GB2073264A - Orthocyclic coil winding machine - Google Patents

Abstract

The machine comprises a bed (1), Fig. 1, on which is mounted a turntable (2) with several mandrels (3) installed radially thereon, each mandrel, Fig. 3, comprising a body (13) with a tapered supporting sleeve (14), a slotted head flange (15), a removable tail flange (16), a carrier (17) with radial slots (18) and sectors (19) received in the carrier slots and having inclined inner surfaces cooperating with the taper surface of the support sleeve so that the sectors are retracted radially inwardly when the flange (16) is removed. Teeth (20) on the sectors form, when the sectors are expanded through axial slots in a bobbin having flanges 25, 25_, orthocyclic grooves (21). Elastic rings (22) are fitted around the sectors (19). The machine also includes a mechanism for correcting the winding pitch during the winding of a coil, and a wire placer (7) which acts as a wire tensioner and is adapted to ensure the correct initial winding pitch. The bobbin may be omitted. <IMAGE>

Description

SPECIFICATION Orthocyclic coil winding machine This invention relates to manufacturing equipment for making electric coil windings and has particular reference to machines for winding orthocyclic electric coils.

The invention may be used in various applications, for example, in electric engineering and in manufacture of automotive and aviation electricals and electronic equipment.

There is known a machine for winding orthocyclic coils (F.R.G. patent No. 1232655, cl.

H01 F,1961).

The known machine comprises a bed and a turntable with several mandrels radially installed thereon. Located at the required distance from one of the mandrels is a winding spindle installed on the machine bed and provided with a drive unit.

Mounted on the spindle is a faceplate whose shaft carries a wire placer. As the turntable rotates in the proper sequence, the mandrels are set in the required position at the winding spindle. The winding spindle rotates and reciprocates simultaneously. This winding spindle is constructed as a hollow shaft through which wire passes from an uncoiler to a winding head.

When the coil has been wound with the required number of turns, a counter mechanism switches off the winding spindle drive. The winding spindle is braked and thereafter, by means of an auxiliary drive, a worm gear and a freewheel clutch, is slowly turned into the initial position whereat guide pulleys, which are mounted on the faceplate of the winding spindle, are over the completed coil. When this position has been attained, the auxiliary drive is switched off by a contact. Thereafter the drive of the winding spindle is switched on again and winding is done on the next coil.

The known machine can wind only former coils because of the mandrel construction. This machine fails to ensure high quality of winding multilayer coils, especially with fine wire, because of lack of uniform winding pitch inasmuch as said machine has no provision for pitch correction in winding orthocyclic coils.

In accordance with the invention in its broadest aspect there is provided an orthocyclic coil winding machine comprising a bed, a turntable mounted on the bed and having several mandrels installed radially thereon, and a winding mechanism for winding coils of wire onto the mandrels in turn, each mandrel comprising a support device with a tapering surface portion, a head flange and a removable tail flange carried on the support device, and a plurality of elongate elements supported by the support device in respective radial slots and between the flanges, the elements being movable in the slots and having inclined inner surfaces cooperating with the taper surface of the support device for the elements to be displaced radially in response to relative axial movement between the elements and the support device.

More specificaily the invention provides an orthocyclic coil winding machine comprising a bed, a turntable mounted on the bed and having several mandrels installed radially thereon, and a winding mechanism for winding coils of wire onto the mandrels in turn, each mandrel including a body, a supporting sleeve having a tapering surface and mounted on the body, the sleeve supporting a slotted head flange, a removable tail flange, and a carrier provided with radial slots and positioned between the flanges, a plurality of sectors received in the radial slots of the carrier, and elastic rings extending about the sectors, the sectors having inclined inner surfaces cooperating with the taper surface of the supporting sleeve for displacing the sectors radially, and the outer surfaces of the sectors being toothed to form peripheral grooves.

It is desirable that, in order to provide for selfplacement of wire at the preset pitch of the winding spindle during the movement thereof along the mandrel axis, the wire placer should be constructed as a guide pulley and a tensioner comprising a rotatable sleeve having longitudinal slots and installed on the shaft of the guide pulley and further comprising a brake installed on the rotatable sleeve and arranged to contact the guide pulley, the guide pulley with the rotatable sleeve installed thereon being positioned between abutments with a clearance equal to the diameter of the wire being wound.

It is further desirable that, in order to maintain the winding pitch within the preset limits, the machine should be provided with a winding pitch correction controller comprising a correction unit mechanically linked with the winding spindle and an actuator whose electrical input connects with an amplifier which is connected with a coil fill pickup installed on the machine bed and mechanically linked with the winding spindle and is also connected with a wire turn count pickup mounted on the machine bed and arranged to interact with the winding spindle.

The proposed invention widens the scope of the machine by virtue of the special mandrel construction which enables formerless coils to be wound as well as former coils. The invention enhances the quality of coil manufacture inasmuch as it provides for producing orthocyclic coils with more turns and layers.

The invention will now be more particularly described by way of example with reference to the accompanying drawings, wherein: Figure 1 is a general side view of an orthocyclic coil winding machine according to the invention; Figure 2 is a general plan view of an orthocyclic coil winding machine according to the invention; Figure 3 is a longitudinal sectional view of a mandrel according to the invention; Figure 4 is a cross sectional view of Figure 3 according to the invention; Figure 5 shows the construction of a sector according to the invention; Figure 6 is a longitudinal sectional view of a wire placer according to the invention; Figure 7 is a sectional view on the line Vil-VIl of Figure 6 according to the invention;; Figures 8, 9, 10 and 11 schematically show a wire placer and a mandrel and explain the successive stages of forming the first wire turn in winding an orthocyclic coil according to the invention; and Figure 12 is a diagrammatic view of an orthocyclic winding pitch correction controller according to the invention.

The orthocyclic coil winding machine comprises a bed 1 (Figure 1) which mounts a turntable 2 with several mandrels 3 installed radially thereon. At the required distance from one of the mandrels 3 is situated a winding spindle 4 driven by a drive unit 5.

The winding spindle 4 mounts a faceplate 6 on whose shaft is installed a wire placer 7.

An electric motor 8 is provided for setting the faceplate 6 in the initial position.

The winding spindle 4 has a hollow shaft through which is passed wire 9 running from an unreeling device 11 by way of a guide pulley 10.

A coil fill pickup 12 (Figure 2), designed for control of filling coil tiers, wire wire turns, is provided on the bed 1.

The mandrel 3 is constructed as a body 13 (Figure 3) with a supporting taper sleeve 14 mounted thereon. The supporting sleeve 14 mounts a head flange 15 with a slot, a removable tail flange 16, and a carrier 17 with radial slots 1 8 wherein sectors 1 9 are installed for radial movement. The taper surface of the sectors 1 9 mates with the taper surface of the supporting sleeve 14. On the side opposite the taper surface, the sectors 19 are provided with teeth 20 which form grooves 21. Elastic rings 22 are provided on the sectors 19. A rod 23 is inserted into the hole in the supporting sleeve 14. Locks 24 are provided on the mandrel body 13 for the purpose of fixing the rod 23 in the supporting sleeve 14.

Figure 3 depicts a mandrel 3 which mounts a coil former having flanges 25 and a body 25' with longitudinal slots.

To enable wire transition from turn to turn (zone y in Figure 4), the space between the two sectors 1 9 at the location of the slot in the flange 1 5 may be wider than between the other sectors.

Figure 5 shows the construction of a sector 1 9 with teeth 20 and grooves 21.

The wire placer 7 comprises a guide pulley 26 (Figure 6) and a tensioner constructed in the form of a rotatable sleeve 27 which has longitudinal slots 28 and is installed on the shaft 29 of the guide pulley 26, and further comprising a brake 30 which is installed on the rotatable sleeve 27 and is arranged to contact the guide pulley 26. The guide pulley 26 with the rotatable sleeve 27 installed thereon is positioned between abutments 31 and 32 with a clearance t equal to the diameter of the wire 9 being wound.

Figure 7 is a sectional view on the line VIl-VIl of Figure 6 according to the invention.

Figures 8, 9, 10 and 11 schematically depict the wire placer and a mandrel and explain the successive stages of forming the first wire turn in winding an orthocyclic coil.

Correction of the pitch in winding an orthocyclic coil is effected by the use of a winding pitch correction controller comprising a correction unit 33 (Figure 12) constructed, for example, as a variable-speed drive (see the magazine "Engineering for the Youth", No. 12, 1977, Moscow, an article by Nurbei Gulia, "Change Speed Smoothly or Variations on the Theme of Variable-Speed Drives") which is provided with an actuating mechanism 35 constructed, for example, as an electric motor, has an input shaft 33' and an output shaft 33", and is mechanically linked through a flat-toothed belt 34 with the winding spindle 4 and through a flat-toothed belt 36 with a worm wheel drive 37. The shaft of the worm wheel mounts a cam 38 which mates with a roller 39 installed on a slide and interacts, through a screw mechanism 40, with a pivoted lever 41 and the spindle 4.The electrical input of the actuating mechanism is connected with the output of an amplifier 42 (see "Semiconductor Integrated Microcircuits, Series K511), for Machine-Tool Control Systems", published by ENIMS, Moscow, 1978, pages 72,76, 108).

The amplifier 42 is electrically connected with the coil fill pickup 12, which is constructed, for example, as a wiper switch installed on the bed of the winding machine and mechanically linked with the winding spindle 4 through a rack 43 and a pinion 44. The amplifier 42 is also electrically connected with a wire turn count pickup 45 constructed, for example, as a contactless limit switch. A finger 46 connected with the spindle 4 is caused by the spindle movement to act upon the pickup 45. To enable lengthwise movement of the spindle 4, the latter is made in two parts united by means of a splined coupling 47.

When the winding machine is put in operation, the turntable 2 (Figure 1) with several mandrels 3 is moved by a pitch determined by the quantity of the mandrels 3 and thereafter the turntable is locked in position. Then the drive unit 5 is switched on and rotation is transmitted to the winding spindle 4. The winding spindle 4, in conjunction with the faceplate 6 and the wire placer 7, places the wire 9 in the winding space of the mandrel 3. When the last wire turn is completed, the spindle 4 operates a limit switch (not shown), whereby the drive unit 5 is switched off. The spindle 4 is positively braked and at the same time the motor 8 is switched on to set the faceplate 6 into the initial position.

The mandrel 3 (Figure 3) operates as follows: The coil former with the flanges 25 is mounted on the mandrel 3. Thereafter the removable tapered tail head flange 1 6 is installed. By interaction of the tapers of the flange 1 6 and of the supporting sleeve 14 with the tapers of the toothed sectors 19 fitted in the slots 1 8 provided in the carrier 17, the sectors 1 9 are moved radially toward the former body 25' and the sector teeth 20 enter the lengthwise slots in the former body 25', standing over the surface thereof. The sectors 1 9 are locked in position by the locks 24. The teeth 20 of the sectors 1 9 form orthocyclic grooves 21.

After the coil has been wound, the tapered flange 1 6 is removed, the sectors 1 9 are returned into the initial position by the action of the elastic rings 22, the teeth 20 come out of the slots in the former body 25', and the completed coil is removed from the mandrel 3.

The winding of an orthocyclic coil can also be done without a former. In such a case the mandrel 3 functions likewise, but a former is not used and the flanges 25 are replaced with dummies.

In the making of orthocyclic coils, the proposed mandrels enable effecting economy in the material of formers, provide a choice of winding technology (with or without formers) and promote flexibility of the control and organization of coil manufacture.

The wire placer 7 operates as follows: The wire 9 (Figure 1) passes from the unreeling device 11 through the guide pulley 10 and the hollow shaft of the spindle 4 to the wire placer 7.

Before the commencement of winding, tension is given to the wire 9, between the pulley 26 and the winding, by means of the sleeve 27 (Figure 6) and the brake 30 mounted thereon. The initial position of the pulley 26 is set so that the axis of the wire 9 makes a right angle with the axis of the coil former or of the mandrel 3, the wire 9 contacting the flange 25 (Figure 3) of the coil former. In this case the pulley 26 (Figure 6) contacts the abutment 32 installed on the shaft 29. A clearance t equal to the maximum diameter of the wire 9 is provided between the pulley 26 and the abutment 31.

With the machine switched on, the spindle 4 (Figure 1) rotates and moves along the axis of the mandrel 3, causing movement of the shaft 29 (Figure 6). This starts the process of forming a wire turn in the plane perpendicular to the axis of the coil former, i.e. as the shaft 29 moves together with the spindle 4 (Figure 1) in the direction of the wire turn placement, the pulley 26 (Figure 6) remains in place under the action of wire tension or oscillates a little along the axis of the shaft 29.

After the wire placer 7 rotates about the wire approximately through 3600 C, the wire 9 (Figure 10) starts forming a second turn.

At the commencement of forming the second turn the portion of the wire 9 between the winding and the pulley 26 makes an angle a with the vertical, owing to which rise is given to an axial component acting in the direction of movement of the shaft 29. By the action of this force the pulley 26 moves on the shaft 29 in the direction of the wire turn placement and takes a position similar to the position of the pulley 26 (Figure 11) at the commencement of winding the first turn. The shaft 29 with the abutments 31 and 32 moves so that at the commencement of forming the first turn of the second layer the abutment 31 ensures that the portion of the wire 9 between the winding and the pulley 29 is perpendicular to the axis of the coil former.

At this instant the shaft 29 starts to be positively moved in the opposite direction and therefore the axial movement of the pulley 26 and of the sleeve 27 mounted thereon is limited by the abutment 32. Now the process of forming the turns of the second tier commences and the operation proceeds in this manner until the coil former is filled up with wire turns.

The wire placer 7 (Figure 1), apart from its major function of placing wire, acts as a wire tensioner. The tension of the wire 9 (Figure 6) on the pulley 26 is created by virtue of the wire 9 rubbing against the teeth 28 of the sleeve 27 and the action of the brake 30 on the pulley 26 which controls the braking moment of the pulley 26 and, accordingly, the tension of the wire 9. The teeth 28 prevent the sleeve from rotation with respect to the pulley 26.

The pulley 26 together with the sleeve 27 and the brake 30 moves relative to the shaft 29 in the direction of the wire turn placement. The abutments 31 and 32 installed on the shaft limit the free movement of the pulley 29 within the clearance t equal to the diameter of the wire 9, which is particularly necessary for excluding the influence of the dynamic components in transition from turn to turn and at the instant of reversal of the direction of the wire turn placement. The clearance t between the abutments 31,32 and the puliey 26, which is equal to the diameter of the wire 9, and the positive movment of the shaft 29 in winding one turn ensure the process of selfplacement of the wire 9 strictly for each turn. With the aid of the abutments 31 and 32 the pulley 26 is set in the initial position before winding the coil.

The combination of the wire placement and tension functions in one mechanism simplifies the machine and ensures high-quality placement of the wire. The combination of the principle of positive wire placement in a tier with selfplacement of the wire in a turn enhances the quality of wire placement by virtue of reducing the influence of inertia forces and vibration. There is no need of special devices for damping vibration in winding coils at high speed with a considerable winding aperture. This wire placer features a great advantage in that it can be used in modern hlgh- production winding machines of the rotary type, wherein the coil is stationary and the wire placer rotates. The use of such a machine for winding orthocyclic coils increases 2-2.5 times the productivity of the coil winding process. The use of the orthocyclic coil winding machine provides for enhancing the winding closeness and economizing up to 6 percent of wire.

In the proposed orthocyclic coil winding machine, correction of the winding pitch is accomplished as follows: With the machine switched on, the spindle 4 (Figure 12) rotates, acting on the count pickup 45 and the turn fill pickup 12. The signals from the pickup 45 give information on the wound turn, whereas the signals from the pickup 1 2 give information on the travel of the wire placer 7 through the pitch in winding the turn. These signals are fed into the amplifier 42, wherein they are processed and amplified. The amplified signal is sent to the actuating mechanism 35 which operates the correction unit 33 designed to vary the pitch of coil winding.

From the spindle 4 rotation is transmitted by the flat-toothed belt 34 to the input shaft 33' of the correction unit 33. From the input shaft 33' of the correction unit 33 rotation is transmitted to the output shaft 33", thence, via the flat-toothed belt 36, to the worm wheel drive 37 and therefrom to the cam 38. This cam operates a lengthwise placement mechanism and moves the lever 41 which is pivoted to the housing whereas the other end thereof mates with the abutment of the spindle 4. Thus the spindle 4 with the faceplate 6 and the wire placer 7 makes rotary and reciprocating movements and the wire placer 7 takes the wire 9 (Figure 1) in the winding space of the mandrel 3.

If the signals from the pickup 45 (Figure 12) and the pickup 12 come to the amplifier 42 simultaneously, the winding pitch need not be corrected and therefore the actuator 42 does not send a signal to the actuating mechanism 35.

If the signal from the pickup 45 comes later than the signal from the pickup 12, the amplifier 42 sends a signal to the actuating mechanism 35 and the latter operates the correction unit 33. The correction unit 33 slows down the worm wheel drive 37 through the operation of the output shaft 33D and the flat-toothed belt 36. The worm wheel drive 37 transmits the slower rotation to the cam 38 which mates with the roller 39 of the slide and operates, through the screw mechanism 40, the pivoted lever 41 and the spindle 4. The pivoted lever 41 transmits a slower reciprocating movement to the spindle 4, whereby the winding pitch is decreased. The correction of the winding pitch is effected until the signals from the pickups 45 and 12 comes to the amplifier 42 simultaneously.

If the signal from the pickup 45 comes earlier than the signal from the pickup 12, the amplifier 42 sends a signal to the actuating mechanism 35 which operates the correction unit 33 through a rigid link. The correction unit 33 speeds up the worm wheel drive through the operation of the output shaft 33" and the flat-toothed belt 36. The worm wheel drive 37 transmits the faster rotation to the shaft of the cam 38 which mates with the roller 39 of the slide and operates, through the screw mechanism 40, the pivoted lever 41 and the spindle 4. The pivoted lever 41 transmits a faster reciprocating movement to the spindle 4, whereby the winding pitch is increased. The correction of the winding pitch is effected until the signals from the pickups 45 and 12 come to the amplifier 42 simultaneously.

The employment of the proposed winding pitch correction controller provides for fuller and wider use of rotary winding equipment in the manufacture of windings.

The invention provides for simplifying the construction of the machine, increasing its working rate and enhancing the quality of orthocyclic windings.

Claims (5)

1. An orthocyclic coil winding machine comprising a bed, a turntable mounted on the bed and having several mandrels installed radially thereon, and a winding mechanism for winding coils of wire onto the mandrels in turn, each mandrel comprising a support device with a tapering surface portion, a head flange and a removable tail flange carried on the support device, and a plurality of elongate elements supported by the support device in respective radial slots and between the flanges, the elements being movable in the slots and having inclined inner surfaces cooperating with the taper surface of the support device forth elements to be displaced radially in response to relative axial movement between the elements and the support device.

2. An orthocyclic coil winding machine comprising a bed, a turntable mounted on the bed and having several mandrels installed radially thereon, and a winding mechanism for winding coils of wire onto the mandrels in turn, each mandrel including a body, a supporting sleeve having a tapering surface and mounted on the body, the sleeve supporting a slotted head flange, a removable tail flange, and a carrier provided with radial slots and positioned between the flanges, a plurality of sectors received in the radial slots of the carrier, and elastic rings extending about the sectors, the sectors having inclined inner surfaces cooperating with the taper surface of the supporting sleeve for displacing the sectors radially, and the outer surfaces of the sectors being toothed to form peripheral grooves.

3. A machine according to claim 2, wherein the winding mechanism includes a spindle on which is mounted a faceplate carrying a wire placer, the wire placer comprising a guide pulley mounted on a shaft, a tensioner including a rotatable sleeve having longitudinal slots for the wire to pass therethrough and mounted on the pulley shaft, and a brake device mounted on the rotatable sleeve and arrariged to contact the guide pulley, the guide pulley and the rotatable sleeve being axially movable on the pulley shaft through a distance limited by abutments and equal to the diameter of the wire being wound.

4. A machine according to claim 2 or 3, wherein a pitch correction control mechanism is provided to maintain the winding pitch within the preset limits, said mechanism comprising a correction unit mechanically linked with the rotary and axial drives of the winding spindle of the winding mechanism, and an actuating device for the correction unit having an electrical input connected with a control unit, the control unit being connected with a coil fill pickup responsive to axial displacement of the winding spindle and with a wire turn count pickup responsive to rotation of the winding spindle.

5. A coil winding machine substantially as herein described with reference to the accompanying drawings.