DE2419600C3 - Central spinner with monitoring of the spinning material flow - Google Patents

Description

Coupling of the transducers to the transducers thus takes place above the air gap, which also gives the possibility of the actual monitoring device to be arranged in a stationary manner. This in turn enables a structurally simple and rotationally symmetrical one Structure of the central spinner, with which the adaptation to high speeds are guaranteed

In the structural design of the central spinner, it is expedient to proceed in such a way that both the Spinning pot or the spinning plate as well as the spinning material is each arranged on a hollow shaft which is connected to one end carries the wheel-shaped encoder. It makes sense to use the hollow shaft of the spinning pot or to store the spinning plate on the hollow shaft of the spinning material carrier. This creates a compact, rotationally symmetrical ι s metric construction of the spinner ensured

In the case of the central spinner, parts of the monitoring device that are firmly connected to the central spinner are used, i.e. the wheel-shaped measuring transducers, only to be able to determine the measurement data required for monitoring. The real one Determination of the data and the evaluation takes place with the help of a separate from the central spinner Stationary arranged monitoring device. In the interaction between the respective transducers and transducers generated electrical pulses, the with the two Pulse sequences received from measuring transducers / measured value pickups are compared with one another. If the monitoring device is dimensioned such that the same speed of rotation of the spinning pot or spinning plate and the spinning material carrier result in the same pulse sequences, the monitoring device would only respond if there is an actual match between the two pulses because in 3s normal operating condition of the spinning pot or spinning plate and the spinning material carrier different speeds exhibit.

The monitoring of the central spinner provided within the scope of the invention can be carried out both optically as well as by magnetic means. In the case of optical monitoring, it is advisable to use the train wheel-shaped transducers as perforated or toothed disks, which optical transducers with are assigned to an optical electrical converter. It is recommended for monitoring on a magnetic basis to train the wheel-shaped transducers as gears made of magnetic material, which are magnetic Meßwertauf subscribers with magnetic-to-electrical transducers, such as field plate sensors assigned are. In this case, a particularly useful construction can be seen when the teeth of the Measuring wheels are arranged radially. Then the gear-shaped measuring transducer assigned to the spinning pot or spinning plate can simultaneously act as the drive wheel of the spinner serve.

The structural design of the new central spinner can be further simplified by the fact that the wheel-shaped transducers in the axial direction of the spinner are arranged side by side. Regardless of this arrangement, it is also recommended that the wheel-shaped transducers have the same number of holes or the same number of teeth.

The structural design of the transducers and transducers of the central spinner must go through a corresponding evaluation device can be added. In a further development of the invention is therefore provided that the transducers with a electronic expander are connected, with a comparison of the defi transducers supplied electrical pulse sequences takes place. Such an evaluation device can be used with the help known electronic components and corresponding circuits aufbauea

An embodiment of the decentralized spinners including the associated monitoring device is shown in Fig. 1 in the form of a block diagram, while in Fig.2 within the scope of the invention provided constructive measures are shown on the central spinner.

Fig. 1 shows the central spinner 10, with the thread-like spun material 22 on a basic bundle 1 of a Communication cable is spun. The central spinner, which rotates on a guide tube 28 is stored, consists essentially of a spinning plate H, which carries a knock-off device 12 and is connected to a first measuring transducer 14 as well as from a spinning material carrier 20 on which a spinning material supply 21 is arranged and via an unspecified one The shaft is connected to a second encoder 26 The Spirngul carrier 20 and the spinning plate 11 are over a slip brake, not shown, connected to one another, for example via a hysteresis brake or a slip clutch. Because through the Spinning process is constantly withdrawn spinning material from the spinning stock 21, result in normal Operating state of the central spinner different speeds between the spinning plate 11 and the Spinning material carrier 20 and thus between the first measuring transducer 14 and associated with the spinning plate 11 the second measuring transducer assigned to the spinning material carrier 20. Both measuring transducers are gearwheels consist of a magnetic material, for example steel, and act with two radially These transducers are fixedly arranged transducers 31 and 32 together. These transducers are permanent magnets with Field plate elements are coupled by the teeth of the Transducers 14 and 26 are the magnetic flux in the permanent magnets of transducers 31 and 32 constantly changed in pulse form so that the transducers 31 and 32 according to the number of teeth Encoders 14 and 26 and emit pulse trains according to the speed of these encoders. the Pulses of these pulse trains are counted in the counters 33 and 34, the decoders 35 and 36 are downstream. Depending on the particular circuit the encoder is after a certain Number of pulses from both the decoder 35 and the decoder 36 a signal on one Gate circuit 37 given in which the two signals are compared with one another. In this comparison is taken into account via the decoder 36 that formed between the two as gear wheels Encoders 14 and 26 can have a phase shift of up to a tooth width.

A match between the signals supplied by the two decoders 35 and 36 means that the Spinning plate 11 of the central spinner and the spinning material carrier 20 rotate at the same speed, d. i.e. that the Central spinner is not working properly. In this case, a signal from the gate circuit 37 is on Timing element 38 given, which extends the signal supplied by the gate circuit to now have a relay or to be able to control a contactor with which the

The spinning process is interrupted or an optical or acoustic signal device is triggered. Normally the signals supplied by the decoders 35 and 36 do not match, so that from the gate circuit 37 no signal is given to the timer 38.

The monitoring process takes place continuously in a rhythm that is determined by the dimensioning of the decoder 35 and 36 is determined After a certain number of pulses has been stored in the counters 33 and 34 this counter is reset to zero via a timer 39, this timer simultaneously causing a delay the reset causes the reset only after the comparison of the values from decoders 35 and 36 to perform delivered signals in the gate circuit 37.

Fig.2 shows the structural design of the central spinner to. The central spinner exists initially from the spinning plate 11, which carries the lantern-shaped chopping device 12 and on a hollow shaft 13 is arranged with the hollow shaft 13 of the first encoder 14 is connected, which is a Drive wheel acts With the spinning plate 11, a ring 15 is also connected, in which a Permanent magnet 16 is arranged a hysteresis brake. This permanent magnet acts with a disk 25 magnetic material together, which is attached to the spinning material carrier 20 is on this spinning material carrier the spinning material supply 21 arranged from which the thread-like spinning material 22 with the knock-off device 12 is knocked off. The spinning material carrier 20 is mounted on a hollow shaft 23 which is attached to the Spinngutvorrats 21 facing away from the end of the second

ίο sensor 26 carries. This transducer is next to the first transducers 14, namely the drive wheel of the spinning plate 11 is arranged

The hollow shaft 13 of the spinning plate 11 is via the two bearings 24 and 24 'on the hollow shaft 23 of the Spinngutträgers 20 stored The hollow shaft 23 in turn is with the help of two bearings 27 and 27 'on the Guide tube 28 (through which the material to be spun is passed) stored

The measuring transducer acts with the measuring transducer arranged in a stationary evaluation unit 31, the measuring transducer 14 with the measured value also arranged in the evaluation unit 30 takers 32 together.

For this purpose 2 sheets of drawings

Claims (10)

Patent claims: 1. Central spinner with monitoring of the spinning material flow, consisting of a rotating spinning plate connected to the spinner drive or Spin pot and from one connected to the spin pot or the spinning plate via a slip brake Spinning material carrier in which both the spin pot or spinning plate and the Spinngutträger parts of a monitoring device are rigidly coupled, with which the speed difference between the spinning pot or spinning plate and the spinning material carrier is monitored, characterized in that that both with the spinning pot or Spinnte'ler (11) connected part of the Monitoring device as well as the part of the monitoring device connected to the spinning material carrier (20) as wheel-shaped measuring transducers (14, 26) arranged concentrically to the spinner axis are formed, each of which is a stationary relative to the spinner axis transducer (31,32) is assigned 2. Central spinner according to claim 1, characterized in that both the spinning pot or The spinning plate (U) and the spinning material carrier (20) are each arranged on a hollow shaft (13, 23), which carries the wheel-shaped encoder (14, 26) at its end 3. Central spinner according to claim 2, characterized in that the hollow shaft (13) of the spin pot or spinning plate (U) is mounted on the hollow shaft (23) of the spinning material carrier (20) 4. central spinner according to one of claims 1 to 3, characterized in that the wheel-shaped Encoders are designed as perforated or toothed disks, which optical transducers with optical-electrical Converters are assigned. 5. Central spinner according to one of claims 1 to 3, characterized in that the wheel-shaped transducers (14, 26) are magnetic gears Material are formed, which magnetic transducers (31, 32) with magnetic-electrical Converters are assigned. 6. central spinner according to claim 5, characterized in that the teeth of the measuring transducer (14, 26) are arranged radially. 7. central spinner according to claim 5 or 6, characterized in that the spinning pot or Spinning plate (11) assigned wheel-shaped measuring transducer (14) at the same time as a drive wheel for the spinning plate (11) is used 8. central spinner according to one of claims 4 to 7, characterized in that the wheel-shaped transducers (14, 26) in the axial direction of the spinner are arranged side by side. 9. Central spinner according to one of claims 4 to 8, characterized in that the wheel-shaped transducers (14, 26) have the same number of holes or the same Have numbers of teeth. &O 10. Central spinner according to one of claims 1 to 9, characterized in that the transducers (31, 32) have an electronic evaluation device (30) to compare the electrical pulse trains delivered by the transducers are connected. In order to be able to control the proper operation of spinners, with which band or fedenjönniges spinning maierial is applied to an elongated material, it is customary to monitor the flow of the spinning material in such a way that an alarm device or a triggering device to stop if the spinning material breaks of the clamping process is actuated. Such spinners with monitoring of the spinning material flow are particularly common in the production of electrical cables, for example when wrapping electrical conductors, cores or groups of cores (DT-PS820176 and 857 977, DT-AS1041 556). ^ - 'A thread spinner with monitoring for thread breakage is known, with which the previous monitoring devices working with mechanically operated contacts are improved. In this thread spinner, an element is rigidly connected to the thread spool, which interacts without contact with an element arranged on the spinner a gear wheel is rigidly connected to the thread spool and is opposed by a permanent magnet system arranged on the spinner (DT-AS 1113 73). Such a monitoring device cannot yet be regarded as the optimal solution to the problem at hand, because slip rings for electrically coupling the monitoring element connected to the spinner to the evaluation device are required to operate this monitoring device, and because this monitoring element represents an imbalance that can only be compensated for by appropriate counterweights can. In particular at high spinner speeds, such measures are to be regarded as disadvantageous because of the centrifugal forces that occur here. The invention is based on the object of central spinning machines with monitoring of the spinning material flow to arrange the actual monitoring device mechanically separated from the central feeder and This means that the monitoring device works reliably even at high speeds of the central spinner to guarantee. To solve this problem, the invention is based on a central spinner, which consists of one with the Spinner drive connected, revolving spinning plate or spinning pot and one with the spinning pot or the Spinning plate is connected via a slip brake spinning material carrier and in which both with the Spinning pot or spinning plate and the spinning material carrier parts of a monitoring device are rigidly coupled with which the speed difference between the spinning machine or spinning pot and the spinning material carrier is monitored will. According to the invention it is provided that sowoh! the one with the spinning pot or spinning plate connected part of the monitoring device as aucli that part of the monitoring device connected to the spinning material carrier is in the form of a wheel. concentric Encoders arranged on the axis of the spinner are formed, each of which is a fixed relative to the spinning axis transducer assigned. In the case of a central spinner designed in this way, the one on which the invention is based is corresponding Task definition of the actual monitoring device, which is connected to the transducers, mechanically completely separated from the central spinner. the