROUND OF THE INVENTION The present invention relates to a yarn feeder for textile, in particular annular twisting machines, comprising a magnetically conductive clutch element, axially adjustable on a shaft between a drive wheel and a brake lining, behind which an electromapnet is mounted. the front surfaces of which are flush with the front surface of the brake lining, the diameter of the clutch element being larger than the outer diameter of the clutch lining.

In the known yarn feeder, the feed roller is driven by a toothed belt or chain from a toothed clutch which is actuated by a lever mechanism coupled to a respective work station, for example a spindle. By adjusting the gear coupling axially on the drive shaft, the lever mechanism disengages the feed mechanism formed by the bead.

In another known yarn feeding device, the feed roller is mechanically coupled to the friction wheel and is withdrawn from the drive shaft provided with the friction wheels as required. The friction wheels can optionally be replaced by toothed wheels. The pulling of the feeding device is ensured by mechanical coupling with the spindle control.

In newer methods of operating the yarn feeding device, electromagnetic couplings mounted on a countershaft countershaft are used. Electromagnetic couplings are continuously supplied with power during operation.

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A drawback of the yarn feeder with a mechanical toothed clutch is the necessity of a mechanical bond with a workstation, such as a spindle, which cannot be used with electric stop spindles. Similarly, in the case of a device with a hinged bale, a mechanical linkage with the workstation is required, and moreover, the friction drive causes an undesirable slip on the periphery of the friction wheels and consequently the technological parameters of the thread being processed are not observed. If toothed clutches are used for the torque accuracy, the slip is removed, but the risk of incorrect or late engagement of the teeth increases. With feeder devices operated by an electromagnetic clutch, the main drawback is the need for continuous power supply during operation.

The above-mentioned disadvantages are overcome by the yarn feeding device for textile, in particular annular twisting machines according to the invention, characterized in that a magnetically conductive auxiliary ring is rotatably mounted on the coupling element and secured against axial displacement.

An advantage of the yarn feeder according to the invention is its low power consumption during operation control. It does not consume any electrical energy, either in the braked state or during operation. The feeder device contains a minimum number of moving parts, is very reliable and allows computer control.

An exemplary embodiment of a feed device according to the invention is shown in the accompanying drawings, in which Fig. 1 shows the device in the received state and in Fig. 2 the feed device is shown in the braked state.

In an exemplary embodiment, the yarn feeder is formed by a body in which the shaft 2 is rotatably mounted, for example on rolling bearings 2. At one end of the shaft 2 a bead 4 is fixedly fixed, on the circumference of which one or more windings of a thread not shown. At the opposite end of the shaft 2, a drive wheel 6, which in the exemplary embodiment is formed by a toothed pulley, is rotatable, for example by means of a rolling bearing 6. The inner face of the drive wheel 6 is provided as a friction surface for a clutch element 6 mounted axially adjustable on the shaft 2, wherein

3 241 428 is secured against rotation, for example by means of the grooves in the shaft 2 and the projections engaging therein, provided in the clutch element 2. A clutch lining 8 is fastened to the surface of the clutch element 2 abutting the drive wheel 6.

In an exemplary embodiment, a magnetically conductive sub-ring (j) is mounted on the clutch element (1) and is rotatably mounted thereon. the coupling element is secured against axial displacement.

The casing 1 is fixed magnetically conductive housing 10 in which is formed an annular gap which accommodates the permanent magnet rings 11 are shaped ^to ^ o ^ m tery poison DOS box ^{"can be} on the bottom of the annular gap 10. The inner housing průměr.permanentního magnet 11 is larger than the inner diameter of the annular gap of the housing 10, so that a gap 12 is formed between the permanent magnet 11 and the inner wall of the annular gap of the housing 10, which is air, but can be filled with any non-magnetic material. In the upper part of the annular gap of the housing 10 is an inner housing part 10 secured vnitřní.prstenec 12 forming together with the casing 10, one pole piece on the permanent ^h m ^g net 11. The other ^{pole of} the AC ^{and the} adjusting ^p n ermanentn ^¹H the magnet 11 is formed by an outer a ring 14 formed by a cylindrical portion 141 and a flange 142. A magnetically non-conductive brake lining 15 is fixedly positioned between the end of the cylindrical portion 141 of the outer ring 14 and the outer end of the inner ring 15, the front surface of which is flush with the faces of the cylindrical portion 141 of the outer ring 14 and the inner ring. 22 ·

The inner diameter of the flange 142 of the outer ring 14 is smaller than the diameter of the inner surface of the annular gap of the sleeve 10 so that a space 16 is formed between the inner diameter of the outer ring 14 flange 142 and the inner wall of the annular gap. filled with another suitable non-magnetic material »An electromagnet 17 is located in the space between the brake lining 15, the outer ring 14 and the inner ring 15.

A resilient member is received in the housing 10 or in the body 1

In the alternative embodiment, the resilient member 18 may alternatively be formed in another manner, for example one helical compression spring.

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The resilient member 18 abuts the sub-ring thereby pressing the clutch element 2 against the friction surface of the drive wheel 6. In the absence of a sub-ring 18 between the clutch element 2 and the brake lining 15, the resilient element 18 abuts the clutch element 2 directly. The air gap 20 is formed between the braking surface 19 and the abutment surface of the auxiliary ring 7 or the clutch element 2.

The air gap 16 between the pole pieces of the permanent magnet 11 is smaller than the air gap 20 between the braking surface 19 and the contact surface of the auxiliary ring or clutch element 2 ^{in the} released state.

In the braked state, the gap 16 between the pole pieces of the permanent magnet 11 is greater than the gap 20 between the braking surface 19 and the seating surface of the sub-ring 2 or the clutch element 2.

Timing pulley 6 is driven by a toothed belt, not shown in the released state and entrains the coupling element together with the auxiliary ring J.Spojkový element 2 .I ^{е к} driving wheel 6 is pressed against the elastic member 18 »Together with the coupling element 2 e rotates the shaft 2 and fixed thereto godet 4.

In this case, the magnetic circuit of the annular permanent magnet 11 closes from one pole of the permanent magnet 11 via the housing 10, the air gap 16 between the pole pieces and the flange 142 of the outer ring 14 to the other pole of the permanent magnet 11. however, due to the ratio of the width of the air gap 16 between the pole pieces of the permanent magnet 11 and the width of the air gap 20 between the brake surface 19 and the sub-ring 2 in the released state, the force effect of the permanent magnet 11 on the sub-ring 2 is overflowed. by the force of the resilient member 18 »

Applying an electric pulse of a DC voltage of a certain polarity by means of conductors (not shown) to the coil of the elect / magnet 17 adds the magnetic flux of the electromagnet 17 and the permanent magnet 11. The force effect in the air gap 20 between the braking surface 19 and the auxiliary ring increases. Ring% overcomes

- 5241428 force of the resilient member 18, whereby the auxiliary ring 2 together with the coupling element £ axially moves and compresses the elastic member 18o After · MOCR ring 2 engages the braking surface 19 formed by the helical ^pl OCHEM ^ ^{i pole} ovýc ^h bits ^p ermanentn ^¹H about of the magnet 11 and the brake lining, thereby braking the shaft 2 with the bead 6. At the same time, the clutch element 2 moves away from the drive wheel 6, whereby the clutch system disengages and the drive wheel 6 continues to rotate. The shaft 2 with the galette 4 will remain braked even after the electrical pulse has been lost, somewhat the air gap 20 between the braking surface 19 and the sub-ring 2 has decreased, thereby changing the magnetic flux of the permanent magnet 11 which now closes over the pole pieces and the auxiliary ring 2t, thereby helping. the ring · keeps it pressed against the brake lining and the clutch element. 2 It is pulled away from the drive wheel 6. Since the auxiliary ring 2 is rotatably mounted on the clutch element 2, the shaft 2 and the bead 4 fixed thereon can be freely rotated.

The feeding device is released by electrical supply. a pulse of direct voltage into the coil of the electromagnet 17, the pulse having the opposite polarity as the pulse to be braked. The magnetic flux of the solenoid coil 17 suppresses the effect of permanent magnetic flux. In this way, the coupling ring 2 and the resilient member 18 push the sub-ring 2 together with the clutch element 2 in the axial direction, so that the clutch lining Ό abuts against the friction surface of the drive wheel 2 and the shaft 2 with the bead 4. An air gap 20 is formed between the auxiliary ring 2 and the braking surface to prevent re-tightening of the auxiliary ring 2 with the clutch element 2 'to the brake lining 15 by the force of the permanent magnet 11.

Claims (1)

SUBJECT OF THE INVENTION Thread supplying device for a textile, in particular annular · twisting machines, comprising a magnetically conductive coupling element is axially displaceable on the shaft between the driving wheel and the brake clad · IM Nevo ^the previously brake oblomní permanent magnet ^E-plane with the frontal ^and · Ploc ^h ou Veho element is ^{characterized by Et} Si ^brand Ujica around and behind which the brake is mounted electromagnet, · wherein the magnetic pole is disposed between nestavící whose. face surface located at one of the brake linings with the primers spojkonež outer primers of the brake lining, that the coupling element (?) is ^rotatably stored rnagnetick ^{n Y in} wild auxiliary ring ⁽⁹⁾ which is ^of n zajl.št against axial displacement.