CS215082B2 - Method of the drive and braking of the weft at the weacing machine with stabil arranged bobbin of the weft thread - Google Patents

Abstract

Weft drive and braking equipment threads (7) for weaving machines with the help of flowing medium at which the weft thread is (7) alternately using guide guides (4, 5) and storing the thread guides (6) around it continuously drum (1a, 1b, 1c) and coaxial with it a fixed drum (2a, 2b, 2c) thereby the energy is low, mechanical accelerating weft yarn for picking and k the end of the weft for soft weft braking threads. There is a knot and shear to retract into the blow nozzle (13). In addition to saving energy and flowing media for acceleration of the picking is also achieved by soft braking. The device of the invention is applicable for all machines where it is required in rapid succession accelerating the thread with the following by braking it to a complete stop.

Description

The invention relates to a device for driving and braking a weft in a weaving machine with a fixed weft thread bobbin, in which the weft thread is guided alternately around a rotating and coaxial fixed drum for driving and braking.

In such weaving machines, the weft must be accelerated at the beginning of each pick and slowed at the end.

Each such weaving machine construction has devices which correctly accelerate and slow down the weft. However, since the necessary forces often have to be generated during a short section of the weft, this leads, in particular to weft yarns from short staples, to breaks.

SUMMARY OF THE INVENTION It is an object of the present invention to promote acceleration or deceleration in such weaving machines by means of an additional device and to apply the necessary forces over a long weft range.

This object is achieved according to the invention in that the device for driving and braking the weft is provided with a weft thread guide arranged movably in the direction of the axis of at least two drums arranged coaxially side by side, the at least one drum being driven at a constant speed.

The weft passes through the guide loop and thence tangentially to the drum, which spans at least 90 ° around the wrapping angle and from there runs in a tangential direction and passes through the second guide loop. Depending on the position of the guide lugs, the weft passes through a rotating or fixed drum.

The invention will be explained in more detail below with reference to the drawings, in which FIG. 1a shows a front view of a device according to the invention with drums and a weft thread guide; FIG. 1b shows the same apparatus as in FIG. 1a but viewed from above; 3a, 3b of the device according to the invention used in the weft feeding device, FIG. 4 shows different ways of arranging the drums.

Figures 1a and 1b show an object of the invention in an embodiment with two cylindrical drums 1 a and 2a having the same diameter. The drum 2a is rigidly arranged and includes a bearing for the shaft J. The drum 1 is mounted on the shaft 2 and is driven by the drive means 8 so that it rotates as indicated by the arrow. The drums 1a and 2a are arranged side by side without touching each other.

The weft yarn 7c first passes through the guide eyelet 1, then encircles the drum 1 or 2a at a wrapping angle of about 270 °, moves tangentially and passes through the guide eyelet. Both guide eyelets 4 and 2 are supported by the weft yarn guide 6 it periodically moves up and down so that the weft yarn 7c alternately surrounds the drums 1 a and 2a. In this case, the weft yarn guide 6 is controlled so that the weft yarn loop 7c is guided around the drum 1 and if the weft yarn 7c and 7d is to be supported , and around the fixed drum 2a if the weft yarn 7c and 7d is to be braked. The driven drum 1a rotates at a constant speed such that its greatest peripheral speed is greater than the maximum speed of the weft yarn 7c and 7d.

Variants of the drums are shown in Fig. 2. The fixed drum 2b has a cylindrical shape and operates or cooperates with the driven drum 1b, respectively. The driven drum 1b has a cylindrical portion having a larger diameter than the fixed drum 2b and a conical portion that serves to transition between the two diameters. As a result, the weft yarn loop surrounding the drum 1 or 2b changes its diameter as it periodically moves the weft yarn guide 6 shown in Fig. 1a from one drum to the other drum. The weft thread loop around the drum 1b or 26 may be considered as a supply of weft thread. The change in the diameter of the weft thread loop is equal to the change in the length of the stock weft thread.

For example, if the weft yarn loop moves from the driven drum 1b to the fixed drum 2b, it will leave the drums of the weft yarns for a short time before being fed to them.

Upon transition of the weft yarn loop from the solid drum 2b to the drum 1b. less weft thread is then removed than is fed as the weft yarn loop increases.

This phenomenon can be used to additionally influence the positive and negative acceleration of the weft yarns 7c and 7d. In addition, it is advantageous for many applications if, in connection with the drive and braking of the weft yarn 7c. 7d, additional weft yarn accumulation is initiated as shown in FIGS. 3a, 3b. FIG. 2 shows other combinations of drum diameters. The fixed drums 2b, 2c are combined with the driven drums 1b. 1 e.

Figures 3a, 3b show an object of the invention when used in a weft feeding apparatus in a pneumatic weaving machine.

The weft yarn 7a coming from the stock bobbin 12 through the pull roller 11. from there it is fed as weft thread 7b to the deflection member 2 and as weft thread 7c further to the guide eyelet 8, around the drums 1b. 2b, then a guide loop 2 and a blowing nozzle 13. In operation of the weaving machine, the pulling roller 11 rotates at a constant speed and supplies the weft yarn 7a to the deflection member 2, which moves on the track 10 synchronously with the weaving machine. The conveying amount of the pulling roller 11 and the travel speed of the deflection member are matched to each other such that the weft yarn 7c stops in the guide eye 6 whenever the deflection member moves in the direction from the axis 17 of the track 10 to the axis 16 of the track 10. the deflection member again from the axis 16 of the track 10 to the axis 17 of the track 10, then the weft thread 7c in the guide eyelet 4 is again in motion. This process occurs periodically in such a way that the weft thread 7c. 7d moves as long as the readiness shed 4 for weft picking.

Weft loop 7b. 7c in the shape of the hairpin formed by the deflection member 2 is withdrawn by the action of the blowing nozzle 13 if weft picking is to be carried out. The force required to accelerate this piece of weft yarn is exerted by the blowing nozzle 13 and on the drums 1b. 2b. If the force exerted by the blowing nozzle 13 and acting on the weft yarn 7d is marked as force S, then the total force acting on the weft yarn portion 7c is indicated. ^S 2 ^{= S} 1 'where e = 2.71, u = coefficient of friction between the weft yarn and 7c of the cylinder 1B and alpha = angle of wrap of the weft yarn around a drum 1b 7c. 2b.

The movement of the guide 6 is adjusted so that the weft thread loop lies between the guide eyelet 4 and 2 around the driven drum 1b as long as the deflection member 2 moves in the direction from the axis 16 to the axis 17 of the track. During this process, the weft yarn 7d is inserted into the shed 15. As soon as the deflection member 2 begins its semicircular path near the axis 12, the weft yarn 7c slows down. 7d, and this results in an additional inertial force acting on the weft yarn 7b. In order to prevent this force from acting on the weft yarn 7c and thereby imposing unacceptably high stresses, the weft yarn guide 6 is controlled in a timely manner at the start of the deceleration so that the weft yarn loop 7c. 7d has been placed around the solid drum 2b. Before the deflection member 2 on its path ¹ from the axis 17 to the axis 16 of the track 10 again enters its semicircular portion at the axis 16, the weft yarn guide 6 introduces the loop formed by the weft yarns 7c. 7d again on the driven drum 1b.

The design of the drum 1b, 2b with different diameters brings with it the additional advantage of cutting the weft yarn 7d with the scissors 14. This occurs after each weft picking with the weft yarn still standing. When cutting the weft yarn, the loop formed by the weft yarn 7c lies. 7d around the solid drum 2b. since the weft thread loop from the fixed drum 2b to the driven drum 1b is still transitioned while the weft yarn 7c is at rest. causes the weft thread loop to expand by pulling the weft thread tip 7d away from the scissors 14.

This is highly desirable since it prevents the tip of the weft yarn 7d from getting caught by the flow from the blowing nozzle 13 against the shears 14 or other adjacent parts before the weft is changed.

Fig. 4 shows embodiments for seamless arrangements of the two drums 1a, 1b, 1c, 1d, and 2a, 2b, 2c, 2d side by side.

Claims (4)

A device for driving and braking a weft in a weaving machine with a fixed weft yarn supply bobbin, in which the weft yarn is guided alternately around a driven and coaxial fixed drum, characterized in that it is provided with a weft yarn guide (6) movably arranged in the axial direction of the at least two drums (1a, 2a, 1b, 2b, lo, 2c) arranged coaxially side by side, at least one of the drums (1a, 2a, 1b, 2b, 1c, 2c) being driven at a constant speed. Device according to claim 1, characterized in that the driven drum (1a) and the fixed drum (2a) are of the same diameter. Device according to claim 1, characterized in that the driven drum (1a, 1b, 1c) and the fixed drum (2a, 2b, 2c) are of unequal diameter. Device according to Claims 1 and 3, characterized in that the transition between the driven drum (1b, 1c) and the fixed drum (2b, 2c) of unequal diameters is formed by a conical part which is driven or fixed.