GB2049496A - Manufacturing commutators for electric rotating machines - Google Patents

Abstract

Shells for commutators are made by performing a number of forming operations on stock metal strip before the strip is cut into lengths and rolled into a cylinder. A roller (14) forms parallel transverse grooves (18) and ribs (19) in one side of the strip. Punches (26) cut slots (27) in alignment with the grooves (18) to form fingers along one edge of the strip. Knives (32), Figures 2,5 (not shown) skive under the ribs (19) to form anchors (41). Then the strip is cropped into lengths by a punch (43), bent into a cylinder by a two-stage press and forced through a tapered sizing die (61) Figure 7 (not shown). All operations are performed in automatic sequence on a multi-stage slide press machine. <IMAGE>

Description

1

GB 2 049 496 A 1

SPECIFICATION

Improvements in or relating to commutators for electric rotating machines

5

The present invention relates to commutators for electric rotating machines and in particular to a method of and an apparatus for making so-called commutator shells for use in the manufacture of 10 commutators.

A common method of manufacturing relatively low price commutators is to form a cylindrical shell of metal which is then moulded full of an electrically insulating material. The shell is then divided parallel 15 to the axis of the cylinder into a plurality of segments which form the segments of the finished commutator. An axial bore is normally provided through the moulding material in the centre of the cylinder for mounting the commutator on the rotor of the 20 machine in which it is to be used.

Normally, the metal cylinder or shell, before it is moulded and divided into segments, is shaped so as to provide some hook like extensions on the interior of the shell which serve as anchor members to hold 25 the finished segments of the commutator to the insulating moulding material. In one known arrangement, axial cuts are made into each end of the cylinder to produce fingers which are then bent inwards back on themselves to point inwards and 30 towards one another on the inside of the cylinder. These fingers then serve as anchor members. However, it is also usual in a commutator shell to provide further axially extending fingers at one end of the cylinder of the shell which are subsequently 35 bent outwards to form the winding hooks or tangs for connecting the windings of the machine to the respective segments of the commutator. Since it is desirable to make anchor members at both ends of the cylinder, it can be appreciated that at the end at 40 which the winding hooks are formed there may not be sufficient material to form both a winding hook and an anchor member. This problem is especially severe for commutators with relatively large numbers of segments.

45 Accordingly, it has been proposed to provide the interior of the cylinder of the shell with axially extending ribs which can then be undercut or skived at each end and bent inwards to provide the anchor members. Such an arrangement is disclosed in 50 British Patent Specification No.1,428,054. However, such a ribbed arrangement is relatively more difficult to produce especially for commutators with large numbers of segments.

The present invention is concerned primarily with 55 a method of and apparatus for making a commutator shell of the kind with interior axially extending ribs forming the anchor members.

According to the present invention a method of making commutator shells comprises forming,from 60 strip stock,metal strip ready for use as commutator shells when the formed strip is only cut into lengths and the lengths are formed in cylinders, said strip forming step including the steps of rolling the strip to produce on one side only of the strip integral ribs 65 extending normal to the length of the strip and then skiving under the ribs at both ends of the ribs and lifting said ends away from the rest of the strip to form anchor members forthe shells, and after said strip forming step the further steps of cutting the formed strip into predetermined lengths, bending said lengths into cylinders with the anchor members inwards and forcing the bent cylinders axially through a tapered sizing die to form the cylinders with smooth cylindrical outer surfaces of a desired diameter.

With this method, all the forming steps required to form stock strip into strip suitable for use as a commutator shell are performed before the strip is cut into lengths and bent into cylinders forming the shells. Once the strip is cut, bent into cylinders and forced through the sizing die, no further operations are required on the shell before the shell is used in the moulding step in forming a complete commutator. In this way, the production of commutator shells is very greatly facilitated and is made especially suitable for automation.

Normally, the ribs produced by the rolling step of the method of the invention extend only part way across the width of the strip, the strip having after the rolling step a longitudinally flat portion along one edge of the strip. Then, the strip forming step typically further includes the step of cutting slots through the strip extending into the flat portion from the adjacent edge of the strip so as to leave laterally extending fingers along the length of the strip, with the fingers substantially registering with the ribs produced by the rolling step. These fingers provide the winding hooks forthe finished commutator.

Preferably, after the rolling step the side of the strip opposite to said one side with the ribs is substantially flat right across its width, and said flat edge portion of the strip has, on said one side, a longitudinal step dividing the edge portion into an outer thinner part adjacent the edge of the strip and an innerthicker part which has a thickness not greater than the thickness of the strip between said ribs. Because the thicker part of the flat edge portion of the strip is no thicker than the thickness of the strip between said ribs, it can be seen that both ends of the ribs are accessible to a skiving tool to skive under the ends and lift them away from the rest of the strip. Further, at least the end parts of the laterally extending fingers of the strip are only as thick as said outer thinner part of the flat edge portion, so that the fingers can be relatively easily bent upwards to form the winding tangs. Moreover, the innerthicker part of the flat edge portion of the strip provides a more rigid support for when the windings of the electric machine are being secured to the winding hooks, as will be explained later herein.

Very conveniently, at least said outer thinner part of the flat edge portion of the strip is formed in said rolling step simultaneously with said ribs. Where only the outer thinner part is formed in said rolling step, the strip stock used in the method of the invention may have on one side a longitudinal step between a thicker portion for formation of said ribs . and a thinner portion for said flat edge portion of the strip.

70

75

80

85

90

95

100

105

110

115

120

125

130

2

GB 2 049 496 A

2

Preferably, the rolling step employs a toothed roller to form said ribs, the strip being fed between the toothed roller and pressure member so that the teeth of the roller are pressed into said one side of 5 the strip as the roller rotates to displace material of the strip to form said ribs.

Very conveniently, all said steps from said strip forming step to said step of forcing the bent cylinders through the sizing die are performed in 10 automatic sequence on a multiple stage slide press machine.

Multiple stage slide press machines are known and commercially available and are widely used for manufacturing articles from metal strip. Such a 15 machine can be tooled to perform in sequence a number of forming operations on the strip such as punching and bending and cutting operations.

The present invention further envisages commutator shells made by the method described above, 20 commutators formed from such shells and electric rotating machines containing such commutators.

Furthermore, the invention envisages a method of making a commutator using a commutator shell formed by the method described above and com-25 prising moulding insulating material inside said shell to form a commutator blank, and then dividing the shell with axial cuts between said ribs to form separate commutator segments, each with at least one pair of opposed said anchor members. Further, 30 after said moulding step said laterally extending fingers may be bent outwardly to form winding hooks for the commutator.

According to a further aspect of the present invention, there is provided apparatus for making 35 commutator shells, the apparatus comprising a multiple stage slide press machine having a plurality of work stages and being arranged to feed metal strip from stock from one stage to another whereby to perform in automatic sequence a plurality of 40 forming operations on said strip, a first work stage of the machine comprising a toothed roller and a pressure member co-operating therewith, the strip being fed from stock to said roller so that as the roller rotates, the teeth of the roller are pressed into 45 one side of the strip displacing metal to form integral ribs on said one side which extend normal to the length of strip, one or more subsequent work stages being arranged to form the ribbed strip into strip ready for use as commutator shells when the formed 50 strip is only cut into lengths and the lengths are formed into cylinders, the or one of the subsequent work stages comprising skiving means arranged to skive under the ends of the ribs and lift said ends away from the rest of the strip to form anchor 55 members for the shells, and one or more final work stages comprising, in a single or separate stages, means for cutting the formed strip into predetermined lengths, means for bending said lengths into cylinders with the anchor members inwards, and a 60 tapered sizing die and means for forcing the bent cylinders axially through the die to form the cylinders with smooth outer surfaces of a desired diameter.

An example of the invention will now be described 65 with reference to the accompanying drawings in which:

Figures 1 and 2 are corresponding schematic views in plan and elevation respectively illustrating various steps of a method of making commutator shells, referring to a plurality of stages of a multi stage slide press machine by which the method can be put into practice;

Figures 3 to 7 illustrate in greater detail stages 1 to 5 respectively referred to in Figures 1 and 2;

Figure 8 is a cross-sectional view of a complete commutator shell formed by the method or apparatus illustrated in Figures 1 to 7 and

Figure 9 is a partial cross-sectional view of a complete commutator made using the shell of Figure 8 showing a winding hook bent back to connect a winding to a segment of the commutator.

Figures 1 and 2 illustrate in outline the operation of various stages of a multi stage slide press machine which has been tooled up and arranged to make commutators from metal strip in accordance with an embodiment of the present invention. Multi stage slide press machines are well known and are commonly used for shaping and forming strip metal to produce small metal artifacts. Such machines typically have a number of stages and are arranged to transfer metal strip from stock from one stage to the next. A separate forming operation is performed at each stage. Typical forming operations are punching, cutting and bending.

In the example of the present invention illustrated in Figures 1 and 2 a multi stage slide press machine is adapted to have in effect five stages at which forming operations are performed on metal strip from stock to produce commutator shells. The metal strip normally used for commutators is copper strip. The strip 10 is fed to stage 1 of the machine from the right hand side in Figures 1 and 2. Stage 1 is illustrated in greater detail in Figure 3 and it can also be seen in Figure 3 that the stock strip 10 has a single step profile with a longitudinal step 11 dividing the stock strip into a thicker portion 12 and a thinner portion 13. A strip of such a stepped profile can readily be made by extruding.

The strip 10 is fed to stage 1 which comprises a toothed roller 14 which co-operates with a pressure pad 15. The pressure exerted on the strip 10 by the pressure pad 15 is sufficient to cause the teeth 16 of t the roller 14to penetrate into one side 17 of the strip 10 displacing material of the strip to form alternate grooves and ribs 18 and 19 respectively. The roller 14 is arranged to produce these alternate grooves and ribs 18 and 19 only in the thicker portion 12 of the strip and is arranged also so that the base of the grooves 18 approximately coincide with the level of the thinner portion 13 of the stock strip, i.e. the thickness of the strip in the grooves 18 is substantially equal to the thickness of the thinner portion 13 of the stock strip.

Coaxial with the roller 14 is a step forming wheel 20 which has a diameter slightly greater than the diameter of the circle through the tips of the teeth 16 of the roller 14. The wheel 20 is arranged to engage the thinner portion 13 of the stock strip 10 to produce a second longitudinal step 21 in the strip dividing the portion 13 itself into an outer thinner part 22

70

75

80

85

90

95

100

105

110

115

120

125

130

3

GB 2 049 496 A

3

adjacent the edge 23 of the strip and an innerthicker part 24.

As can been seen particularly well in Figure 3, the strip 25 emerging from stage 1 of the machine has 5 on the side 17 only ribs 19 which are normal to the length of strip. The ribs 19 extend only partway across the width of the strip 25 and the portions 22 and 24 of the strip form a longitudinally flat portion of the strip adjacent the edge 23.

10 The strip 25 from stage 1 of the machine, is fed to stage 2. Stage 2 comprises a series of punches 26 which are arranged to punch a corresponding series of slots 27 in the flat portion of the strip 25. The punches 26 co-operate with a die block 28 having a 15 series of cavities 29 for receiving the material punched out of the strip 25 by the punches 26. The punches 26 are spaced apart by amounts equal to the spacing of the ribs 18 of the strip 25. Further, the machine is arranged so that the punches 26 punch 20 the slots 27 at positions accurately corresponding to the grooves 18 between the ribs 19 so that the punched slots 27 leave behind laterally extending fingers 30 which register with the ribs 19. The number of punches 26 depends on the number of 25 segments in the commutator to be made from the shell produced by the machine. Thus, for example, if the shells are to be used in making twenty four segment commutators, then there are twenty five punches 26 arranged to produce twenty four fingers 30 30 registering with a series of twenty four ribs 19. The machine is conveniently arranged to operate stepwise, transferring the strip from stage to stage in the machine in steps and then halting the transfer for the forming operations of the various stages to be 35 made. Thus, between each punching operation in stage 2, the machine transfers the strip 25 by a distance slightly greater than a length of the strip having the desired number of ribs 18, i.e. twenty four for a twenty four segment commutator. 40 The slots 27 extend over the full width of the flat portion of the strip, i.e. over both the thinner and thicker parts 22 and 24.

The slotted and ribbed strip 31 from the second stage is then fed to stage 3. Stage 3 comprises a pair 45 of opposed skiving knives 32 arranged approximately in the plane of the strip directed at opposite edges thereof. The machine is arranged to drive the skiving knives 32 and 33 towards the strip in the direction of arrows 34 and 35 when the strip is halted during the 50 stepwise operation of the machine. The skiving knives are positioned so that their cutting edges 36 and 37 engage the ends of the ribs 19 substantially at the level of the grooves 18 between the ribs so as to skive under the ends of the ribs. The knives 32 and 33 55 are provided with bevels 38 and 39 to lift the ends of the ribs 19 away from the rest of the strip as illustrated in Figure 5 at 40. The knives 32 and 33 are made just long enough to skive simultaneously under the desired number of ribs for a single 60 commutator shell, i.e. twenty four for a commutator of twenty four segments. Furthermore, the knives are positioned so that the ribs which are skived simultaneously are those which correspond to the set of fingers 30 which was formed by a simul-65 taneous punching operation in stage 2. Although the skiving knives 32 and 33 are shown in Figure 5 with straightline cutting edges and plane bevels, the bevels 38 and 39 may in fact be formed slightly corrugated so that the grooves of the corrugation in 70 the bevels correspond with the ribs 19 during the skiving operation and ensure that the lifted end portions of the ribs 19 are retained correctly positioned and spaced relative to one another.

The lifted ends 41 of the ribs 19 produced by the 75. skiving knives 32 and 33 will form anchor members in the finished commutator shell.

The strip 42 emerging from stage 3 is fed by the machine to stage 4. In stage 4, two forming operations are performed on the strip. A crop punch 43 80 co-operating with a die 44 crops from the leading end of the strip 42 a predetermined length 45 of the strip. The length 45 is selected to include the desired number of ribs 18 and tongues 30 to produce a commutator shell with the desired number of seg-85 ments, in the present example 24. The machine automatically positions the strip 42 so that the crop punch 43 cuts off the length 45 at the correct position so that the length 45 can form when bent into a cylinder the desired commutator shell.

90 In the same stage, before the strip 42 is again moved forward by the machine, but after the crop punch cuts off the length 45, a forming punch 46 is moved in the direction of an arrow 47 towards the face of the strip having the anchor members. 95 Simultaneously, a spring loaded bending pad 48 is moved in the direction of an arrow 49 to engage the other plane side of the length 45. The form punch 46 and the bending pad 48 are provided with complimentary shapes so as to bend the ends 50 and 51 100 of the length 45 of the strip between them as illustrated in Figure 6. After bending, the ends 50 and 51 are directed at right angles to the rest of the length 45 and the bent portion of the length 45 is radiused with substantially the radius of the desired 105 cylinder into which the length 45 is to be bent to produce the complete commutator shell.

After stage 4, the machine transfers the bent strip 45 upwards, in Figure 2, transversely of the length of the strip to stage 5 in which again two forming 110 operations take place.

Firstly, in stage 5, the bent strip 45 is presented to a pair of forming dies 52 and 53. The forming dies 52 and 53 have opposed semi-cylindrical cut-outs 54 and 55 of substantially the same radius as the 115 cylinder into which the length 45 of strip is to be bent. The dies 52 and 53 are brought by the machine together in the directions of the arrows 56 and 57 so that the cut-outs 54 and 55 engage the bent ends 50 and 51 of the length 45 and further bend the length 120 45 into the complete cylinder shown at 58 in Figure 7.

Also in stage 4, after the length 45 is bent to the cylinder 58, the cylinder is forced axially in the direction of an arrow 59 into the inwardly tapering 125 entrance 60 of a sizing die 61. The upper end 62 of the bore in the sizing die 61, has a minimum diameter equal to the desired outer diameter of the formed commutator shells produced by the machine so that the cylinders 58 pushed through the die 61 in 130 successive stepwise operations of the machine are

4

GB 2 049 496 A

4

slightly compressed by the sizing die to have the desired smooth outer diameter. By using the sizing die 61 in this way, any irregularities in the outer peripheral surface of the cylinder 58 are smoothed 5 out. The commutator sheels produced by the machine are formed with precisely the desired outer diameters so that no further machining is required after the shells are divided to form the segments of the complete commutator. In this context it will be 10 understood that it is common practice for the manufacturer of the rotating electric machine to provide a final machining of the commutator after the commutator has been mounted on the rotor axis of the machine to ensure that the segment surfaces 15 are perfectly symmetrical relative to the axis of rotation of the machine's rotor. However, commutators made from commutator shells formed as described above require no further machining before being supplied to the electrical machine manufactur-20 erfor incorporation in a machine.

A completed commutator shell formed by the machine illustrated in Figures 1 to 7 is illustrated, in schematic form, in Figure 8. As can clearly be seen in Figure 8, each finger 30 at the right hand end of the 25 cylinder of the shell registers with a rib 19 the ends of which are lifted from the rest of the shell to form anchor members 41. Further as also illustrated in Figure 8, the step 21 formed by stage 1 of the machine is clearly visible and the slots 27 between 30 the fingers 30 extend right across the full width of the flat portion of the strip to the adjacent ends of the ribs 18, so that the fingers 30 include outerthinner parts 63, corresponding to the thinner part 22 of the strip 25 after stage 1, and innerthicker parts 64, 35 corresponding to the thicker part 24 of the strip 25.

When the shell illustrated in Figure 8 is used to make a commutator, the interior of the shell is filled with an electrically insulating mouldable material so that the anchor members 41 become completely 40 embedded in this material, indicated at 65 in Figure 9. A bore may be provided through the centre of the mouldable material 65 for mounting the commutator on a suitable shaft. After moulding, the shell is divided into the various segments of the commuta-45 tor by axial cuts between adjacent ribs and fingers 30, so that in the twenty four segment example described herein, each segment has a single pair of anchor members 41, formed by a single rib 18, with a single finger 30 extending from one end. 50 The fingers 30 of each of the segments can then be bent outwards to the position shown in ghost in Figure 9 to serve as winding hooks or tangs for connecting the rotor windings to the commutator. This is normally done by locating the winding wire 55 behind the bent up hook and then pressing the hook firmly down onto the winding as shown in Figure 9. The thicker portions 64 of the fingers 30 provide strengthened regions to withstand the axially inward force when the hooks are pressed down onto the 60 wires of the windings.

The entire operation of forming the commutator shells, as described in the above example, can be performed automatically on the multi stage slide press machine thereby greatly reducing the cost of 65 producing these shells whilst ensuring that the shells are produced to a relatively tight tolerance and have anchor members enabling the separated segments of the commutator to be firmly anchored to the moulded material ofthe commutator.

70

Claims (16)

1. A method of making commutator shells comprising forming from strip stock metal strip ready for ' 75 use as commutator shells when the formed strip is only cut into lengths and the lengths are formed into cylinders, said strip forming step including the steps ' of rolling the strip to produce on one side only ofthe strip integral ribs extending normal to the length of 80 the strip and then skiving under the ribs at both ends ofthe ribs and lifting said ends away from the rest of the strip to form anchor members for the shells, and after said strip forming step the further steps of cutting the formed strip into predetermined lengths, 85 bending said lengths into cylinders with the anchor members inwards and forcing the bent cylinders axially through a tapered sizing die to form the cylinders with smooth cylindrical outer surfaces of a desired diameter.

90

2. A method of making commutator shells as claimed in claim 1 wherein the ribs produced by the rolling step extend only part way across the width of the strip, the strip having after the rolling step a longitudinally flat portion along one edge ofthe 95 strip, and wherein the strip forming step further includes the step of cutting slots through the strip extending into the flat portion from the adjacent edge ofthe strip so as to leave laterally extending fingers along the length ofthe strip, with the fingers

100 substantially registering with the ribs produced by the rolling step.

3. A method of making commutator shells as claimed in claim 2 wherein after the rolling step the side ofthe strip opposite to said one side with the

105 ribs is substantially flat right across its width, and said flat edge portion of the strip has, on said one side, a longitudinal step dividing the edge portion into an outerthinner part adjacent the edge ofthe strip and an innerthicker part which has a thickness -

110 not greater than the thickness ofthe strip between said ribs.

4. A method of making commutator shells as claimed in claim 3, wherein at least said outer thinner part of the flat edge portion of the strip is

115 formed in said rolling step simulataneously with said ribs.

5. A method of making commutatorshells as claimed in any of claims 2 to 4 wherein the strip stock has on one side a longitudinal step between a

120 thicker portion for the formation of said ribs and a thinner portion for said flat edge portion.

6. A method of making commutator shells as claimed in any preceding claim, wherein the rolling step employs a toothed roller to form said ribs, the

125 strip being fed between the toothed roller and a pressure member so that the teeth ofthe roller are pressed into said one side of the strip as the roller rotates to displace metal ofthe strip to form said ribs.

130

7. A method of making commutatorshells as

5

GB 2 049 496 A 5

claimed in claim 6 wherein all said steps from said strip forming step to said step of forcing the bent cylinders through the sizing die are performed in automatic sequence on a multiple stage slide press 5 machine.

8. A method of making commutator shells substantially as hereinbefore claimed with reference to the accompanying drawings.

9. A commutator shell made bythe method of 10 any of claims 1 to 8.

10. A com mutator formed from a shell as claimed in claim 9.

11. An electric rotating machine having a commutator as claimed in claim 10.

15

12. A method of making a commutator using a commutator shell as claimed in claim 9, comprising moulding insulating material inside said shell to form a commutator blank, and then dividing the shell with axial cuts between said ribs to form 20 separate commutator segments each with at least one pair of opposed said anchor members.

13. A method of making a commutator as claimed in claim 12, where claim 9 is dependent on any of claims 2 to 5 or claim 8 or claims 6 or 7 as

25 appendant to any of claims 2 to 5, wherein after said moulding step said laterally extending fingers are bent outwardly to form winding hooks forthe commutator.

14. A commutator made by the method of either 30 of claims 12 and 13.

15. An electric rotating machine having a commutator as claimed in claim 14.

16. Apparatus for making commutator shells, the apparatus comprising a multiple stage slide press

35 machine having a plurality of work stages and being arranged to feed metal strip from stock from one stage to another whereby to perform in automatic sequence a plurality of forming operations on said strip, a first work stage ofthe machine comprising a 40 toothed roller and pressure member co-operating therewith, the strip being fed from stock to said roller so that as the roller rotates, the teeth ofthe roller are pressed into one side ofthe strip displacing metal to form integral ribs on said one side which extend 45 normal to the length ofthe strip, one or more subsequent work stages arranged to form the ribbed strip into strip ready for use as commutator shells when the formed strip is only cut into lengths and the lengths are formed into cylinders, the or one of 50 the subsequent work stages comprising skiving means arranged to skive underthe ends ofthe ribs and lift said ends away from the rest ofthe strip to form anchor members forthe shells, and one or more final work stages comprising, in a single or 55 separate stages, means for cutting the formed strip into predetermined lengths, means for bending such lengths into cylinders with the anchor members inwards, and a tapered sizing die and means for forcing the bent cylinders axially through the die to 60 form the cylinders with smooth cylindrical outer surfaces of a desired diameter.

Printed for Her Majesty's Stationery Office by Croydon Printing Company Limited, Croydon Surrey, 1980.

Published bythe Patent Office, 25 Southampton Buildings, London, WC2A1AY, from which copies may be obtained.