DE2831604A1 - Cable winding machine - has proximity switches to register material on spools to control rotary twisting speeds - Google Patents

Abstract

The speed control on the rotating parts is determined according to the quantity of material present on the unwinding spools. The system ensures that the twisting machine capacity is used to the full, without incurring a moving mass level which could cause damage. The rotary drive speed is increased so that the unwinding spools maintain a constant centrifugal force effect. The operating rotary speed is programme controlled, and there is a sensor to register the amt. of material on the spools. The sensor registers the max. amt. of material on a spool on each spool carrier unit. There is a sensor circuit for the sensors of several spool carrier units, so that the spool with the max. material on it can be selected as the datum point for the rotary speed control unit.

Description

"Stranding machine with speed control"

Stranding machine with speed control The invention relates to on a stranding machine whose pay-off spools rotate with the spool carriers.

Stranding machines are cage stranding machines with revolving spool carriers, for example known from US Pat. No. 1,866,272. With this stranding machine, the Speed and thus also the production speed of strands or ropes very limited at the top. This affects productivity and economy the production of strands, ropes or cables on such machines.

To limit the speed, inter alia. the number and the quality of the supply spools decisive. The operating personnel are instructed to use the machines only to be equipped with original bobbins as similar as possible, but there are imbalances cannot be ruled out due to an uneven mass distribution. Such encircling Imbalances lead to uneven loads and can damage bearings Overuse, which are the cause of unpredictable machine damage.

For the reasons mentioned, in the known stranding machines, in which the pay-off bobbins rotate with the bobbin, the inertia forces after limited above, in particular those in the second power in the calculation of the The speed of the incoming centrifugal forces is kept low.

Finally, US Pat. No. 2,171,993 discloses a stranding machine with stationary pay-off spools known, in which the withdrawal speed of the individual wires is changed by the winding device for the finished rope in such a way that the finished rope always has the same lay length.

The object of the invention is to provide the specified in a stranding machine Propose genus measures that allow the speed of work and productivity the machine is increased without doing the stress for certain maximum To increase inertia forces intended machine elements impermissibly.

For a stranding machine, the specified task becomes the one in the generic term of claim 1 specified type solved according to the characterizing part of this claim. The invention is based on the knowledge that the dimensioning of the bearings and the revolving bobbin for a certain speed and among the most unfavorable Prerequisites are made, that is, that as a calculation basis for the permissible Mass forces usually taken the mass of the prescribed full pay-off bobbins will. With constant working speed or rotational speed of the bobbin carriers however, the stress on the machine elements decreases in the course of the coil travel, since the bobbin fullness of the original bobbins becomes less. This reduction in the circumferential According to the invention, mass is a prerequisite for increasing the speed of rotation Coil carrier with the proviso that the inertia forces occurring in the course of the coil travel remain the same and the stress on the machine elements is the same as that on the basis of calculation The stress taken remains. As a result of this increase in speed, the output is of the machine is not permitted without individual machine elements and over that of the Calculation based on the dimension.

Such a control of the operating speed of the stranding machine leaves run through a program control, whereby as a variable, for example, the Bobbin fullness on the original bobbins as a representative size for the one available there inertial mass is used. The operating speed is determined according to such a program increases with decreasing bobbin fullness, taking into account that the Mass forces in the second power with the speed n and only linear with the mass gain weight. With a coil travel of several hours for today's usual The original spools used, however, results from the one made according to the invention Increasing the speed with decreasing bobbins is much better for the operator Machine utilization rate.

To practice the invention it is proposed that on the stranding machine suitable scanning devices are arranged, through which the decrease in the bobbin capacity the individual supply bobbins of a bobbin is continuously monitored. Since it is, however It is of fundamental importance that a permissible inertia force is never exceeded in order to avoid damage to bearings and machines, it is still suggested that that in each case a scanning device has the largest bobbin fullness of all the pay-off bobbins Detected coil support unit and that all scanning devices have a common Selection circuit is assigned by which that original coil determined which has the largest total bobbin fullness in order to use this measured value for the set the optimum operating speed via the program control provided.

The individual scanning devices are preferred as in the protective housing the stranding machine pivotably arranged proximity switches formed accordingly the set sensitivity when approaching the rotating supply bobbins emit a suitable signal which is fed into the selection circuit for the speed control device can be entered. Such proximity switches work, for example, on inductive or capacitive basis.

A simplification can be made for a stranding machine with several to achieve coil carriers arranged one behind the other in the axial direction, that all proximity switches for the coil carriers on one in the direction of the machine longitudinal axis trending. motor-driven shaft are attached cantilevered. These will when the shaft rotates so far in the direction of the revolving reel spools, until the drive shaft reaches a predetermined approximate value between the proximity switch and the coil with the largest number of coils is stopped. Due to the swivel angle reached, which is filled with the bobbins in the machine presented largest supply coil is related, the operating speed of the Stranding machine discontinued. If the bobbin filling is reduced further, the shaft will Turn slowly further with the proximity switches and according to the filling level the still most filled original coil tracked.

At the same time, the operating speed is set via the program control so increased that the permissible stress on the machine elements for no bobbin is exceeded by the mass forces.

The invention will now be based on only one embodiment Illustrative drawing explained in more detail.

It shows: FIG. 1 a schematic representation of a stranding machine with several bobbin units arranged one behind the other in the machine axis and a device for measuring the coil full; Fig. 2 is a plan view of two Adjacent coil support units of FIG. 1; Fig. 3 is a section through a coil carrier unit with the associated measuring device for the degree of filling 4 shows a corresponding section through the coil carrier unit with a view of the angularly offset pay-off bobbins of the neighboring bobbin unit.

Fig. 1 shows a stranding machine with five axially one behind the other the machine shaft 1 mounted coil support units 2, in each of which, for example three pay-off bobbins 3 parallel to each other and rotatable coaxially to the machine shaft 1 are stored. A strand of heart 4 is attached to one end of the stranding machine stored supply reel 5 tangentially withdrawn and through the hollow machine shaft 1 to the stranding head 6, where the individual. withdrawn from the reels 3 Wires 7 in layers and, for example, with the opposite direction of lay around the Strand of heart 4 to be beaten around.

The stranding machine is driven by the main drive motor 8 via a coupling 9, transmission 10 and countershaft 11 driven.

The countershaft 11 is mounted in the machine frame 12 and drives the stranding machine shaft on the outer wire guide sleeve carrying a toothed or sprocket 13 141 via a chain or a toothed belt 15. The wire guide sleeves 14, on which the coil support units 2 are attached, are rotationally fixed to the machine shaft 1 connected. A gear 16 is also arranged on the outer wire guide sleeve 141, through which, via a toothed belt 17, an angular gear 18 of a trigger mechanism 19 is driven, darch which the substantially finished cord 20 from the stranding head 6 is deducted. A station known per se for calming the cord, i. E. to eliminate elastic deformations that break the cord into its individual wires or Would let strands jump open, closes the take-off mechanism 19, which consists of a godet duo exists, on. This cable calming station is not shown in the drawing, since it is not essential to the invention; there is also a turning unit for the cord 20 is not shown. The cord 20 is finally taken up by a winder recorded from the winding shaft 22 driven by the motor 21 for recording a flange coil 23 and a suitable traversing device 24, which is drivingly coupled to the winding shaft 22. Fig. 1 also shows that the coil support units shown in more detail in Fig. 2 2metric to the bearing point 121 are arranged in pairs on the two ends of the wire guide sleeve 14. To 2 to 4, each bobbin support unit 2 has bobbin axes 25 for three pay-off bobbins 3 provided. For reasons of symmetry, the coil axes 25 are on an equilateral one Arranged in a triangle or a regular polygon. They are lockable and can after they have been unlocked axially pulled out to the processed Ab lau Take out the bobbin cores and the bobbin unit 2 with new original bobbins 3 to be fitted.

Each coil support unit 2 consists of one closely spaced from of the bearing point 121 in a rotationally fixed manner via the wire guide sleeve 14 with the stranding machine shaft 1 connected bearing washer 26 and a spaced-apart counter-bearing washer 27- The bearing washer 26 and the counter-bearing washer 27 are distributed around the circumference End bearings 28 and bores 29 assigned to them for the two-sided storage of the reel axles 25 according to the number of reel spools.

The coil support units 2 according to FIG. 2 are angularly offset from one another (Fig. 4), so that the adjacent counter-bearing disks 27 in the example shown by an amount of about 60 ° on the circumference to each other angularly offset holes 29 for have the storage of the coil axes 25. The counter bearing disks 27 point to this Recesses 30 on the circumference of the disc. These recesses 30 are coaxial too the end pieces 31 of the coil axles 25 arranged so that the coil axles 25 at a re-equipping of a coil support unit 2 axially approximately up to the flanges 32 of the pay-off bobbins 3 of the adjacent bobbin carrier unit 2 are pushed out can. As a result of this constructive hatred, 27 the coil support units 2 required only a relatively small distance, whereby the Overall length of the stranding machine shortened can be.

To secure the coil axes 25, the end pieces 31 have an annular groove 33, in which an eccentrically mounted locking washer 34 or a corresponding one Pin engages and held there by the centrifugal force acting during operation will.

As can also be seen from FIG. 2, the coil axes 25 are axially parallel arranged to the stranding machine shaft 1 and the template material is tangential over one wire guide roller 35 each withdrawn to each other, shown in Fig. 3 Deflection roller 36 guided and through the wire guide bore 37 in the wire guide sleeve 14 to be guided axially parallel to the stranding machine shaft 1 to the stranding head 6.

The wire guide rollers 35 are at the end of dancer arms 38 for control the wire tension is freely rotatable, the dancer arms 38 are each on the bearing washer 26 pivotally attached and run around with the bearing washer. You are by feathers 39 adjustable so that the wire guide rollers 35 at the nominal wire unwinding tension point radially outwards and in the event of voltage changes and / or fluctuations wire brakes known per se, preferably loop brakes such as cable link brakes 40 act, which slow down the pay-off bobbins 3 to a greater or lesser extent.

Axially parallel to the stranding machine shaft 1 is a in the bearings 41 common drive shaft 42 with several scanning devices 43 mounted. By the scanning devices, the largest actual value of the bobbin fullness to be taken into account of the pay-off bobbins 3 of a bobbin unit 2 are determined. The drive shaft 42 is by a servomotor 44 and a gear 45 or the like.

driven. The scanning devices are on the drive shaft 42 43, which are designed as proximity switches, such clamped, that each coil support unit 2 is assigned an actual value transmitter. All proximity switches align with each other and have such a distance that they encircle the dancing arms 38 do not hinder.

When operating the stranding machine, in which the coil carrier 2 and the Pay-off bobbins 3 are driven by the stranding machine shaft 1 and the wires 7 are processed by the pay-off spools 3 in order to produce a wire cord 20, the shaft 42 with the scanning devices 43 is driven by the servomotor 44. In this case, the scanning devices are moved together in the direction of the revolving bobbin units 2 pivoted towards. As soon as the first proximity switch emits a signal that indicates 1 that the set critical distance between one of the actual value transmitter and one the reel coils 3 is reached, the servomotor 44 receives a control pulse due to the further rotation of the shaft 42 is interrupted. In a selectable time cycle an actual value-setpoint comparison is now carried out and the proximity switch is activated Further rotation of the drive shaft 42 tracked in such a way that the distance to the pay-off reel 3 remains constant with the highest degree of filling. With increasing maturity of the stranding machine the shaft 42 with the proximity switches opposite the starting position twisted and the Ab spools are processed more and more, with the mass of the presented wire 7 decreases. Depending on the determined angle of rotation a between the starting position of the proximity switch a and the position in which the Signal was caused, is at the same time via a program control not shown in detail the machine speed increased so that the maximum occurring inertia forces in the remain essentially constant.

In the present version with on a common drive shaft 42 aligned sensing devices 43 and more Bobbin units 2, an electronic selection circuit is not required as the selection of a Control pulse for the servomotor 44 automatically by that proximity switch is hit, the one on the payoff bobbin 3 with the largest bobbin fullness except for one selectable critical distance approaches at which the control command takes place.

Claims (10)

Claims 1. Stranding machine whose pay-off bobbins with the bobbin carriers revolve, characterized in that the drive speed of the stranding machine in Depending on the decreasing bobbin fullness is continuously increased. 2. Stranding machine according to claim 1, characterized in that the The drive speed is increased in such a way that the centrifugal forces acting on the pay-off bobbins (3) remain essentially constant. 3. Stranding machine according to claim 1 or claim 2, characterized in that that the operating speed is program-controlled. 4. Stranding machine according to claim 1 or claim 2, characterized in 1 that the drive speed is detected by the scanning devices (43) is controlled. 5. Stranding machine according to claim 4, characterized in that the Scanning device (43) the largest bobbins fill the pay-off bobbins (3) one at a time Coil carrier unit (2) detected. 6. stranding machine according to claim 5, characterized in that the Scanning devices (43) of all coil support units (2) a selection circuit is assigned, through which the largest bobbin filling of all pay-off bobbins (3) can be selected and entered into the speed control device. 7. Stranding machine according to one or more of claims 4 to 6, characterized in that the scanning device (43) as in the housing of the device pivotably arranged proximity switch is formed. 8. Stranding machine according to claim 5 to 7, characterized in that that all the scanning devices (43) for the coil carrier (2) on one for Stranding machine shaft (1) axially parallel, motor-driven shaft (42) attached cantilevered and by rotating the shaft (42) so far in the direction of revolving pay-off bobbins (3) can be pivoted until the drive shaft (42) is reached a predetermined approximate value between one of the scanning devices (43) and the pay-off bobbin (3) with the largest bobbin filling can be stopped. 9. Stranding machine according to claim 8, characterized in that the on the shaft (42) attached scanning devices (43) with the reels (3) pursued the hatred be that with a set-actual value comparison between none of the scanning devices (43) and all of the delivery coils (3) specifiable approximate value is fallen below. 10. Stranding machine according to claims 8 and 9, characterized in that that over the winding cycle the angle of rotation (X) of the shaft (42) with respect to a starting position it is detected that the measured value can be input to a programmable control device and that from this control device the drive (8,21) of the stranding machine shaft (1), the winding shaft (22) and, if necessary, the trigger mechanism (19) controllable list.