CS273741B1 - Lever driving mechanism for weaving loom's weft shears - Google Patents

Abstract

The purpose of the device consists in making possible disengagement of the weft cutter drive out of operation, in the course of the weaving machine operation with the possibility of performing a cut beyond the firm coupling synchronizing with the weaving machine speed or in the course of its stoppage. This is achieved by that the lever driving device is constituted by a pair of mutually resiliently mounted levers (4, 5) by means of a resilient spacing member (6), the driving lever (5) being coupled in its drive with driving cam (11) and the driven lever (4) with the tie rod (9) of the cutting jaw, the force moment of lifting the driven lever (4) being smaller than the force moment of the spacing of levers (4, 5).

Description

BACKGROUND OF THE INVENTION The present invention relates to a lever drive device of a weft shear of a weaving machine, wherein the device is supported by a pendulum and is resiliently engaged with a cam of the coupling dependent drive.

There is known a lever drive device of a weft scissors of a jet weaving machine consisting of one double-arm lever, where its one arm is in circumferential contact with the cam of the drive fixedly dependent on the speed of the weaving machine. Engagement of the lever arm and cam circumference is ensured by a spring. The shear arm of the movable shear jaw is then attached to the second arm of the two-arm lever. This provides a precisely defined π shear of the scissors, which is dependent on the low speed of the weaving machine. In order to exclude the scissors from this fixed bonding dependency, the second shear jaw, which is normally rigid, is coupled by force to an independently controlled solenoid. '

During the normal weaving process, only the first movable shear jaws depending on the speed of the weaving machine. In case the scissors need to be temporarily disabled, the solenoid is excited, which moves a normally rigid second shear jaw in a direction from approximately 00 of the movable first shear jaw. Thereby, ae prevents closure of the weft yarn between the shearing jaws and its shearing.

The need to prevent the shearing of the weft scissors arises in particular after the detection of a weaving error, where it is also necessary to realize an auxiliary shearing independently of the speed of the weaving machine. This auxiliary cut is carried out on the weaving machines by additional scissors placed in the desired area.

Reliable disengagement of the scissors by deflecting the fixed shear jaw is disadvantageous due to the short period of time required for large angular rotation of the deflected second jaw.

A further disadvantage of this embodiment is that the shearing moving first jaw of the scissors, by cutting the weft thread path, may damage it, which may result in the weft thread breaking during the subsequent operation thereof, and thus the impossibility of automatically completing the entire cycle.

The disadvantage of using the auxiliary shears is the need to place them in the path of the weft thread to be swept between the main nozzle and the weft picking channel.

There is very little space in this area, and insertion of the auxiliary shears into the firmly bonded shears results in an unevenly cut off end of the weft thread protruding from the main nozzle.

The above drawbacks overcome the weft scissor lever drive device of the present invention, which is constituted by a drive lever and a driven lever which are spring-loaded with an expanding resilient member, the drive lever being driven coupled and the drive cam and driven lever and shear rod, the driving torque of the driven lever is less than the torque force of the driven lever and drive lever.

The object of the invention is shown in the attached drawing in a side overall view.

In this exemplary embodiment, the device body 1 is fastened to the fixed parts of the weaving machine by means of screws 2. In the right part of the body 1 there is attached a first pin 3, on which the pivoted lever 4 and the drive lever 5 are pivoted. The driven lever 4 is provided, at its free end, with a second pin 8, which is connected to the drawbar 9 of the movable shear jaw, not shown. As a whole, this lever assembly 4, 5 is sprung by a spring element 10 formed by a coil spring into engagement with the cam 11. This spring bears on one end on the driven lever 4 and the other on the body 1. The cam engagement with the lever assembly 4, 2,3 12 mounted at the end of the drive lever 5 such that the roller 12 is a β cam 11 in circumferential contact. The cam 11 is fixed by a drive shaft 13 which is rigidly dependent on the speed of the weaving machine. A solenoid 14 is fastened to the body by a pair of levers 4, 5 in a dust-tight housing (not shown) 273741 B1.

The shaft 16 is mounted in a pair of sliding bearings 18. A shaft member 20 is mounted on the shaft 16 by its bearing 19, which has a strut surface 21 at its free end. A longitudinally adjustable locking cube 22 is mounted against the strut surface 21. The cube 22 and the strut surface 21 of the strut member 20 in the buckled state is a gap the size of which is given by the spreading of the levers 4, 5 at rest and is adjustable by an adjusting screw 7. From below. of the roll 24 forming an independent element 25 of the lever drive device in relation to the speed of the weaving machine.

The air cylinder 24 is connected to a pressurized air source via a control valve (not shown).

For proper operation of the lever drive device, it is necessary that the lift torque of the driven lever 4 is less than the torque of the strut of both levers 4, 5.

The stroke moment of the driven lever 4 is given by the force of the spring element 10 multiplied by the perpendicular distance of the pivot point from the direction of its action plus the displaceable inertia forces.

The expansion moment of the two levers 4, 5 is then again given by the expansion force of the levers 4,5 multiplied by the perpendicular distance of their pivot point from the direction of application of this force.

In spite of the normal operation of the weaving machine, the shaft 13 is rotated in a fixed coupling dependent on the speed of the weaving machine.

The shaft 13 carries with it the cam 11 and it pivots over the roll 12 by a system of levers 4, 5. The rod 9 fixed to the driven lever 4 then shears the not shown movable jaw of the scissors. Spring spacing elastic member 6 strutted levers 4, 5, while acting as a solid unit, since the force moment spacing levers 4, 5 ^ev 3 ®tší than the force moment of lifting the driven lever 4. At the stroke during normal weaving thus biases a spring elastic element 10, which simultaneously pulls the drawbar 9 down and ensures a constant engagement of the roll 12 with the circumference of the cam 11.

At the moment when the scissors are disabled, current is applied to the solenoid 14. This overcomes the resistance of the spring 17 and pulls the armature 15. By rotating the shaft 16, the support member 20 is also rotated, thereby shifting its support surface 21 against the blocking cube. Thus, the upwardly moving driven lever 4 is locked by the strut member 20 and the shear movement of the rod 9 is stopped.

On the periphery of the cam 11, the rolling roller 12 is then spring-biased by the spring of the expanding resilient member 6 so that only the drive lever 5 pivots, while the driven lever 4 remains stationary. After the current in the electromagnet 14 has been canceled, the armature 15 is returned by its spring 17 to its original position, whereby the strut member 20 leaves its space against the locking shaft 22 of the driven shaft 4 with its strut surface.

The scissors (not shown) are then ready for normal operation again. The construction of the expanding member 20 is volena-? So that there is not or only to a minimal bending stress in mutually braced ₍ 'locking condition when the driven lever fourth

The geometrical position of the strut 21 in the bucked position and the bearing 19 of the strut 20 is such that a circle centered at the pivot point of the driven lever 4 extending through the strut 21 also extends through the pivot point of the strut 20 or at least through it.

If the shears (not shown) are to be cut between the individual strokes of the linkage 9 or when the weaving machine is stopped and hence the rotation of the shaft 13 is stopped, the shearing is carried out by a coupling independent drive element 25. Compressed air and piston rod 23 it overcomes the spring resistance of the spring element 10. In doing so, it rotates the driven lever 4, thereby shearing the rod 9.

The lever drive mechanism thus made can be used in all types of weaving machines with scissors having one shear jaw and the other movable.

CS 273741 Bl

The device shown in the drawing is shown in the locked drive lever position 4. The embodiment shown in the drawing is merely exemplary because, for example, levers 4, 5 need not be rotatably mounted on a common first pin 3. Also, the driven lever 6 need not engage the buckling member. 20 via the blocking block 22, but directly.

Claims (4)

1, A weaving machine of a weaving machine of a weaving machine mounted pendulously and spring-loaded with a cam of a coupling-dependent drive by a resilient element, provided with a locking device, characterized in that it consists of a drive lever (5) and a driven lever (4) a spacer spring member (6), wherein the drive lever (5) is coupled to the drive cam (11) and the driven lever (4) and the shear bar (9), the lift torque of the driven lever (4) being less than the force the torque of the drive lever (4) and the drive lever (5). Device according to Claim 1, characterized in that the driven lever (4) engages the strut surface (21) on a fixed part of the weaving machine of the rotatably mounted strut member (2) in the strut position, Device according to claim 2, characterized in that the strut face (21) of the strut member (20) in the strut position and its bearing (19) passes a circle centered at the pivot point of the driven lever (4). Device according to claim 3, characterized in that the drive lever (5) or the driven lever (4) is coupled to the independent drive element (25) formed by the air cylinder.