DE1915847A1 - Process for the production of windings for dynamo machines - Google Patents

Description

915847

March 27, 1969

JOSEPH LUCAS (INDtTSTRIES) LIMITED Birmingham (UK)

Process for the production of windings for dynamo machines

The invention relates to a method for producing windings for dynamo machines.

According to the invention it is provided that a flat conductive tape is helically wound, the helix to form a Wave winding is bent and the winding is dipped in synthetic resin, while adjacent windings of the winding be kept out of contact. The term wave winding is understood here to mean a winding that is in use around equiangularly spaced poles on the inside of a cylindrical yoke of a dynamo machine. The winding has an even number of essentially axially extending parts, with adjacent pairs of the axially extending parts are interconnected by curved end parts. Curved ones lying next to one another

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End portions of the winding are at opposite ends of the Yokes and extend around the poles.

The invention is illustrated below using an exemplary embodiment described in more detail with reference to the drawings. In the drawings are:

Fig. 1 is a section through the winding station of a machine for the production of wave windings,

2 shows a schematic view of a top view a machine transfer station,

Fig. 3 is a front view of the molding station of the machine; 4 shows a section through the station shown in FIG. 3;

Fig. 5 is a perspective view of a helically wound Core made of flat conductive tape, which has been produced in the winding station of the machine is,

6 is a perspective view of a finished wave winding,

7 shows a detail in section through a dynamo machine, in which the windings shown in FIG. 6 used, and

FIG. 8 is a section on line 8-8 in FIG. 7.

Aluminum wire in the shape of a running ribbon Io rectangular Cross-section runs from a feed station through hammers through to an isolation ward, in which a running

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Self-adhesive tape ^ *! Igglier paper 1oa on top of the Aluminum wire baBäs is glued on. The insulating paper has im essentially the same width as the aluminum tape it is but it is not important that the paper covers the entire top of the tape "

The aluminum tape ίο runs together with the insulating paper 1oa su a winding station 11 (Fig. 1). The winding station 11 has a substantially cylindrical winding holder 12 which is provided on its lower edge with an outwardly directed peripheral flange 13. The coil holder 12 is at the top. Attached to the end of a vertically extending shaft 14 which is journalled in the mass retainer for axial and angular movement. Pneumatic leather cylinder 15 acts via a fork lever 1b _f which engages a sleeve 17 on the shaft 14 and pushes the shaft 14 and the winding holder 12 upwards. The end of the shaft 14 opposite the winding holder 12 has lutes 18 which engage in corresponding grooves on the upper end of the drive shaft 19, which is driven by an electric motor via a two-speed gear and a reduction gear 21. There are two cams on the shaft 14 !! 2 2, which rotate with the shaft 14 and see the microswitches that control the rotation of the winding holder and the actuation of an electromagnetic lock to lock the rotation of the shaft 14.

The winding holder 12 is assigned a release roller 23 which engages the flange 15 of the winding holder 12. The role 23 takes the form of a rigid disc that rotates around an axis is, which is offset to the axis of the winding holder 12 and inclined. Located on the flange 13 of the winding holder 12 a Klenmfinger 24, which serves to the end of the To clamp aluminum tape to the weighing holder 12. To the Winding station 11 includes a tape cutting device 25, with which the tape wound on the winding holder 12 afterwards

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fines Wiak & XYQrgajigs, VQl Se§t ät§ can be.

In addition to the Wiokelsta.tiaji b, efindet gigh, a; f-pansf§r§ $ ati @ n ft6 (Fig, 2], which in the wrap, tatipn 11 Gewi6ke £ te ^: --SsS ^r äW§S & elB ■ forwards to a form statian? hr§ile, n will be, Pie transfer station has a vertika.1b; §wegba; right., | rotatable column 27, at the upper end of which sits gizie s $ QU extending plate 2g on the blade; qind peripheral claws 29 . rotatably the claws 29 extend pIGH gbe: r 4as free Jende 2R out and are bent with ^{greif§tügjten:} provided J1 'at their free linden, I> i§ claws 2f are connected du'reh §ine spring with each other, the Klguen presses into an open position, the claws are closed by a part 32 which can be moved between the rear ends of the claws by means of a compressed air cylinder 55

The transfer station transfers the wound in the winding station Coils to a forming station 34 (Fig. 3 and Fig, 4), The Fgrm station comprises a vertically extending frame 35? which forms part of the framework of the entire machine »Am the lower end of the frame 35 are two vertically extending, essentially parallel fingers 3 (5 hinged, which in Swiveling towards and away from each other and at their free ends in the cross-section of a quarter circle from » are formed. Above the fingers there is a 6 pound Carriage 37, which is vertically displaceable on the frame 35 · The Movement of the slide is made by a hydraulic cylinder 38 controlled. On the slide 38, for movement in a plane which is at an angle of 90 ° to the plane of movement of the fingers 36 hinged two more pairs of fingers 39, which are down in Extend towards the fingers 36 and at their free end. which are designed as a quarter circle in cross-section, The Fingers 36 are urged apart by a spring,,,,, and

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a corresponding spring pushes the pingers 39 apart. The arcuate surface of the free end of each of the fingers 36, 39 includes a protrusion in the form of a pole piece around the the winding to be formed will stretch around when used in a dynamo machine. Furthermore, the projections each have an arm that extends parallel to the associated finger, to make a slit with the free end of the finger. The fingers 36 are surrounded by a cylindrical calibration sleeve 4-1, which is vertically movable on a socket 42, which is displaceable on the frame 35 · An inclined shaft 43 sits on the fingers 36, 39 and is in a position between the Fingers movable while the forming station is working.

The procedure works as follows: The aluminum tape is provided by the insulating station, in which the tape is provided with a layer of insulating paper on its upper side is conveyed to the winding station, where the end of the tape by the clamping finger 24 to the flange 13 of the winding shark. ters 12 is clamped. The legroll 23 is then brought into engagement with the top of the belt so that the belt is between the flange of the Legrolle and the flange 13 of the winding holder 12 is connected. The coil holder 12 is then set in rotation in order to wind the tape onto the winding holder. With the winding of the tape on the The winding holder pulls the tape through the isolation station so that the tape is wound onto the winding holder is always provided with a layer of insulating paper on its top. To rotate the winding holder 12 by a certain Number of revolutions and parts of revolutions, a control device is provided to which the cam disks 22 belong. The cradle holder is then locked. During the cradle, the cradle holder 12 moves downwards against the Force of the pneumatic spring cylinder 15 so that the tape is helically wound on the winding holder. If the wieklungshalter 12 engages, the transfer device is in

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brought a position in which the claws 31 are on opposite sides of a wound coil. The Trennein- '"'" direction 25 is then actuated in order to separate ax wound coil from the "rest of the belt. Then, the coil is slightly developed due to their spring properties, are present at the mouth 31 to the ünden the wound coil. The low level of Development of the coil occurs after the coil can spread slightly as a result of the severing, so that the coil can be lifted from the coil holder 12. The transfer device is then actuated, the claws 31 gripping the coil, vertical relative to the coil holder 12 lift it up, transfer it to the forming station and then release it. Then the transfer device * moves out of the working area of the forming station.

The wound coil is opened by the transfer device the fingers 36 of the forming station 34- deposited. The helix arrives engaged in the carriage between fingers 36 and the Arms of the protrusions on the fingers, so that the coil is prevented from developing by the arms of the protrusions.

Thereafter, the cylinder 38 is acted upon in order to move the carriage downwards, so that the free ends of the fingers 39 migrate into the coil, while the arms of the respective projections on the outside of the coil run along ₆ . The coil is thus supported at two diametrically opposite points by the projections of the fingers 36, and it is pressed downwards through two further diametrically opposite points which are offset by 90 from the first diametrically opposite points, namely by the projections of the fingers 39 . in a further movement of the slide 37 down the coil is bent so that the winding is formed, as shown substantially in Figure ₉ 6. With the bending of the helix, the fingers wander

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gea? 36 gg ^ nd | .i WiriEung the said Fed ^ r ill direction aufginandgr zu _e similarly move the fingers 39. against the we-? kung you-ej? Corresponding spring, with the movement of the pairs of fingers, the four ends of the four fingers interlock to form a fully cylindrical. To form profile when the carriage 37 reaches the lower end of the path. When the fingers have come into full engagement, locks assigned to the pairs of fingers come into effect! to lock fingers 36 in their closed position and, correspondingly, fingers 39 in their closed position.

When the carriage 37 reaches a lower end of travel, the Calibration sleeve 41 is moved upwards in the direction of the position ", at which the fingers 3fc>, 3y are in engagement. The calibration sleeve increases inside from a largest diameter at the top to a smallest diameter at a point between the ends the. Sleeve from conical, with the smallest diameter slightly smaller than the inside diameter of the yoke of the dynamo in which the finished winding is to be used. One of the Finger 39 is assigned a pull-out lock which is actuated while the calibration sleeve encloses the interlocking portions of the fingers to grip the partially formed coil and thereby hold it on the fingers 39. The calibration sleeve 4-1 executes an upward stroke and then returns to the starting position of the partially formed winding is brought to the desired size in order to complete the shaping of the winding. When the calibration sleeve 41 reaches the starting position, a microswitch is switched, which causes a return movement of the slide 37 and thus the finger 39 in the direction of the upper end of the path of the slide 37. Because the pull-out lock is in engagement with the winding, the form winding is guided with the fingers 39 upwards. During the return When the slide 37 moves, a microswitch is switched which stops and closes the slide 37 in its upward movement

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a movement of the shaft 43 between .die fingers 39 and the Finger 36 leads. After entering the shaft 43 between the fingers 36 and 39, the upward movement of the fingers 39 and of the carriage 37 resumed. One, cam on frame 35 works with the pull-out lock during the further upward movement. movement of fingers 37 together to release the pull-out lock. At the same time the projection runs between one of the fingers 39 two stops on the frame 35, which is attached to the. Form winding attack and wipe it off fingers 39. The .Formwick "-. lung falls on shaft 43 and rolls down the shaft, .. " in a magazine. Then the fingers 39 return to hers. Exit: -? lay back, and the locks assigned to the two pairs of fingers are released so that the fingers of the respective. , Pairs spread under the action of the said springs, can, =, so that the parts forming the forming station are in the starting position for another. Working cycle is ·. ...

Since the aluminum tape used to make the winding was provided with a layer of paper on the top, the turns of the shaped winding are at a distance from one another and are insulated from each other by the layer of insulating paper. Around the form winding against moisture in use To protect it, the molding is wrapped in melted synthetic resin submerged, for example PVC, which wraps around the winding and completely covers it. After the PVC has cured the windings are completely encapsulated and insulated by a layer of PVC. . . .. ....

In one variant, the insulating station is omitted, and * the winding is made of aluminum tape without the insulating one. Paper layer made. The turns of the finished winding are therefore not isolated from one another before the winding is immersed in the molten synthetic resin. Prior to immersion ,, _of: winding the turns of the winding are placed in a distance from each other by paper strips between adjacent

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Coils are introduced to separate the coils from one another to keep. Then the winding is immersed in the molten synthetic resin. During the immersion, the molten one flows Resin around and between the turns of the winding to complete the insulation of the winding.

As shown in Fig. 7 and β is the coated Winding 44 at its ends each with a threaded part 45 and with two brushes 46 with the associated supply lines 47 Mistake. The winding 44 is then inserted into the yoke 48 of a dynamo machine inserted so that the curved ends 44a at the rounded ends of two diametrically opposite Contact pole pieces '49 *, which are formed in one piece with the yoke 48 are. '"Two more pole pieces 41 are then inserted into the Yoke 48 inserted, with the winding 44 between the yoke

48 and integrally molded flanges 52 on the pole pieces

49 and 51 is included.

The coil from which the winding is formed does not need to be cylindrical. Flawless windings have also been produced by the forming station of the device, in de NEN of coils was assumed which had essentially square or essentially elliptical cross-sections.

The two methods according to the invention, in which the turns the winding are kept at a distance from one another by the paper tape 1oa or by paper strips use themselves to make turns from copper tape. A process that is used for making turns from aluminum strip suitable and in which the tape is completely encapsulated in insulating paper prior to winding the tape, wherein If the molded winding is not immersed in synthetic resin, it has proven to be unsuitable for the production of windings from copper tape proven that the force required to bend the copper band is greater than that of the corresponding aluminum band for bending required force caused damage

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finishing of the paper layer surrounding the copper tape.

Claims t

909845/0945

ORIGINAL INSPECTED

Claims (1)

Claims Process for the production of windings for dynamo machines, characterized in that a flat conductive The tape is wound in a helical manner, the helix is bent to form a wave winding and the winding is made of synthetic resin is immersed while adjacent turns of the winding are kept out of contact. 2ο method according to claim 1, characterized in that adjacent Turns of the winding are kept out of contact by the fact that the flat conductive tape is attached one side is provided with an insulating layer before the tape is helically wound. 3. The method according to claim 1, characterized in that adjacent Turns of the winding are kept out of contact by insulating spacers between adjacent turns are used after bending the helix to produce the wave winding. 4. The method according to any one of claims 1-3, characterized in, that polyvinyl chloride is used as the synthetic resin. 5 »Method according to one of claims 1-4, characterized in that that aluminum tape is used as the conductive tape. 6. The method according to any one of claims 1 - 4, characterized in, that copper tape is used as a conductive tape 23 135 Wa / K. 909845/0945 BATH ORIGINAL Read r e 11 e