DE190593C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

CLASS 76 d. GROUP

Patented in the German Empire on December 16, 1906.

In the case of automatic winding machines, the winding spindle must be used for the time during which the stripping of the completely wound coil takes place, must be stopped, otherwise on the one hand, the threads on the bobbin face on the stripper facing the stripper chafe and thereby damage and on the other hand while walking back and forth of the stripper turns

ίο the rotating winding spindle lie down, which both results in bad windings.
- In the first winding machines with friction roller transmission, the spindle rotation is interrupted by removing the spindle with its friction roller from the driving friction roller. This type of interruption of the spindle rotation is reliable, but the transfer of motion from the thread guide shaft to the winding spindle by means of friction is unsafe, in that slippage occurs between the thread guide shaft and the winding spindle. As a result, there has been a transition to the transmission of motion by means of gears. With regard to security

means nothing to be desired in the transmission, but the gear ratio is only adjustable using intricate (differential) devices, as required for closed turns for different yarn counts. Belt drives however, now allow the transmission ratio to be adjusted. the However, transmission is because of the very different sized pulley diameters with the small shaft distances given by the size ratios of the machines not safe and the belts require special tensioning devices. The latter Both types of transmission also require, because both thread guides as Also the winding spindle cannot be disengaged, the application of a clutch to the rotation of the winding spindle during the To interrupt stripping. This clutch can now be used with wheels as well as with Belt transmission mounted either on the thread guide shaft or on the winding spindle be. If it is on the thread guide shaft, this will be when it is disengaged entire gear or belt drives with disengaged. But such a transmission has because of the flywheel it contains and the high speed of rotation a 'so great persistence that the winding spindle after the clutch is disengaged spins too long. If the coupling is arranged on the winding spindle, so the loosely rotating coupling half exerts a torque on the spindle, which is caused by the belt tension or the tooth pressure is increased. This in turn has the disadvantage that the winding spindle performs rotations, which are not desired. Both cases also make it necessary to use a brake, which, however, if coincidences occur, such as B. Inadequate or careless lubrication, causing oil in the brake

does not come into effect, or does not work properly or not at all when fluff and waste build up comes. In addition, rigid, so-called hard couplings are used excluded due to the high speed of rotation, and it can only Friction clutches are used, but with the size ratios of the Machines can only be executed inadequately in terms of construction, which means that the the use of gear or belt drive achieved relatively safe transmission is lost again by sliding in the coupling.

The present invention relates to a belt drive winder for the Winding spindle, in which, as is already known on other machines; a Cord or belt drive by bringing one drive pulley closer to the other is automatically stopped. Here, however, the arrangement is made that after completion a coil that automatically brings one pulley closer to the other, thus stopping it the winding spindle of the belt is automatically relaxed, whereupon after stripping the coil automatically removes this pulley from the other and so the belt is automatically tensioned to restart the spindle rotation.

The drawing illustrates an exemplary embodiment of the subject matter of the invention in FIG. 1 in a partial front view and in FIG. 2 in a partial plan view. Fig. 3 and 4 represent sections along the line AB in Fig. 2 with working parts adjusted to one another.

The winding spindle c , which carries the winding mandrel d, is mounted in a bearing block b carried by a base plate α. Below c , the thread guide shaft e (FIG. 2) is mounted on b , which serves to move the thread guide f and carries a loose disk g and a fixed disk h. This shaft is the carrier of a toothed wheel i fastened on the same, in which a toothed wheel k engages, which is fastened on a shaft / mounted in front of the thread guide shaft on b. On the winding spindle c there is a weakly co-

5 <r niche pulley m and in front of this a rocker η rotatable around the shaft / is arranged in front of this, in which a shaft ο running parallel to this is mounted at the level of the winding spindle, on which a pulley ρ is attached opposite the pulley m is. The shaft 0 also carries a gear q mounted on it, which meshes with a gear r mounted on the shaft /. The pulleys m and ρ are approximately the same size and as a result the belt drive will work reliably.

The necessary translation from shaft e to shaft / is carried out by the gear drive i, k. Behind e , in extensions of the base plate a, a shaft s running parallel to e (FIG. 2) is mounted, on which a cam disk t is firmly attached. This is able to work together with a roller ν mounted on a rail u in order to push the rail, which is arranged displaceably in its longitudinal direction, forwards. Since the front end of this rail rests against an adjustable stop w of the rocker, the rocker is swung backwards.

The operation of the winding machine described above is as follows:

The winding spindle is driven from the fixed disk h with the intermediation of parts e, i, k, I, r, q, o, p, m and a belt x stretched between ρ and iti. In the points in time now, in which the coil y has reached the desired thickness, already occur not shown but _n means known in activity which s couple the shaft with a driving part. As a result, the cam disk f is rotated, as a result of which the roller ν moves up from the straight part of the disk t to the concentric part thereof, which causes the rail to be displaced forwards and the rocker to swing out from the position in FIG. 3 into the position in Fig. 4 has the consequence. As a result, the belt pulleys m and ρ have been brought closer to one another, as a result of which the belt χ placed over these two pulleys has become slack and the drive of the winding spindle has been interrupted. This now remains interrupted during the time during which the roller ν rolls on the concentric part of the cam disk, during which time the displacement of the last produced coil by the known stripping device, not shown, has to take place. After the latter has taken place, the roller ν moves from the concentric part of the cam disk down into the position shown in FIG. 3, which takes place by moving the rail back into its initial position. When the rail is moved back, the rocker ^1, due to its excess weight, also moves back into its initial position, in which the belt is tensioned again and, as a result, the winding spindle is driven.

The fact that now the drive of the winding spindle with the winding machine described above takes place without the use of a clutch using a belt drive the advantages mentioned at the beginning are achieved. The transfer of the rotary motion to the Winding spindle is perfectly safe by the excess weight of the rocker and the

Rotational movement of the gears q, r in the sense of the arrows indicated in FIG. 3 cause an automatic tensioning of the belt.

Claims (1)

Patent claim: Winding machine with belt drive for the winding spindle, characterized in that that after completion of a coil, one pulley automatically approaches the other and so comes to a standstill the winding spindle of the belt is automatically relaxed, whereupon after stripping the coil automatically removes this pulley from the other and so the belt is automatically tensioned to restart the spindle rotation. For this purpose ι sheet of drawings.