DE2534120C3 - Waveguide winding machine - Google Patents

Description

The invention relates to a waveguide winding machine for continuously winding circular, Waveguides transmitting electromagnetic waves

Ij

ius metal wire The machine has a wire stripper, a wire winding device and a tape winding ; device, which are arranged in this order in the direction of the Uohlleitvorschubes, wherein the Wire winding device has a fixed mandrel and a rotor outside the dome

On this machine, endless circular waveguides can be made from an insulated metal wire, e.g. from Manufacture enamelled copper wire by winding this wire to form a cylindrical layer of adjacent turns.

If a round waveguide for the transmission of the TEoi frequency has the geometry of a perfect circle, then the propagation of the TE ₀ 1 frequency is not disturbed, provided that the waveguide wall consists of a homogeneous conductor .

One of the properties interessantesten ^ ines such a waveguide is its low attenuation. The larger the diameter of the waveguide and the higher the frequency, the lower the line attenuation. Unfortunately, the TEoi frequency is poorly compatible with the TMu frequency, with imperfections in the circular geometry leading to a coupling between the two frequencies and consequently to a higher one; ₅ cushioning.

The object of the invention is to create a waveguide winding machine for producing circular waveguides from thin wire with Loher dimensional accuracy. _Yo

Such machines that make a wire by continuously winding it into contiguous turns shapes have already become known on various occasions.

In a first group of known machines (British Patent 8 87 063) the wire is wound on a rotating mandrel. The metal wire folds up on the mandrel to form contiguous turns, and the resulting winding remains on the mandrel only as long as is necessary to stiffen it and protect it by a covering or outer clothing. The wire turns are held back by one or more rotatable rollers, the task of which is to determine the position of the first turn of the winding along the dome. At a point where the winding has reached a length sufficient to be stiffened by the hardening of an applied hardenable impregnating agent or an outer protective sheath, the mandrel diameter is reduced, e.g. B. by a conical taper or a Absat? or by cooling the dome without cooling the winding at the same time. If such a machine is equipped with a rotating mandrel, then endless, wound circular waveguides can be produced,

Such machines are only suitable for a low working speed, because a far protruding rotating mandrel shows imbalances, but on the other hand a large mandrel length is required, in order to achieve a hardening of the waveguide on the mandrel at high working speed.

In another known group of machines (French patent specification 16 04 891) the mandrel is either fixed or rotatable and the wire is wound onto the mandrel by means of a rotating winding device which carries the wire spool. On the one hand, these machines are poorly suited to continuous operation because the machine has to be stopped to change the wire spool when it is empty; changes

It has now been observed that the wire must be wound onto the mandrel with constant tension if one wants to obtain a completely regular winding with adjacent turns. Now the wire tension at the winding point depends on the wire tension at the unwinding point of the wire spool and on the axial thrust of the winding head . This thrust in turn depends on the static friction forces of the wire on the mandrel .

The invention is based on the object of a waveguide winding machine of the type described above Kind to provide that allows the highest possible working speed and still a good dimensional accuracy the waveguide ensures.

This task is solved by the fact that at the end of the feed length, behind the tape winding device (IH) a roller brake is arranged that the rotor of the wire winding device has an inner, to the rotor axis has inclined and the wire through channel, which has a cone with a center on the Wire tensioner describes, as well as one, the wire from the exit of the channel to the winding to be made leading pulley and that a magnetic coupling is provided, which holds the mandrel without the rotation to obstruct the wire.

The axial thrust of the end winding is relatively independent of these static friction forces, if a roller brake is arranged coaxially to and close to the winding head, which both the waveguide lengthways drives as well as keeps the section between the winding head and the roller brake under tension. This one Voltage depends on the length of this waveguide section, the end winding is movably arranged and a control device is provided which keeps the distance between the winding head and the roller brake constant.

The wave guide ^r winding machine according to the invention provides an arranged behind a lying in the machine axis wire tensioner and working on a mandrel before winding head which is longitudinally displaceable under the action of the return coil to some extent. Furthermore, means are provided to keep a certain winding length under a compressive pretension, the position of the winding head influencing these means.

The magnetic coupling can consist of a frustoconical The middle part, which is connected to the mandrel, and one with part of the Machine frame connected outer part, with an air gap between the middle and outer part the passage of the wire from the wire tensioner to the channel in the rotor.

Furthermore, the winding device and the tape winding device can be provided with electric drive motors to each of which a tachometer generator is coupled. Furthermore, a control system is provided in which a Speed control loop of the winding device whose speed tracks a reference / speed, and a speed control loop the tape winding device whose speed tracks the speed of the winding device.

The tape winding device can be a rotor mounted coaxially to the rotor of the wire winding device have such that the winding of the tapes takes place as close as possible to the winding of the wire.

The speed of the roller brake in a speed control loop can correspond to the speed of the wire winding device be trackable that on the one hand the length of the waveguide piece let through by the roller brake is equal to the wound length and that, on the other hand, the waveguide piece between the wire winding device and the roller brake is kept under pressure.

In the case of a waveguide winding machine with a roller brake with several rollers, the rollers be arranged evenly distributed over the circumference of the waveguide and each by an electric motor are driven, the roller axis running perpendicular to the feed direction of the waveguide.

The electric motors of the rollers of the roller brake can be connected in series.

Tacho generators can be coupled to the electric motors, which send a signal via the middle Supply speed of the rollers.

In a waveguide winding machine with a roller brake with four rollers, two lower rollers can be inserted in be arranged in a fixed position, and two upper rollers can rest elastically against the waveguide, wherein the axes of rotation of the rollers are inclined by 45 ° to the horizontal.

De ^ the speed of the wire winding device tracked The speed control loop of the roller brake can contain a correction loop that adjusts the wound and let through waveguide length takes over as well as the generation of the compressive bias of the Waveguide piece between winding device and roller brake.

The rotor of the wire winding device can also carry a co-rotating winding head, which over Presses compression springs against the wire of the waveguide section between the winding device and the roller brake. A displacement transducer acting on the winding head supplies an electrical control signal for the compressive tension to the correction circuit of the speed control circuit of the roller brake.

The two voltage signals entered into the speed control loop of the roller brake for the speed of the Wire winding device and for the position of the winding head can under normal operating conditions in Ratio 10: 1 stand.

The speed control loop for the tape winding device can also have a fine correction device, by means of which the pre-tensioning of the tapes, which depends on the diameter of the tape reels, can be manually corrected is

In a modification, the tape winding device can be driven by a stepping motor, whose numerical control depends on the one hand on a pulse generator, one on the speed the wire winding device provides dependent pulse frequency, and on the other hand of a pulse generator for manual correction.

An embodiment of the invention is shown in FIGS. 1 - 12 and is explained in more detail below described. It shows

F i g. 1 a waveguide winding machine in schematic Overall view and in partial section,

F i g. 2 a wire tensioner in a schematic representation.

3A, 3B and 3C show a wire winding device in schematic representation,

F i g. 4 the magnetic coupling of the winding device in cross section.

F i g. 5 shows the torque of the clutch in FIG. 5 in a diagram. 4 depending on the angle of rotation,

6 shows the tape winding device in a schematic Opinion,

F i g. 7 the roller brake in a schematic representation,

F i g. 8 is a diagram showing the force relationships on the waveguide section between the winding device and the roller brake,

ίο Fig.9 in a diagram the thrust of the Wire winding device depending on the length of the waveguide section between the wire winding device and roller brake,

10 is a circuit diagram of the speed control loop the wire winding device,

F i g. 11 is a circuit diagram of the speed control circuit of the tape winding device and

F i g. 12 is a circuit diagram of the speed control loop the feed device.

The continuously operating waveguide winding machine (Fig. 1) essentially has the following Subunits:

A wire tensioner I, which is arranged in the main machine axis,
a wire winding device 11, a tape winding device 111 and a roller brake IV.

The wire tensioner 1 (see also FIG. 2) has the task of providing the machine with insulated copper wire, e.g. B. enamelled copper wire to be fed under constant voltage. In the feed direction of the wire, the wire tensioner has a magazine 11, a wire guide 12, an adjustable roller 13, the horizontal axis 13a of which is located in a lever 14 which is pivotably mounted on an axis 14a connected to the machine frame. The lever with the roller 13 is pressed upwards by a compression spring 15 which can be adjusted with the aid of a knurled screw 151. The wire tensioner also has a stationary roller 16 which is connected to the machine frame via an axis 16a and is equipped with a magnetic powder brake 17 which is known per se and which is fed by a set current. Finally, the wire tensioner has an output wire guide 18, which is located in the main axis of the machine.The wire to be processed is clamped between the rollers 13 and 16 in such a way that, taking into account the moments and coefficients of friction that occur, none of the following ^:

Slipping of the wire is possible. The output voltage of the wire is determined by the braking torque Brake 17 regulates, which increases in direct proportion The brake feed current is

The wire winding device II (see also Fig. 3; and b) has the task of the wire on eini to wrap a cylindrical mandrel in superimposed turns.

It (F i g. 3a) comprises a mandrel 21 and a red 22, which is coaxial with the mandrel and about this rotatable is stored

The rotor has a channel 221 in a radial half-plane, which extends in the direction of the output wire filler tion 18 is inclined, as has already been stated, the geometric axis of the dome 21 Hegt Di

Near the end of the channel 221 facing away from the wire guide, the rotor carries a deflection roller 22Z over which the wire F runs before it is wound onto the mandrel 21. The wire F describes t

its leading a rotational cone coaxial to the mandrel with the tip 18.

The thorn stands firm, i. H. it is firmly connected to the machine frame in order to avoid the difficulties which a rotation of the waveguide would bring with it during its manufacture. The high rotational speeds required to manufacture continuous waveguides would otherwise result in relatively high rotational speeds of the tape winding device and the roller brake, which would lead to difficult problems.

For the reasons given, the mandrel 21 (FIG. 3a) should be firmly connected to a part 23 of the machine frame. However, the cone described by the wire requires that this part 23 has a cutout in the form of a truncated cone 231 .

A constructive solution to this problem is shown schematically in FIG. 3b. A part 23 ′ of the machine frame has a cylindrical inner surface in which the rotor 22 is mounted coaxially with the aid of roller bearings 223, 224. The rotor 22 in turn carries the mandrel 21 with the aid of roller bearings 213, 214. The mandrel 21 is held in its angular position with respect to the frame 23 'with the aid of a magnetic coupling 24 which is shown in axial section in FIG. 3b and in cross section in Fig. 3c.

This magnetic coupling 24, known per se, has a middle part 241 and an outer part 243, both of which are designed to be rotationally symmetrical about their common axis and are separated from one another by an air gap 245 of uniform thickness. The air gap has the basic shape of a truncated cone in order to allow the passage of the wire F describing a cone. In the embodiment shown in FIG. 3c, the coupling 24 is divided into six equal sectors (see also FIG. 4), each of which corresponds to a magnetic circuit, as indicated by the line provided with arrows. For example, one sector includes teeth 243a. 2436 of the clutch outer part, which are separated from one another by a permanent magnet 244a with the poles N. S , as well as teeth 241a, 2416 of the clutch middle part, which converge in an inner core 242. The teeth like 241a. 243a consist of magnetic material, and the volume remaining in the sector between the teeth is filled with non-magnetic material, the conical surfaces being smooth so that the wire passing through the air gap can slide through undisturbed.

A torque exerted on the mandrel is expressed by an angle of rotation Θ between the parts 241 and 243 of the coupling. This angle leads to a magnetic counter-torque Ce, which tries to keep the mandrel in equilibrium. The torque Ce depends on the angle of rotation θ according to the one in FIG. 5 given course. The maximum moment occurs at an angle θ «which corresponds to half the angular division of the coupling teeth. The torsional stiffness of the connection results from the gradient of the tangent at the origin to the curve Ce = / (8Jl This torsional stiffness and the inertia of the dome lead to a natural frequency of the dome, which is to be avoided in order to prevent resonance phenomena

For reasons given below, the rotor 22 of the wire winding device has a shoulder 225 of reduced diameter on its front part. On this paragraph a winding head 25 is mounted which is non-rotatably verbun with the rotor 22 with the aid of a connecting element, not shown . A wire passage channel 251 in this end winding is found in the extension of the aforementioned channel 221 in the rotor. The aforementioned deflection roller 222 is located as a deflection roller 252 on the end face of the winding head. The end winding is axially displaceable, as indicated by the double arrow in FIG. 3b is indicated, and has on its front side a protruding nose 253 with a screwed side surface, the pitch of which is equal to the diameter of the to

ίο winding wire is. This nose helps when winding the wire onto the mandrel and pushes each newly created turn behind the existing ones. The reaction force exerted on the winding head by the already wound waveguide acts against three compression springs 254 evenly distributed over the circumference of the winding copy, of which only two are shown in FIG. 3c. The path of the winding head is measured by a displacement encoder 255 , which z. B. consists of a straight potentiometer of high resolution, which is arranged axially and whose tap is carried by a rod also axially attached to the end winding. The path signal of the winding head 25 emitted by the position transmitter 255 is included in a control system which is described further below.

The rotor 22 of the wire winding device is driven by a motor 26 via a reduction gear 261, 262 . A tachometer generator 263 sits on the shaft of the motor 26, and its signal, the speed of the motor 26, is entered into the control system of the machine.

The tape winding device Ul (see also Fi g. 6) has the main task of the waveguide windings to the extent. in which they are wrapped and advance on the mandrel to fasten by tapes. The tape winding device has a rotor 31 which is mounted coaxially to the wire winding device II in part 23 ′ of the machine frame via roller bearings 311, 312. The rotor 31 carries two coils 32, 33 with the same adhesive tape R \, R2 for external protection of the waveguide. The diametrically opposed coils rotate on the body 31 on two inclined axes 32a. 33a. The inclination of the coils depends on the uniform width of the two belts. Each individual tape is wound in contiguous windings without a gap or overlap. The joints of the first tape are covered by the second tape, which is wound up shifted by half a tape width. The two coils 32.33 are provided with two magnetic powder brakes 34, 35 which generate a pretension for the winding of the tapes. Would men without special precautions this bias be variable with the Abwickelgrad or the remaining diameter of the coils. The preload is kept constant, however, by changing the supply current of the electromagnetic brakes depending on the number of unwinding revolutions of the reels. The brakes are supplied via slip rings such as 341, 342 and sliding contacts such as 343,344.

The rotor 31 of the tape winding device is driven by a motor 36 via a reduction gear 361,362 . On the shaft of the motor 36 there is a tachometer generator 363, whose signal, the speed of the motor 36, is used in the control system of the machine

The main task of the roller brake IV (see also FIG. 7) is on the waveguide section that has already been wound between her and the wire winding device to exert a counterforce equal to that of this waveguide piece of exerted pressure counteracts while the pressure in the waveguide part, which is on the roller brake «

has already passed, is practically saved. One of the main tasks of the roller brake is to enable the waveguide to advance as it arises. In addition, the roller brake serves to carry and center the mandrel, which would otherwise be overhung. The roller brake has a number of rollers evenly distributed around the outer circumference of the dome 21, which is covered by the waveguide G. The tangent to a roller at its point of contact with the waveguide runs in the direction of the surface line that is touched. There are normally four rollers 41-44. In this case, which is also shown as an example, the rollers are offset from one another by 90 ° and their axes are inclined by 45 ° to the horizontal. The two lower rollers have fixed positions, and the two upper rollers are pressed elastically against the waveguide in order to balance the four contact forces. This arrangement also proves to be most suitable for guiding and centering the dome.

If the four rollers were driven by a single motor it would be a mechanical differential between them necessary to make changes to the effective rolling radii with which the waveguide is driven to balance. To overcome the difficulties of such a mechanical differential avoid, the rollers are equipped with single motors 45 - 48, which are fed in series in order to act on them Way to form an electrical differential. If the contact pressure on the waveguide is reduced with a roller, then the role is accelerated, and this leads to a compensatory slowdown of the other roles.

The rollers are gimbaled and have rubber tires to prevent the active edges of the Pressures exerted by the roller ring are balanced out. The rollers are driven with the help of reduction gears like 45ί, 452 driven by motors like 45. A tachometer generator belongs to every motor like 453, and the four tacho generators in the selected example are connected in series, so that the uniform Signa !, which is formed in this way and which goes into the control system of the machine, is characteristic of is the mean roll speed.

For a description of the control system of the machine, reference is first made to the schematic representation in F i g. 8 and the diagram in FIG. 9 referred to.

In Fig. 8, the mandrel 21 and the wound in contiguous turns on this mandrel waveguide section G is illustrated, and the roller brake IV is located between the Drahtwickeieinrichitung II In the preparation of the waveguide, this waveguide section G continuously renewed, because the windings to the extent by sliding on advance the cathedral from left to right by forming them anew. The following forces act on the waveguide section: a thrust force F _b exerted by the winding device II; a counterforce F _c exerted by the roller brake IV ; and frictional forces of the individual turns on the mandrel, the axial components Z ₁ , f ₂ ... and the sum Σ fr and which also counteract the force Fb.

In order to ensure the mobility of the waveguide section on the mandrel, the following must be performed at all times Balance to be fulfilled:

F _b - F + Zf,
In the diagram in FIG. 9 shows the thrust force Fi as a function of the compression deformation, which is defined by the relative length AUL of the waveguide section C between the wire winding device and the roller unit. For the sake of simplicity, the curve is schematized by three straight lines. A first signature AO corresponds to the case AUL < 0, i.e. the tensile zone in which the waveguide windings are under tensile stress. Since the copper windings have a very low tensile stiffness, this segment AO has a relatively low gradient. The two following segments OB and BC correspond to the case AUL> 0, i.e. the pressure zone in which the waveguide windings are under pressure. The waveguide piece G has a considerable compressive rigidity in the zone OB when the individual wire windings and the insulating material are pressed together, which is expressed in a steep slope of the segment OB . Above a certain limit force Fb , this stiffness drops sharply, since turns such as S emerge from the winding bond to the outside, which leads to what is known as "winding jam", which is undesirable and manifests itself in the segment with a flat slope βC.

As shown above, the thrust Ft of the wire winding device must at all times be exactly equal to the sum of the counterforce F _{c of} the roller brake and the forces Σί due to the winding friction on the mandrel. Now the winding friction and with it the expression Σί is variable; it depends on the type and condition of the surfaces in contact, on the contact pressure, on the advancing speed of the windings on the mandrel, etc. Regarding the last-mentioned influencing variable, it can be said that the frictional force is relatively high at zero sliding speed (static friction), it decreases up to a certain speed and increases again from then on. The friction term 2 //, which is not known in its exact height, is shown in the diagram in Fig. 9 by a mean value <Σ: Ί> and can therefore fluctuate to a certain extent, as indicated by the double arrow on the segment OB . A point P is therefore selected as the working point on this segment, which lies in the middle between the two force levels, one of which represents a mean frictional force <2 "//> and the other corresponds to the limit force Fw for congestion The working point is therefore fully in the pressure zone, which is a necessary condition in order to produce a waveguide with good mechanical and electrical quality.

The operating point is determined to be exerted from the wire winding means and from this force over the difference F ₆ - 2i, the reaction force F _c of the reel brake. These force relationships are to be considered with the reservation that the counterforce is not too low, because otherwise the waveguide would be too subject to the frictional forces. In this case it would be necessary to increase the thrust F _t or to reduce the feed rate of the waveguide, to use the expression Σί, but this is not always compatible with a stable operation of the machine.

In summary, it can be stated that the counterforce F _c exerted by the roller brake, taking into account the changes in the frictional forces, must be sufficiently tied to the thrust force F _b emanating from the wire winding device, so that on the one hand the waveguide section G between the

Wire winding device and the roller brake under constant pressure bias is kept and thus on the other hand the length of the let through the rollers Waveguide piece is constantly equal to the length added, with the compressive bias in one narrow area is maintained. The difference between the piece of waveguide let through and the added length is equal to the previously defined size 4L

The control system of the waveguide winding machine comprises the following control loops:

A speed control circuit 20 (FIG. 10) of the wire winding device which can be set via a control voltage V ₂₀ I; a speed control circuit 30 (F i g. U) of the tape winding device, which takes the speed of the wire winding device as a manipulated variable; and a speed control circuit 40 (Fig. 12) of the roller brake, which also takes the speed of the wire winding device as a manipulated variable, but which, as shown below, is corrected by a device that ensures the equality of the wound and permeable waveguide length and the pressure biasing of the waveguide piece C between the Wire winding device and the roller brake ensures.

The speed control circuit 20 of the wire winding device is relatively simple. It has a potentiometer 20t which supplies a control voltage V> oi, a comparator 202, and an amplifier 203 which generates the power required to drive the motor 26 of the wire winding device. The tachometer generator 263 supplies a voltage V ₂₆₃ which is indicative of the true speed of the wire winding device. The comparator 202 supplies an error voltage V ₂₀₂ = V ₂₀₁ -V263, which is smaller, the higher the control gain.

The voltage V ₂ ^ , which characterizes the speed of the wire winding device, serves as a reference voltage for the speed control circuits 30 of the tape winding device and 40 of the roller brake, because of these three circuits the control circuit of the wire winding device has the largest time constant.

The speed control circuit 30 also has a simple structure, but it must be very efficient. This speed must be adjusted as precisely as possible to the speed of the wire winding device, the ratio of the width of the strips /? _t . R> to the diameter of the wire F must be taken into account. The control circuit 30 has a comparator 302 and an amplifier 303, which supplies the power necessary to drive the motor 36 of the tape winding device. The tachometer generator 363 supplies a voltage V ₃₆₃ which is indicative of the true speed of the tape winding device. The comparator 302 supplies an error voltage V ₃₀ ^ = V263-V ₃₆₃ , which is all the smaller. the higher the control gain. The gearboxes 261/262 and 361/362 (see also Fig. 6) translate the ratio of the bandwidth to the wire diameter.

The control loops 30 and 20 are of a known type, but have particularly high quality features. On the one hand, this applies to the time constant, which must be as small as can be achieved with mechanical means in order to obtain the minimum response time. On the other hand, this applies to the precision, i.e. the control gain. In particular, the amplifier 303 and the subsequent mechanical links are designed as best as possible to avoid disadvantages resulting from changes in the drive torque of the drives

NEN tape winding device by changing the reel diameter when emptying. Despite these precautionary measures, a small speed error would always be expected, which would result in the tape being wound up with an overlap or with a gap, if a fine correction potentiometer 301 were not additionally provided. This potentiometer supplies a voltage V301, which is also applied to the comparator 302 . Accordingly, ViO) = V ₂ Dj - Vj (, 3 - Vjoi. This fine correction of the speed requires constant monitoring of the operation of the machine.

The speed control circuit 40 of the roller brake must ensure compliance with the two previously defined conditions, namely the equality of the wound and the passed waveguide length (constancy of L) and the maintenance of the compressive bias of the waveguide section G between the wire winding device and the roller brake. This control circuit 40 firstly has a comparator 402 which forms the algebraic sum of all the voltages applied to it, and also an amplifier 403 which is used to drive the motors 45 to 48 (only the motor 46 is shown in FIG. 12) Roller brake delivers the necessary power. The tacho generators 453,463,473 and 483 (only the tacho generator 463 is shown in FIG. 12) supply a voltage V _4t i which is indicative of the true speed of the roller brake. The comparator 402, which the voltage k V ₂ ^ prop. V ₂₆₃ receives an error voltage V ₄₀₂ - A control loop described up to this point is not sufficient to meet the two conditions listed above. The smallest speed error of the roller brake is integrated in time and delivers a long error. the one for relocating the operating point in FIG. ^ leads, which ultimately leads to either the winding or the pulling out of the winding, which in both cases would impair the quality of the waveguide.

To avoid this error, a correction circuit is used, which works as a function of the change AL between the length of the waveguide section G that has passed and the length that has been wound. The change Ji. is nothing other than the displacement of the end winding 25. The Weggcber 255 already described supplies a voltage V _25,. which is indicative of the position of the winding head 25 with respect to a normal position. which, when the expected frictional forces are present, corresponds to the operating point indicated in FIG. 9 at which the desired preload is present and the voltage V'255 equals NuI! is. The voltage V255 is brought to the input of the comparator 402 via an operational amplifier 256. The total voltage applied to the input of this comparator is therefore the algebraic sum of three expressions and can be written as follows:

V - ί
Hence, expression (1) becomes
kV _1M + ak'Jv _M dt - Ku.3 -

where a, h, k, Ar 'are constant-

f J ^

df.

To control the speed of the roller brake from the position of the winding head alone would be great Encounter difficulties in terms of dynamics. Therefore, the speed of the roller brake motor becomes initially roughly controlled by a first control channel from the speed of the winding head and then corrected by a second control channel from the position of the winding head

In addition 8 sheets of drawings

Claims (14)

Claims-. 1.High winding machine for the continuous winding of circular, electromagnetic waves transmitting waveguides made of metal wire, with a wire tensioner, a wire winding device and a tape winding device, which are arranged in this order in the direction of the waveguide feed, the wire winding device having a fixed mandrel and a rotor outside the dome, characterized in that a roller brake (IV) is arranged at the end of the feed length, behind the tape winding device (III), that the rotor (23) of the wire winding device (II) has an inner channel (221) inclined to the rotor axis and leading through the wire which describes a cone with a center point on the wire tensioner (I), as well as a pulley (222) leading the wire from the outlet of the channel to the winding to be produced, and that a magnetic coupling (24) is provided which holds the mandrel (21) without hindering the rotation of the wire. 2. High winding machine according to claim 1, characterized in that the magnetic coupling (24) consists of a frustoconical central part (241) which is connected to the mandrel (21), and an outer part (23 ') connected to a part (23') of the machine frame ( 243), with an air gap (245) between the central and outer parts allowing the wire (F) to pass from the wire tensioner (1) to the channel (221) in the rotor (22). 3. HohHeiterwickelmaschine according to claim 1 or 2, characterized in that the wire winding device (II) and the tape winding device (111) with electric drive motors (26 and 36) are provided, to each of which a tachometer generator (263 and 363) is coupled, and that a Control system is provided in which a speed control loop (20) of the wire winding device Speed tracks a reference speed, and a speed control circuit (30) of the tape winding device the speed tracks the speed of the winding device. 4. Waveguide winding machine according to one of claims 1 to 3, characterized in that the tape winding device (IH) has a rotor (31) mounted coaxially around the rotor (22) of the wire winding device (II) such that the winding of the tapes (A ₁ , R ₂ ) as close as possible to the winding of the wire (tracked. 5. Waveguide winding machine according to one of claims 1 to 4, characterized in that the speed of the roller brake (IV) in a speed control loop (40) can be tracked to the speed of the wire winding device (II) that on the one hand the length of the waveguide section let through by the roller brake ( G) is equal to the wound length and that, on the other hand, the waveguide section between the wire winding device and the roller brake is held under pressure pretension. 6. Waveguide winding machine according to one of claims 1 to 5 with a roller brake several roles, characterized in that the rollers (41-44) evenly over the circumference of the Waveguide arranged distributed and each driven by an electric motor (45-48), the Roller axis runs perpendicular to the feed direction of the waveguide 7. Waveguide winding machine according to one of claims 1 to 6, characterized in that the electric motors (45-48) of the rollers (41-44) of the roller brake (IV) are connected in series. 8. Waveguide winding machine according to one of claims 1 to 7, characterized in that the electric motors ( 45-48) of the rollers ( 41-44) of the roller brake (IV) tacho generators (such as 453) are coupled. 9. Waveguide winding machine according to one of claims 1 to 8 with a roller brake with four rollers, characterized in that two lower rollers (41,42) are arranged in a fixed position and two upper rollers (43, 44) rest elastically against the waveguide, wherein the axes of rotation of the rollers are inclined by 45 ° to the horizontal. 10. Waveguide winding machine according to one of claims 1 to 9, characterized in that the speed control loop (40) of the roller brake (IV), which tracks the speed of the wire winding device (II), comprises a correction circuit (255, 256) which compares the wound and passed waveguide length takes over and receives the pressure bias of the waveguide section (G) between the winding device and the roller brake. 11. Waveguide winding machine according to one of claims 1 to 10, characterized in that the rotor of the wire winding device carries a co-rotating winding head (25) which presses via compression springs (254) against the wire of the waveguide piece (G) between the winding device and roller brake and that a The displacement transducer (255) acting on the winding head supplies an electrical control signal for the compressive tension to the correction circuit of the speed control circuit (40) of the roller brake (IV). 12. Waveguide winding machine according to one of claims 1 to 11, characterized in that the both the speed control loop (40) of the roller brake (IV) input voltage signals for the Speed of the wire winding device (II) and for the position of the winding head (25) below normal Operating conditions are in a ratio of 10: 1. 13. A high winding machine according to one of claims 1 to 12, characterized in that the speed control loop (30) for the tape winding device (III) has a fine correction device (301) through which the pretensioning of the tapes ( 32, 33) depending on the diameter of the tape spoolers (32, 33) R \, R ₂ ) can be corrected manually. 14. HohHeiterwickelmaschine according to any one of claims 1 to 13, characterized in that the tape winding device (III) can be driven by a stepping motor (324) whose numerical control (322, 323) depends on the one hand on a pulse generator (264-267), the one on the speed of the wire winding device (II) dependent pulse frequency supplies, and on the other hand of a pulse generator (321) for manual correction.