FR2738686A1 - MAGNETO GENERATOR - Google Patents

Abstract

A magneto is fixed by its armature (7) on a fixing base (23, 33), its rotor can be driven by a rotating shaft, either of small diameter or of large diameter. The armature is fixed to the base by interlocking. To allow the mounting of identical armatures, either on a base (23) provided for a small diameter shaft or on a base (33) provided for a large diameter shaft, the internal (or female) interlocking part (12 ) of the armature core comprises two internal fitting parts: one (13) whose inner diameter (D13) is designed to cooperate with the outer (or male) fitting part of small diameter (26) of a small diameter base (23), and the other (14) whose inner diameter (D14) is provided to cooperate with the large diameter outer (or male) fitting part (44) of a large diameter base diameter (33).

Description

Magnetogenerator The present invention relates to a magneto-generator

  (hereinafter simply called magneto), and more particularly construction improvements for mounting a magneto on mounting bases of an armature; it also relates to a magneto preferable for mounting on the

  engine of a motorcycle, for example.

  As magneto preferable for mounting on a motorcycle-

  te, there is one comprising a generally bowl-shaped rotor rotating around an armature fixed on a mounting base. In conventional magnetos of this type, the mounting bases are formed on the casing of a motor intended to drive the armature in rotation or on a cover fixed to this casing to cover the whole of the magneto; the armature is positioned on the mounting base by a snap joint and is fixed by bolts. In other words, an internal interlocking portion formed on the core of the armature is assembled by interlocking with an outer interlocking portion formed on the mounting base, whereby an air gap is formed between the armature fixed on the mounting base by this interlocking joint and the rotor connected to the

crankshaft of the engine.

  In recent years, depending on the types of vehicles and as measures to account for engine noise, the diameter of the rotating shaft connecting the magneto rotor to the crankshaft of the engine has been increased so that

  increase the stiffness of the rotating shaft.

  However, if one only increases the diameter of the inner interlocking portion of the armature core to correspond to the increase in the diameter of the rotary shaft, one can be confronted with the following disadvantages: (1) It can at least two types of armatures having different characteristics are required: one of the armatures comprises an armature core having a characteristic corresponding to the increased diameter of the rotary shaft and the other armature comprises an armature core having a corresponding characteristic

with the initial rotary shaft.

  (2) If the positions and dimensions of the through holes for the armature core bolts and threaded holes for mounting bracket mounting bolts are changed

  to account for the increased diameter of the nib portion

  internally, then it is necessary to change the characteristics

  armature core and mounting bases.

  (3) If the thickness of the winding wires of an armature coil is reduced so long as the internal interlocking portion has an increased diameter, then the output power of the

magneto is reduced.

  It is an object of the present invention to provide a magneto, in which inductors of identical characteristics may be snap-fitted on each of the mounting bases, the through-holes of which

  rotary shaft have different inner diameters.

  The present invention is characterized in that, in an internal fitting portion of an armature core of the magneto, a small diameter internal interlocking portion is formed, the inside diameter of which is adapted to cooperate with a a small diameter outer interlocking portion of a mounting base, and a large diameter inner interlocking portion whose inner diameter is adapted to cooperate with an outer interlocking portion of

  large diameter of a mounting base.

  In the magneto described above, when the armature is fixed on a mounting base, in which is drilled an insertion hole for a small diameter rotary shaft, a small diameter inner interlocking portion is joined by interlocking with a small diameter outer interlocking portion of the mounting base. In addition, when the same armature is attached to a mounting base in which is drilled an insertion hole for a rotary shaft of large diameter, a large diameter inner interlocking portion is joined by interlocking with an interlocking portion external large diameter of the mounting base. Thanks to the means described above, it is possible to fix armatures having identical characteristics on each of the mounting bases in which the insertion holes for a

  rotary shaft have different inner diameters.

  The invention will be better understood on reading the description of

  following illustration, given by way of example only, of a preferred embodiment, in conjunction with the accompanying drawing, in which:

  - Figure 1 shows the essential parts of a

  Magneto according to the present invention, Fig. 1 (a) being an oblique view showing an armature, Fig. 1 (b) being an oblique view showing a mounting base for a small diameter rotary shaft, and Fig. 1 (c) being an oblique view showing a mounting base for a large diameter rotary shaft; - Figure 2 is a longitudinal sectional view showing the magneto using a mounting base for a rotary shaft of small diameter; - Figure 3 is a longitudinal sectional view showing the magneto using a mounting base for a large diameter rotary shaft; and - Figure 4 shows the armature, Figure 4 (a) being a front view and Figure 4 (b) being a sectional view taken

  along the line b-b in Figure 4 (a).

  We will now describe the preferred embodiment. In this embodiment, a magneto according to the present invention is constructed to be mounted on a motorcycle and includes a rotor and an armature therein. The rotor 2 is constructed so that several magnets 4, as pole pieces, are fixed at regular intervals on the inner peripheral surface of a side wall portion of a yoke 3 formed in the general shape of a bowl. The rotor 2 is secured in rotation to a rotary shaft 6 driven by a

  motor, not shown, of a motorcycle, through

  3. An armature 7 of this magneto 1 comprises a multiplicity of armature coils 8. Each armature coil 8 is constructed so that a winding wire is wound for forming a coil around each of a multiplicity of salient poles 10, each of said salient poles projecting radially from the outer periphery of a core 9. The core 9 is constructed so that a multiplicity of thin iron sheets are laminated in one piece, each of these thin sheets of iron having substantially the same

  form and constituting a flat structure. A receiving hole

  it is provided at the central part of the core 9, concentric with this core, and the receiving hole 11 can

receive the boss 5 and the shaft 6.

  An internal nesting portion 12 is provided at an end portion of this receiving hole 11 on the opposite side of the boss 5, and concentric with this receiving hole 11. The internal nesting portion 12 includes a portion

  interlocking small diameter 13, which practically

  the same inner diameter D 13 as the inner diameter of the receiving hole 11, and is intended to be snap-fitted on a small diameter outer interlocking portion 26 of a mounting base 23 for a rotary shaft of

  small diameter, which will be described below. The nesting part

  Inner element 12 also comprises a large-diameter inner interlocking portion 14 whose inside diameter D 14 is larger than the inside diameter D 13 of the small-diameter interlocking portion 13, and is intended to be fitted by interlocking. on a large diameter outer interlocking portion 44 of a mounting base 33 for

  rotary shaft of large diameter, which will be described below.

  after. In other words, the small diameter inner interlocking portion 13 has an inner diameter D13 intended to be equal to the inside diameter of the receiving hole 11 and is substantially formed by the inner peripheral surface of an end portion of the receiving hole 11 The large-diameter inner interlocking portion 14 is formed by the bottom surfaces of two longitudinal grooves 15 radially outwardly outwardly on the inner peripheral surface of the interlocking portion.

  small diameter inner groove 13. The two longitudinal grooves

  the 15 and 15 are formed symmetrical in rotation with respect to 1, the central axis of the core 9, they are recessed from the same depth towards the outside in the radial direction and have

  appropriate width greater than a predetermined tolerance

  born in the circumferential direction, being parallel to the central axis of the core 9 respectively. The inner diameter D14 of the large diameter inner interlocking portion 14 is formed by the inner diameters of the

  bottom surfaces of the grooves 15 and 15.

  In the core 9, two insertion holes 17 for introducing bolts 16 for attaching the armature 7 to a mounting base are located at positions spaced 180 apart from each other on a circle concentric with the center of the core 9 and they extend in the axial direction. The two bolt insertion holes 17 and 17 are formed so as not to interfere with the two longitudinal grooves 15 and 15. The two bolt insertion holes 17 and 17 are intended to serve both in the case of the mounting base for the large diameter shaft and that of the mounting base for the small diameter shaft, as it

will be described below.

  As shown in Figures 2 and 3, the rotating shaft driving the magnet 1 is projected into the motor housing 21 and a cover 22, constituting a machine base in cooperation with the motor housing 21, is fixed on the housing 21 so as to surround the magneto 1. The small diameter mounting base 23 or the large diameter mounting base 33, these two bases being formed to provide substantially cylindrical shapes, projects around the rotating shaft in the cover 22 of the crankcase 21,

concentric to the rotating shaft.

  A hollow portion in the cylindrical shape of the small diameter mounting base 23 forms a small diameter introducer hole 24 for receiving the small rotary shaft.

  diameter 6, and the inside diameter D24 of the insertion hole

  The small diameter diameter 24 is provided to be greater than the outer diameter D6 of the small diameter rotating shaft 6 of a predetermined size. A hollow part in the cylindrical shape of the large-diameter mounting seat 33 forms a large-diameter insertion hole 34 for receiving a large diameter rotary shaft 36 and the inner diameter D34 of the large-diameter introduction hole 34 is provided to be greater than the outer diameter D36 of

  the large-diameter rotating shaft 36 of a predetermined size

  completed. Two threaded holes 25 provided for fixing the bolts 16 are respectively provided on the outer peripheries of the mounting bases, small diameter 23 and large diameter 33, at the insertion side in the cover 22, said threaded holes 25 being in vis-à-vis

  17 bolt introduction holes of the respective

  7. Tapped holes 25 are provided to have the same provisions in the positions, diameters, etc., both in the case of the small diameter mounting base 23 and in that of the mounting mounting base. great

diameter 33.

  In the small diameter mounting base 23, the short cylindrical outer diameter small interlocking portion 26 is integrally formed and extends in the axial concentric direction to the small mounting base.

  diameter 23 at the introduction side in the cover

  cle 22, as shown in Figure 2 and Figure l (b). The outer diameter D26 of the small diameter outer engaging portion 26 is provided to be equal to the inner diameter D13 of the small diameter inner interlocking portion 13 so that the small diameter outer nesting portion 26 can be mounted by nesting on the

  internal interlocking portion of small diameter 13 of the in-

duit 7.

  On the other hand, the inside diameter D34 of the introducer hole

  34 for the large diameter rotary shaft of the large diameter mounting base 33 is provided to be equal to the inner diameter D13 of the small diameter inner interlocking portion 13 of the armature 7, and thereby , the inner diameter D34 is greater than the inside diameter D24 of the insertion hole 24 of the rotary shaft of small diameter of

  the small diameter mounting base 23. The nesting part

  The large diameter outer portion 44 corresponding to the large diameter inner interlocking portion 14 of the armature 7 projects into the end surface of the large diameter mounting base 33 at the side to be inserted into the cover 22. This large diameter outer interlocking portion 44 is formed by the outer peripheral surfaces of two curved, circle-shaped walls 45 projecting at a marginal portion of an opening of the insertion hole 34 for the shaft. large-diameter rotator provided at an end surface of the large-diameter mounting base 33. The two walls

  curved 45 and 45 are formed symmetrically

  rotating in relation to the central axis of the hole

  ducting 34 for the rotary shaft of large diameter, and

  projects from the same depth to the outside

  in the radial direction, having an appropriate width greater than a predetermined tolerance in the circumferential direction, being parallel to an extension of the central axis of the insertion hole 34 for the large diameter rotary shaft, respectively. The outer diameter D44 of the large diameter outer interlocking portion 44 is formed by the outer diameter of the outer peripheral surfaces of the two circle-shaped curved walls 45 and 45. These curved circle-shaped walls 45 are respectively adapted to cooperate with each other. with the

  respective longitudinal grooves 15 of the armature 7.

  We will now describe the assembly operations of the armature. When the armature 7 is mounted on the small diameter mounting base 23, the small diameter inner interlocking portion 13 of the armature 7 is joined by interlocking with the small diameter outer interlocking portion 26 of the armature. small diameter mounting base 23. Then bolts 16 are inserted into the bolt insertion holes 17 of the armature 7 and are screwed into the threaded holes 25 of the small diameter mounting base 23, the armature 7 is thus fixed on the small diameter mounting base 23. In this assembled state, the armature 7 is fixed on the small diameter mounting base 23 in a state in which the armature 7 is aligned and accurately centered with the small diameter mounting base 23 by the interlocking junction between the small diameter inner interlocking portion 13 and the outer small interlocking portion

diameter 26.

  When the armature 7 is mounted on the large-diameter mounting base 33, the large-diameter inner interlocking portion 14 of the armature 7 is joined by interlocking with the large-diameter outer interlocking portion 44 of the armature. In other words, the two longitudinal grooves 15 and 15 of the armature 7 cooperate respectively with the two circularly curved walls 45 and 45 of the large diameter mounting base 33, which are next to the two longitudinal grooves 15 and 15 of the armature 7. Then, the bolts 16 are introduced into the bolt introduction holes 17 of the armature 7 and are screwed into the threaded holes 25 of the armature 17. the large diameter mounting base 33; the armature 7 is thus fixed on the large-diameter mounting base 33 in a state in which the armature 7 is precisely aligned and centered with the large-diameter mounting base 33 by the interlocking connection between the internal fitting portion of large diameter 14 and the outer interlocking portion of large

diameter 44.

  As described above, in this embodiment, the same armature 7 can be mounted indifferently on the small diameter mounting base 23 and on the large diameter mounting base 33, so that, without having to retouch the 7, it is possible to take into account the increase in diameter from the small-diameter rotating shaft 6 to the large diameter rotary shaft 36. Until now, when passing from the rotary shaft of small 6 to the rotary shaft of large diameter 36, it was necessary to open the insertion hole 34 for the large diameter rotary shaft in the large diameter mounting base 33 to introduce the rotary shaft large diameter 36; therefore, some

  external nesting, which is formed around the insertion hole

  ducting 34 for the large-diameter rotary shaft, was to be increased in diameter and the internal fitting portion 12 on the side of the armature 7 was to be increased in diameter

  in correspondence with this. However, in this realization

  tion, the large diameter inner interlocking portion 14 on the side of the armature 7 is formed by the grooves

  longitudinal projections provided on the peripheral surface

  In the interior of the receiving hole 11, the large diameter outer engaging portion 44 on the side of the large diameter mounting base 33 is formed by the curved circle-shaped walls 45 to cooperate with the longitudinal grooves 15. so that armatures 7 of identical characteristics can be mounted on the large-diameter mounting base 33, which can also be used as a small diameter mounting base 23. Consequently, even if the diameter of the rotary shaft, the thickness of the winding wires of the armature coils 7 is not reduced so that the power output of the magneto i can be prevented from being reduced by

  the increase in diameter of the rotating shaft.

  In addition, it is arranged in this embodiment for the bolt introduction holes 17 do not interfere with the

  longitudinal grooves 15 constituting the nesting portion

  large internal diameter 14 in the armature 7 and that the threaded holes 25 do not interfere with the curved walls in the form of a circle 45 constituting the large diameter outer interlocking portion 44 in the small mounting base As a result, it is not necessary to change the positions and arrangements of the bolt insertion holes 17 and the threaded holes 25 in the armature 7. the small diameter mounting base 23 and the base of

large diameter mounting 33.

  The present invention need not be limited to the embodiment described above and may be modified in various ways while remaining within the scope of the present invention.

present invention.

  For example, the number of longitudinal grooves 15 constituting the large diameter inner interlocking portion 14 and the number of curved circle-shaped walls 45 constituting the large-diameter outer interlocking portion 44 are not necessarily limited to two, but they

  can be equal to three, or more.

  As described above, it is possible to mount by

  armature cores of the same characteristics on mounting bases having rotary shaft introduction holes of different inner diameters so that, without any change in the characteristics of the magneto, the increase in of diameter

  of the rotating shaft driving the magneto.

1l

Claims (10)

claims   1. Magneto (1), wherein an inner interlocking portion (12) formed on the core (9) of the armature (7) is snap-fitted on an outer interlocking portion formed on a mounting base, characterized in that said inner interlocking portion of the core comprises: a small diameter inner interlocking portion (13) whose inner diameter is adapted to cooperate with a small diameter outer interlocking portion (26) of said base mounting (23); and a large diameter inner interlocking portion (14) whose inner diameter is adapted to cooperate with a large diameter outer interlocking portion (44) of said base mounting (33).   2. Magneto (1) according to claim 1, further comprising a receiving hole (12) for receiving therethrough a boss (5) and a rotary shaft (6), characterized in that the inside diameter of said part d internal interlocking of small diameter (13) is equal to the inside diameter said receiving hole (11).   3. Magneto (1) according to claim 2, characterized in that said small diameter inner interlocking portion (13) is substantially formed by the inner peripheral surface of an end portion of said receiving hole (11). 4. Magneto (1) according to claim 1, characterized in that said large diameter inner interlocking portion (14) is formed by the bottom surfaces of two longitudinal grooves (15) recessed outwardly in the direction radial on the inner peripheral surface of   said small diameter inner interlocking portion (13).   5. Magneto (1) according to claim 4, characterized in that   that the two longitudinal grooves (15) are formed symmetrically   rotating in relation to the central axis of said core (9). 6. Magneto (1) according to claim 1, characterized in that said mounting base comprises a small diameter mounting base (23) or a mounting base of large   diameter (33), both being formed into a practical form cylindrical.   7. Magneto (1) according to claim 6, characterized in that a hollow portion of said small diameter mounting base (23) forms a small diameter insertion hole (24) for receiving a small diameter rotary shaft (6), and   in that the inside diameter (D24) of said introducer hole   small diameter (24) is provided to be larger than the outer diameter (D6) of said small diameter rotary shaft (6). A magnetoid (1 () according to claim 6, characterized in that a hollow portion in said large diameter mounting base (33) forms a large diameter insertion hole (34) for receiving a large rotary shaft diameter (36) and in that the inner diameter (D34) of said large-diameter insertion hole (34) is provided to be greater than the outer diameter (D36) of said shaft large diameter rotator (36).   9. Magneto (1) according to claim 6, characterized in that a small diameter outer interlocking portion (26) is formed in said small diameter mounting base   (23) so as to extend in the axial direction.   10. Magneto (1) according to claim 6, characterized in that a large-diameter outer interlocking portion (44) projects into the end surface of said large-diameter mounting base (33) at the outer side. inserting into a cover (22), said outer interlocking portion   large diameter (44) being formed by peripheral surfaces   outer circumferences of two circularly curved walls (45) projecting at a marginal portion of an opening of said large diameter insertion hole (34) provided at a marginal surface of said large diameter mounting base (33).