DE3546512A1 - Method for producing a wire coil - Google Patents

Abstract

In order to produce a meandering wire coil (40) of cylindrical configuration, an endless wire is wound to form a single-layer or multi-layer coil with a desired number of parallel turns, and the wound coil is formed into a meander whose sections (42, 43) which pass to and fro run parallel to one another on the circumference of a cylinder, preferably parallel to the cylinder axis. The winding overhangs (39, 44) which connect the meandering sections (42, 43) passing to and fro can likewise run on the cylinder circumference or can be bent inwards or outwards from the cylindrical configuration. Both a cylindrical coil and a flat coil can be formed into a meandering coil (40) of cylindrical configuration. <IMAGE>

Description

The invention relates to a method for producing a Wire spool. Furthermore, the invention relates to the after Procedure available wire spools. Finally, the concerns Invention a wire coil assembly by intermeshing arrangement of several, electrically separate, according to the invention wire coils is available.

Wire spools are usually produced by winding. Be agreed wire coil configurations can be shaped get wrap.

The object of the present invention is wire provide coils with a specific configuration, namely meandering wire coils in cylinder configuration.  

Starting from a method of making a wire coil, forming an endless wire into a single or multi-layer Coil with a desired number of parallel turns ge is wound, the solution according to the invention consists of this gave in that the wound coil deformed into a meander is, the reciprocating sections among themselves run parallel to the circumference of a cylinder.

The reciprocating meanders preferably run Sections on the circumference of a cylinder parallel to the cylinder axis.

Furthermore, the wound coil is preferably one Meanders with a uniform gap width between neighboring, back and forth meandering sections deformed.

The meanders obtainable by the process according to the invention shaped wire coils in cylinder configuration are apparent excellently suited for various applications where it low self-inductance is important. For example can use the coils generated according to the invention as energy converters in generators, but mainly because of their small electrical Time constants as drive coils for a wide variety of mo toric applications are used. In particular, result the meanders obtained by the process according to the invention shaped wire coils in cylinder configuration a high Filling factor in the cylindrical magnetic air gap electrical machine. Such meander coils are excellent suitable for high frequency machines. Thanks to the meandering Compared to conventional coils, a winding head falls away, so that the finished meander coil has a lower ohmic Exhibits resistance.

The straight, parallel, arranged at the same distance from each other, back and forth  meander sections of the meander coil, because these generate after DC power supply with suitable commutation, a moment driving a permanent magnet rotor, or in this Sections become a change when used as a generator voltage induced, depending on the design and speed is. The method according to the invention also ensures comparatively small meander coils in a cylinder configuration tion with a diameter of only a few centimeters a strictly geometrically parallel arrangement of all turns according to the meander configuration within the pre wire layer (s), an exact parallel guidance of all and leading meander sections and the same gaps width between meandering sections leading or going.

Single-ply or multilayer meandering wire coils in cylinder configuration ration are generated. With regard to the number of wire layers there are no special restrictions as far as the subsequent Liche deformation of the previously wound coil into a meander remains guaranteed. Also for coils with 5 or 6 wire layers there is no change in the magnetic effects. At for example, the method according to the invention allows the manufacture position of single-layer wire spools in cylinder configuration with a strictly cylindrical arrangement of the only Wire layer. All reciprocating meandering sections be can be found on the same, a certain radius speaking circumference around the cylinder axis; if necessary can all winding heads only on this scope be ordered. Such coils can be advantageous in electro nically commutated, multi-pole DC motors with cylinder air gap used as a rotor or stator winding because of high torque in a narrow air gap is achievable.  

Because the method according to the invention the production of mäan shaped wire spools in cylinder configuration with precise, allowed stabilized arrangement, it is possible to two or to arrange more meander coils so that they all fit together Liche, parallel, back and forth meandering sections the electrically separated meander coils on the same cylinder circumference around the common cylinder axis and thus together with appropriate commutation generate a rotating field. Only in the area of the winding heads there is an overlap that is outside the magneti The air gap of an electrical machine can be arranged can. Such a wire coil arrangement is particularly useful moderately as a stator winding for an electronically commutated, multi-pole DC motor with cylindrical air gap because with a comparatively simple control circuit exact commutation to generate a rotor that drives the rotor Magnetic field can be generated.

The conductor material, the thickness and the cross-sectional shape of the wire used to make the wire spool are not particularly limited. Common conductor materials come in Consider, such as copper, aluminum and in special also cut silver. The wire gauge is in the usual range and can be, for example, from 0.01 mm, in particular from 0.1 mm range up to a few millimeters. The wire cross section can be round or angular, for example square or right be angular. With a square or rectangular conductor cross-section, a higher fill factor can be achieved. At for example, the method according to the invention allows processing Processing of rectangular wire into a single-layer meander coil in cylinder configuration, in which the wire with its Main surface is aligned radially to the cylinder axis. Here can achieve a particularly high fill factor and a homo generated magnetic field. Also called "tinsel wire" can be used.  

If such a coil as a stator winding in an elec tric commutated, multi-pole DC motor with cylinder air gap should be used, the coil can because with a narrow wire side on a magnetic back closing part created, and the coil fixed in this arrangement will. The fixed arrangement can then be turned off. If applicable, the insulation between adjacent Wire threads bridging the turns can be etched away be removed. Then another layer of insulation can be used be applied. In this way, an optimally round Meander coil arrangement in a cylinder configuration with minimal Get distance to rotor orbit.

An insulated wire is typically used. In the Isolation agents customary in the art are suitable, such as the various insulating varnishes based on plastic or silk.

In some cases it may be appropriate to use the conductor to coat a double jacket, in which the inner layer primarily used for insulation, and the outer layer consists of a hardenable plastic that is thermally or radiation-induced can be cured, and so a be agreed meander coil configuration stabilized. Also the Use of so-called baked enamel wires is possible.

The number of turns is also not particularly limited. In order to take full advantage of the method according to the invention, The finished meander coil should at least be geometry from a few coaxially arranged turns exist. For the Ver as a stator winding in an electronically commutated, multipole DC motor with a cylindrical air gap the number of turns per wire layer - depending on the wire thickness - preferably chosen such that the width of a back or originating meander section is smaller than the pole width,  because otherwise the parallel conductor sections of one to or originating meander section always the magnetic field of would be exposed to two opposite magnetic poles. Especially the meandering section width should preferably be half the pole width does not exceed, because then with a comparative simple switching an exact commutation in the zero-through gears reached between two adjacent permanent magnet poles can be. Depending on the conductor cross-sectional dimensions the maximum number of turns in a wire layer chosen accordingly. With exemplary coils for this type turns have 15 to 25 turns a 0.15 to 0.5 mm thick wire with a single-layer wire arrangement well proven.

To deform a wound coil into a meander coil with cylinder configuration can be different according to the invention Measures will be provided.

According to a first embodiment of the Ver driving can be a cylindrical or disc-wound Coil of any configuration after stabilization of the win in a mutually parallel, position-stabilized arrangement be formed into a meander coil. The execution shape can by means of a particularly simple device and a meander coil will be obtained that at the top and bottom of the straight, back and forth Meander sections each have double coil thickness. The geometrically parallel arrangement of all coil turns is particularly precise because of an already stabilized coil is assumed, and in the further course no significant, especially no different mechanical stresses in the longitudinal direction of the wire on the different turns occur. This embodiment is particularly well suited  for the production of meander coils with long back and forth leading meander sections.

According to a second embodiment of the Ver the endless wire becomes a ring-shaped disc or flat coil wound, and this into a meandering Flat coil deformed. At least the back and forth Meander sections are then from the flat arrangement brought into the cylinder configuration.

The deformation of a not yet stabilized flat coil to a meandering flat coil, for example by means of a pane arrangement, over the level Main surface a number, arranged on a circumference Protruding pins that stretch a distance against spring pressure the center of the circle are too displaceable. To these pens around it - adjacent to the flat main surface - a single or multi-layer flat coil with the desired number of turns wrapped. Between two neighboring pins a wedge a larger distance to the center of the circle to move which the wire layers located there takes away and in a meandering configuration brings on the circumference of the wedge, while the pins suspended up to a stop on the inside of the circle point to be moved. The wire layer (s) of the resul Tender meandering flat coil are then in held in place and the wedges retracted.

The deformation of an already stabilized flat coil a meandering flat coil is for example by means of a rotatable tooth arrangement possible, the teeth of which one the desired meandering configuration adapted guide groove exhibit. The supplied, stable is in this guide groove  lized flat coil section of a suitable tool pressed in, for example the engaging teeth of one another tooth arrangement or from an adapted, back and forth forth movable lock arrangement.

According to a third embodiment of the Ver driving a solenoid is made from an endless wire wraps. This solenoid is made up of a number of first and second gripping elements packed and so along a virtual, tapered truncated cone section shifted that si multan the coil diameter is reduced and the straight and leading meander sections are generated. This ver can shift in the cross-sectional plane of the solenoid consequences.

According to this embodiment, a meander coil in cylinders configuration in which all windings in remain at their preferred level. The winding heads are also single Lich the material thickness of the coil. Between everyone, yourself opposite, mutually insulated winding section only the step voltage can occur, so that a such a coil especially for operation with higher voltages gene is suitable.

The invention will be described in more detail below preferred embodiments with reference to the drawings explained; the latter show:

Fig. 1 shows a schematic side view of a device for carrying out a first embodiment of the inventive method;

Fig. 2 shows a section of the meander coil available with the device of Figure 1 in Zylin derkonfiguration.

FIGS. 3a, 3b and 3c schematically various stages in forming a meander-shaped flat coil composed of an annular flat coil according to a second embodiment of the method according to the invention;

Fig. 4 on the circumference of a tubular yoke part a section of a meander coil in a cylinder configuration, which is available after bending the straight, reciprocating meander sections from the flat coil according to Fig. 3c;

Figure 5 shows a section of a U-shaped meandering coil in a cylinder configuration, which is obtained from a meandering flat coil according to Figure 3c Lich .

Fig. 6 and 7 in a schematic representation of other alternative alternatives for the deformation of a stabilized flat coil to a meandering flat coil;

Fig. 8 based on a schematic drawing, the deformation of a solenoid to a meander coil in a cylinder configuration according to a third embodiment of the inventive method;

Figure 9 schematically shows a device for carrying out the embodiment of FIG. 8. FIG. and

Fig. 10 is a wire coil assembly of two electrically separated, nested meander coils in a cylinder configuration.

Fig. 1 shows a tooth arrangement for carrying out a first embodiment of the inventive method. This tooth arrangement 10 has an upper ring gear 11 and a lower ring gear 15 which are slidably fitted towards and away from one another on a common holder (not shown). The upper ring gear 11 has a number of teeth or pinnacles 12 arranged along the circumference of a cylinder. Between two adjacent teeth 12 there is a saddle with the straight descending flank section 13 and the straight ascending flank section 14 . All flank sections 13 and 14 run at a 45 ° angle to a cylinder axis parallel. The length of the flan kenabschnitte 13 , 14 is adapted to the meander coil to be produced and is 1.4 times the coil width or the forward or return straight meander section. A playful ring gear 11 can have 40 teeth 12 along a circle with a diameter of 6 cm. The ring gear 11 including the teeth 12 consists of a comparatively thin, stable material, for example aluminum sheet, and has at least in the region of the flank sections 13 and 14 rounded edges, so that damage to the conductor wire is avoided.

The ring gear 15 is constructed analogously to the ring gear 11 , but the teeth 16 of the ring gear 15 are arranged on a gap to the teeth 12 , provided that a meander coil in cylinder configuration is sought, the reciprocating meander sections of which run parallel to the cylinder axis. The teeth 12 and 16 of the ring gears 11 and 15 are directed away from each other.

To produce a meandering wire coil in a cylinder configuration with this tooth arrangement 10 can be started from a flat coil or a solenoid of any configuration, the length of which corresponds to the elongated meander length. For example, to produce the output coil, an endless wire can be wound around two pins arranged at a selected distance from one another to form a solenoid. This output coil is stabilized, namely the individual windings in their parallel arrangement fixed to each other, which can be done for example by soaking the wound coil with a hardenable synthetic resin and subsequent curing.

After the appropriate distance between the two ring gears 11 and 15 has been set, a coil section is placed around the two flank sections 13 and 14 of a tooth 12 , the attached coil sections are then fed onto the opposite ring gear 15 and there around the flank sections of the opposite tooth 16 laying around. In this way, the deformation of the output coil is continued until the entire coil length is wrapped around the teeth 12 , 16 of the tooth arrangement 10 . The application of the last coil loop can be facilitated by reducing the height of the last tooth there or by missing this last tooth completely.

After the entire output coil has been brought into the meandering configuration, the distance between the two toothed rings 11 and 15 can be increased slightly in order to align the individual leading meandering sections 17 and meandering sections 18 exactly straight and strictly parallel to the cylinder axis. If necessary, the coil can be stabilized again in this arrangement.

Then the sprockets 11 and 15 are moved towards each other until the winding heads 19 protrude from the teeth 12 and 16 , respectively, so that the finished meandering coil of the tooth arrangement 10 can be removed. FIG. 2 shows a section of the meandering wire coil 20 obtained thereafter in a cylinder configuration. An exemplary meander coil 20 can have a single-layer wire arrangement with 20 turns per reciprocating meander section 17 , 18 , the length of which is approximately 20 mm.

The meander coil 20 can be used, for example, as a stator winding in an electronically commutated, multi-pole direct current motor with a cylindrical air gap. In such a case, the meander coil 20 is arranged on the circumference of a ring-shaped yoke part made of magnetic material, and fastened there free of vibration, for example glued on. The area of the winding heads 19 is angled inward over the upper or un lower edge of the yoke part, so that only the single-layer straight, parallel to the cylinder axis, reciprocating meandering sections 17 and 18 remain in the magnetic air gap. In this way, an extremely narrow drive level can be achieved, which still delivers a high torque.

Referring to FIGS. 3a, 3b and 3c, a further embodiment of the inventive method for the preparation of a meandering wire coil in cylinder configuration is explained below.

Fig. 3a shows schematically a section of a disc assembly 30, whose a flat major surface a number of protruding pins 31. The pins 31 are arranged along a circumference and within a straight line 32 against a spring pressure to move a distance far to the center of the circle. Furthermore, the disc assembly 30 is equipped with a number of wedges 33, the tracks along corresponding guide 35 in the middle between two adjacent pins 31 a large distance to the center of the circle are displaceable. On the circumference of each wedge 33 , a guide groove 34 is saved, groove height and depth being adapted to the dimensions of the coil to be produced. The contour of each guide groove 34 corresponds to the configuration of a meander, the winding head region preferably being round.

An endless wire 36 is - at least initially adjacent to the flat main surface - wrapped around the pins 31 until a flat coil 37 of the desired number of wire layers and turns is generated. Then all the wedges 33 are simultaneously moved along their guideways 35 towards the center of the circle.

Fig. 3b shows schematically the extent of the deformation of the flat coil 37 after the driven wedges 33 a certain distance be and the spring-loaded pins 31 have been moved a smaller distance far to the center of the circle. The displacement of the wedges 33 and the entrainment of the pins 31 caused thereby continues until the flat coil 37 has taken the meandering configuration shown in FIG. 3c. In this arrangement, the wire layer (s) are held firmly and then the wedges 33 are withdrawn. A meandering flat coil 38 is obtained, which is shown in detail in FIG. 3c. The winding arrangement of the meandering flat coil 38 can be stabilized by applying and curing a suitable binder.

The meandering flat coil 38 is then removed from the disk arrangement 30 and fed to a stamp / cylinder arrangement (not shown). If a meander coil in a "simple" cylinder arrangement is desired, the winding heads 39 of the meandering flat coil 38 are arranged and clamped on the end face of the cylindrical stamp close to the circumference thereof. By means of a suitable hollow cylinder, which is displaceable at a suitable distance along the stamp, the straight, reciprocating meander sections 42 and 43 of the meandering flat coil 38 are then angled and brought into the cylinder configuration. If necessary, the remaining end windings 44 can then be angled out of the cylinder configuration.

In individual cases, it may be expedient to use a ring-shaped yoke as a stamp, and to create the cylinder configuration, the reciprocating meander sections 42 and 43 directly on the circumference of this yoke. Fig. 4 schematically shows a section of the assembly obtained after that. As can be seen, the straight, parallel, reciprocating meander sections 42 and 43 of the finished meander coil 40 are in a cylinder configuration on the circumference of an annular yoke part 45 . The winding heads 39 and 44 are angled and are outside the cylinder configuration.

In an alternative embodiment, these can be sufficient long chosen meandering sections of a meandering flat coil in the middle of the end face of a hollow cylinder with pas Send diameter and sufficient wall thickness arranged will.

The sections of the meandering sections protruding on both sides beyond the wall thickness are then angled by means of a suitable, ring-shaped molded part with a U-shaped cross section and placed on the inner circumference and the outer circumference of the cylinder. It results in a U-shaped meander coil ( 50 ) in wesent union cylinder configuration, as shown in detail with FIG. 5. The winding overhangs 53 and 54 can be angled out of the cylinder configuration. On an annular yoke 55 of suitable dimensions and attached, the reciprocating meandering sections 51 and 52 of this U-shaped meander coil 50 in a "double ter" cylinder configuration within the cavity of a ring-shaped permanent magnet rotor with a U-shaped cross section a particularly generate high emf.

Within the scope of the method according to the invention, other measures can also be provided in order to form an annular and stabilized flat coil into a meandering flat coil, which is then brought into the cylinder configuration in a further working step. For example, such a deformation can take place with a rotatable tooth arrangement, as is shown schematically in FIG. 6. A gear 60 is equipped, for example, with four teeth 61 , on the order of which a guide groove 62 is recessed. Height and depth of the Füh approximately groove 62 are adapted to the wire layer and number of turns of the pre-made flat coil 63 . The gear 60 is partially rotatable about its axis, so that there is always a tooth 61 opposite the mold opening of an adapted lock arrangement 64 . The contour of the lock arrangement 64 is adapted to a tooth 61 and the flanks of the two adjacent teeth of the gear 60 . After a tooth 61 has been pivoted ver into a suitable position, the lock arrangement 64 can be moved to the tooth arrangement 60 , so that a suitably guided portion of the flat coil 63 is pressed into the guide groove 62 and assumes a meandering configuration. Then the lock assembly 64 is returned, the gear 60 rotated through a further angular section, and the coil section provided with the meandering configuration is separated from the gear 60 by a pin 65 .

The meandering flat coil obtained is thereupon one of the methods described above for a meandering wire coil deformed in cylinder configuration.

Fig. 7 shows schematically another way of deforming an annular flat coil into a meandering flat coil. This device comprises two gear wheels 70 and 75 with intermeshing teeth 71 and 76 . At least the teeth 71 of one gear have a guide groove 72 for receiving the stabilized flat coil. The con figuration of this guide groove 72 is largely adapted to the desired meandering shape. The flat coil 73 to be deformed is inserted into the gap between two interacting teeth 71 and 76 and pressed into the guide groove 72 when the teeth 71 and 76 roll together. The meandering flat coil is guided out of the guide groove 72 via a pin 74 and removed from the device.

The concept for deforming a cylindrical coil into a meandering coil in a cylinder configuration is explained below with reference to FIG. 8. In wesent union, the cylinder coil 80 initially produced on a cylinder circumference 81 is packed by first gripping elements 82 and second gripping elements 83 and moved along a virtual, tapering truncated cone section 84 such that the track diameter is simultaneously reduced and the straight, reciprocating meandering sections 85 and 86 of the meander coil 87 are generated. In the practical implementation of this alternative, the displacement can take place along the average cross-sectional plane of the solenoid.

With reference to FIG. 9, a winding machine realizing this concept and the possible deformation of a solenoid coil to a meandering coil in the cylinder configuration will be explained below.

To the essential components shown in FIG. 9 of the winding machine 90 include a base plate 91 , a motor-driven shaft 92 and a feed device 93 , which in turn comprises the first gripping elements 94 , the second gripping elements 95 and slider 96 . At a distance from the shaft 92 around it, the grooves 97 of an Archimedean spiral are recessed in the base plate 91 . A slider 96 is assigned to each gripping element 94 , 95 , and a guide lug 98 on each slider 96 can engage in these grooves 97 .

The first gripping elements 94 and the second gripping members 95 are arranged alternately on the circumference of a cylinder A and connected to the respective associated slider 26 via a slide 26 pivotally about the hinged bracket. The total number of first and second gripping elements 94, 95 corresponds to the number of straight back and forth meander sections of the desired meander coil. The first gripping elements 94 have a guide at their lower end, with which they are guided along the first, rising, inclined plane 99 . The second gripping elements 95 have a guide at their lower end, with which they are guided along the second, ascending, inclined plane 100 . These guide elements can be rotatable cogs 101 , for example.

Initially, feed device 93 and base plate 91 are coupled to one another and are rotated together by shaft 92 . The fuel supplied via the guide roller 103 wire 102 is Celtic gewic the cylinder peripheral A to a mono- or multi-layer cylinder coil 104 with the desired number of turns. The finished solenoid 104 is alternately packed from the first gripping elements 94 and two th gripping elements 95 . Then advancing apparatus 93 and base plate 91 are decoupled, the advancing apparatus held 93, and in the course of further rotation of the base plate 91 98 engage the guide lugs of the slider 96 in which the ro animal forming Archimedean spiral following the guide grooves 97 and move the individual gripping members 94 and 95 specifically towards the inside of the shaft 92 . At the same time, the first gripping elements 94 reach the first, rising, inclined plane 99 and are guided upwards by this; furthermore, the second gripping elements simultaneously reach the second, descending, inclined plane 100 and are guided downwards by the latter. The slope of the Archimedean spiral is adapted to the inclinations of the inclined planes 99 , 100 , so that the reduction in the coil diameter is adapted to the generation of the meandering sections in order to freely deform the neutral zones of the solenoid 104 displacement forces. As a result, a mutual displacement of the individual turns can be avoided during the deformation.

After completing the deformation, the finished meander coil can be stabilized. Thereupon the jaws of the gripping elements 94 , 95 are opened, the gripping elements 94 , 95 are shifted a little further inwards, and the finished meander coil in cylinder configuration is thereby released.

Two or more meandering wire produced according to the invention Coils in cylinder configuration can become a wire coil arrangement in which all and leading meandering sections that are electrically separate from one another separate meander coils on the circumference of a cylinder around the ge common cylinder axis are arranged around, and overlaps only occur in the area of the end windings. If a sol che wire coil arrangement as a stator winding in an electrical machine with a cylindrical air gap in the case of a single-layer design of all meander coils, the width of the magnetic air gap can be kept extremely low and be carries little more than the wire gauge. This can be practical the entire circumference of an annular yoke part with the to generate an EMF effective to and fro meandering sections of different coils in an optimal arrangement will. There can be a maximum fill factor with a low ohmic value Resistance in a narrow magnetic air gap is realized because there are no crossings of the meandering sections in the air gap occur. Thanks to the electrical isolation, different Coils are controlled electrically out of phase, which ins especially for the use of such a wire coil as a stator in an electronically commutated, multi-pole DC current motor is desirable.  

Fig. 10 shows an exemplary wire coil assembly 110 , which consists of two mutually arranged, but elec trically separated meander coils 111 and 115 . Each meander section 112 of the one meander coil 111 is located on the same cylinder circumference within the gap between two adjacent, to and fro meander sections 116 , 117 of the other meander coil 115 . The width "b" of the meandering section 112 preferably corresponds to the gap width "c" between the other two meandering sections 116 , 117 , so that practically the entire circumference of the cylinder can be covered with wire. The winding heads 114 , 118 are angled out of the cylinder configuration so that the required crossovers do not occur in the area of the cylinder circumference.

Claims (15)

1. A method for producing a meandering wire coil in a cylinder configuration, wherein an endless wire is wound into a single or multi-layer coil with a desired number of parallel turns, and the wound coil is deformed into a meander, the reciprocating sections of which are parallel to one another on the circumference of a cylinder, characterized in that a cylindrical tooth arrangement ( 10 ) with two spaced-apart toothed rings ( 11 , 15 ) is used to deform the wound coil, the teeth ( 12 , 16 ) of which point away from one another, with between adjacent teeth each a saddle with a straight descending and with a straight ascending flank section ( 13 and 14 ) is formed, which flank sections ( 13 , 14 ) run at a 45 ° angle to a cylinder axis parallel; and from the sections of the coil one after the other against these flank sections, around a tooth ( 12 ) of the one ring gear ( 11 ) and then around an opposite tooth ( 16 ) of the other ring gear ( 15 ). 2. The method according to claim 1, characterized in that the two ring gears ( 11 , 15 ) moved away from each other to tighten the straight, back and forth meandering sections. 3. The method according to claim 1 or 2, characterized in that the teeth ( 12 ) of the one ring gear ( 11 ) on the gap to the teeth ( 16 ) of the other ring gear ( 15 ) are arranged. 4. The method according to any one of claims 1 to 3, characterized in that the length of each flank section ( 13 , 14 ) is selected to be 1.4 times the width (b) of the coil. 5. The method according to any one of claims 2 to 4, characterized in that after tightening the reciprocating meandering sections, the two ring gears ( 11 , 15 ) are moved towards each other again to the finished meander coil ( 20 ) over the teeth ( 12 , 16 ) from the order of teeth ( 10 ). 6. A method for producing a meandering wire coil in a cylinder configuration, wherein an endless wire is wound into a single or multi-layer coil with a desired number of parallel turns, and the wound coil is deformed into a meander, the reciprocating sections of which are parallel to one another on the circumference of a cylinder, characterized in that a winding machine ( 90 ) is provided, with a base plate ( 91 ) which has a guide groove ( 97 ) following an Archimedean spiral at a distance around a motor-driven shaft ( 92 ), and also with a Shaft ( 92 ) connected feed apparatus ( 93 ), which is equipped with first gripping elements ( 94 ) and two th gripping elements ( 95 ) and with these gripping elements ( 94 , 95 ) associated sliders ( 96 ); The shaft ( 92 ) sets the feed device ( 93 ) in rotation together with the base plate ( 91 ) and an endless wire ( 102 ) around a cylinder circumference (A) on the feed device ( 93 ) to form a single-layer or multi-layer cylinder coil ( 104 ). is wound with the desired number of turns; the wound solenoid ( 104 ) is alternately packed by the first or second gripping members ( 94 or 95 ) at regular intervals; thereupon the feed device ( 93 ) is held, and in the course of the further rotation of the base plate ( 91 ) guide lugs ( 98 ) the slide ( 96 ) engage in the guide grooves ( 97 ) of the rotating Archimedean spiral and the first and second gripping elements ( 94 , 95 ) to be moved inwards onto the shaft ( 92 ), while simultaneously the first gripping elements ( 94 ) along a first rising "inclined" plane ( 99 ) and simultaneously the second gripping elements ( 95 ) along a descending "inclined" Level ( 100 ) can be moved down. 7. The method according to claim 6, characterized in that as "inclined" planes ( 99 , 100 ) blunt, mirror images aligned to each other around the shaft arranged truncated cone sections are selected. 8. The method according to claim 6 or 7, characterized in that the slope of the Archimedean spiral to the inclination of the first and second "inclined" planes ( 99, 100 ) is adjusted. 9. The method according to any one of claims 1 to 8, characterized in that the wound coil stabilized and then into one Meander is deformed. 10. The method according to any one of claims 1 to 9, characterized in that a wire with square, especially rectangular wire cross section is selected. 11. Wire spool with a number of turns in one or more layers order, with all turns meandering on the circumference of a Cylinders run and between neighboring straight meanders sections have a uniform gap width is characterized in that the wire coil according to a method according to one of the Claims 1 to 10 is available. 12. Wire coil arrangement, characterized in that a plurality of wire coils ( 111 , 115 ) obtained in accordance with the method according to one of claims 1 to 10 are arranged one inside the other, the meandering sections ( 112 , 113 ; 116 , 117 ) of all coils ( 111 , 115 ) are arranged on the circumference of a cylinder around the common cylinder axis, and overlaps only occur in the area of the winding heads ( 114 , 118 ). 13. Wire coil arrangement according to claim 12, characterized in that two wire coils ( 111 , 115 ) are arranged one inside the other. 14. Wire coil arrangement according to claim 13, characterized in that the meandering section ( 112 ) of the one wire coil ( 111 ) substantially fills the gap width "C" between two adjacent th meandering sections ( 117 , 118 ) of the other wire coil ( 116 ). 15. Wire coil arrangement according to one of claims 12 to 14, characterized in that the wire coils ( 111 , 116 ) have single-layer wire arrangement.