DE566218C - Device for winding up thread-like material - Google Patents

Description

Device for winding up thread-like material The invention relates to a change to winding devices for machines for wire, rope and cable production, in which the manufactured goods of the winding drum via a take-off disk or a similar device is supplied, which drives the winding drum is inevitably coupled. It is essential that the tension of the to be wound Good always has the same size, regardless of your respective winding diameter and the respective speed and speed change of the winding drum. For the drive the take-up drum are usually slipping clutches or differential gears used with brake. With these known means, it is true that at constant Speed of the machine to achieve winding under constant tension; against it Until now, these devices have failed in the event of changes in speed, especially in the case of rapid Changes in speed as they occur when starting and stopping the machine. The cause of this failure is that the inertia of the take-up drum and the other moving parts of the device additional when the speed changes Deliver torques that are superimposed on the drive or braking torque. The consequence it is that when the machine starts up, the tension in the goods to be wound up reduced, which often leads to malfunctions in the machine, on the other hand, when it comes to a standstill the machine, the tension in the material to be wound increases sharply, which in particular with heavy drums and a short run-out time, the goods are easily damaged. These Naturally, there is a particular risk when winding sensitive goods, for example from telephone wires.

The invention relates to such winding devices at which the drive of the winding drum through a differential gear with brake he follows. The -new is that the moment of inertia of the brake disc, if necessary using additional masses, is balanced in such a way that for all the values of the winding diameter occurring during operation are approximately equal to the twist (Angular momentum equilibrium) exists between the winding drum and the brake disc. By this measure is achieved that the winding tension even with speed changes remains the same size all the time.

The essence of the invention will be explained in more detail using the example shown in the drawing. It denotes a thread (wire, rope or cable) which is fed to the drum c via the take-off disk b. The take-off disk b and the take-up drum c are driven by a common shaft d. The take-off disk b is directly coupled to the drive shaft d via a worm gear or gear train e. The winding drum e is driven from the shaft d via the differential gear f. The shaft k of the winding drum c is connected to this differential gear on one side via the housing shaft g of the differential gear and the gears h and i. The housing shaft L on the opposite side of the differential gear carries a brake disk on which a braking torque is generated by a brake not shown in the drawing. Due to the nature of the differential gear, this braking torque results in an equally large torque in the opposite housing shaft g, which is transmitted to the take-up drum c by the gears lz and i and causes tensile stress in the thread a. By appropriate braking of the brake disk nt, known per se, it can be achieved that the tension of the thread a remains constant regardless of the winding diameter while the speed of the machine remains constant. However, this state of equilibrium is disturbed by the inertia forces of the take-up drum and the brake disc that occur when the speed changes. The possibility of compensating for these mass influences arises on the basis of the following consideration: Let It denote the moment of inertia and itt denote the speed of the winding drum c (both related to the housing shaft g of the differential gear) and Ip and zt "the same values for the Brake disk in (related to the housing shaft Z of the differential gear). For the equilibrium of the motion quantities of the rotation during acceleration and deceleration, the following relationship applies: It. Zzt = Ip . Zzp. (I) Furthermore, for the speeds i1 = Ytt + u ' r, (2) if it means twice the speed of the housing f of the differential gear. This speed zt is proportional to the speed of the take-off disk b and thus the feed speed of the thread a.

When the speed of the drive shaft changes and thus the feed speed of thread a is the change in speed of the take-up drum corresponding to this change only guaranteed if the winding drum and brake disc are always on the same level Twist are adjusted. This adjustment is made more difficult by the fact that -during of the winding process, the moment of inertia It of the winding drum is constantly increased and as a result of the change in the winding diameter with the thread feed speed remaining the same the speed of the winding drum decreases, which is a constant speed The result is an increase in the speed n of the brake disc by the same amount. If one takes now at constant speed n and consequently constant thread speed two different values of the winding diameter of the drum c result from the basic equations (r) and (2) for the assumed values of the winding diameter corresponding drum speeds ztt, and nt = as well as the associated moment of inertia 1t1 and It: the following equations.

Ia, # nt, = Ip # (st- "t,) ,. (3) 1t =, ntz = Ip (3z-nt =) (4) From these equations it follows Ip # = Ik 'nt, -4 zat, (5) Equation (5) contains only one unknown Ip, which is calculated to be For the value I found from this equation, for a given thread feed speed, a very specific value n belongs, if equation (2) is to be fulfilled. This value it has not yet been set. The determination of this value is still necessary, since it determines the speed np of the balancing mass if the speed ztt is known according to equation (2). The speed n results from equations (z) and (2) on the basis of a simple conversion to In this equation one can substitute rt and zzt or It_ and ut for lt and ttt to calculate it.

For the value Ip calculated above, the preconditions made apply Twist equilibrium between the winding drum c and the brake disc in. For the two assumed values of the winding diameter. For the other values of the Winding diameter of the drum c, the equilibrium condition is only approximately fulfilled, but you have it in your hand by appropriately accepting the basis of the calculation laid values of the winding diameter the degree of approximation for the practical To push needs far enough. It is advisable to choose one each value the winding diameter of the drum c for the state shortly after the start and shortly before Completion of the drum filling.

The above derivation for the condition of the twist equilibrium applies not only to constant speed ii, but also when this speed and thus the feed speed of the thread changes. In this case, namely, the speeds of the take-up drum c and the brake disc change in due to the equality of their movement quantities in the same ratio. However, since the movement variables are in turn proportional to the relevant speeds, it remains with every change in the speed. and thus the thread feed speed exist the existing twist equilibrium. The inertia forces of the winding drum c and the brake disk na therefore have no influence on the tension of the thread a to be wound when the movement parameters are compared according to the invention.

The balancing of the moment of inertia in the brake disk which is necessary for the production of the swirl equilibrium according to the invention. can be done in a number of ways. For this purpose, the drawing shows an additional mass p made up of individual disks, the shaft o of which is coupled to the brake disk in, via the enlarging transmission gear r, s. Since the compensating flywheel p runs at a higher speed than the brake disk ni, a relatively small additional mass is sufficient. By changing the wheels r and s and by removing or adding disks p, the moment of inertia of the balancing mass can be regulated accordingly. The moment of inertia of the balancing masses can also be changed by radial adjustment of the balancing masses. In a modification of the embodiment shown in the drawing, the brake disc itself can also be partially or completely used as a balancing mass and, if necessary, driven with a translation. To facilitate the adjustment, in particular to adapt to different drum diameters and different weights of the winding material, the other transmission ratios of the device can be made adjustable using change gears or continuously variable gears in addition to the transmission ratio between the housing shaft l and the balancing mass p.

Claims (1)

PATENT CLAIMS: i. Device for winding up thread-like material (Wires, ropes, cables, etc.) on drums, with the thread-like material over a take-off disk or a similar one with your drive of the winding drum inevitably coupled device is fed to the take-up drum and the regulation of the Thread tension through a differential gear built into the drive of the take-up drum with brake takes place in such a way that one side of the differential gear indirectly or directly drives the take-up drum and the other side of the differential is coupled to a brake disc, characterized in that means on the Centrifugal masses arranged on the brake side of the differential gear (p) the twist (angular momentum) the winding routine (c) and the twist of the brake disc (tii) completely or almost completely are matched. Device according to claim i, characterized in that the balance mass (p) in order to save weight at a higher speed than the brake disc (tii) runs. 3. Apparatus according to claim i or a, characterized in that the Schwunginoinent the balancing mass (p) is adjustable. 4 .. Device according to claim i to 3, characterized characterized in that the drive of the differential housing (f), the winding drum (c) and the brake disc (in) or balancing mass (p) completely or partially over Change gears or continuously variable transmission takes place.