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Claims  |
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What is claimed is:
1. A starter for an engine comprising:
a motor means comprising an armature which includes a hollow armature
rotary shaft and an armature core mounted on the outer periphery of said
armature rotary shaft;
an overrunning clutch means comprising a clutch over member and a clutch
inner member, for transmitting the rotative force of said motor means to
said clutch inner member, said overrunning clutch means being coaxially
disposed within said hollow armature rotary shaft;
said clutch outer member comprising said hollow armature rotary shaft;
said clutch inner member comprising a tubular member coaxially received and
rotatably supported within said armature rotary shaft;
an output rotary shaft means coaxially disposed within said clutch inner
member and supported slidably in the axial direction;
an epicylic reduction gear train means for transmitting the rotative force
of said clutch inner member to said output rotary shaft means without
preventing the axial sliding motion of said output rotary shaft;
means for sliding said output rotary shaft in the axial direction.
2. A starter as claimed in claim 1 in which said overrunning clutch further
comprises:
cam surfaces formed on the inner peripheral surface of said armature rotary
shaft;
wedge-shaped spaces defined between said cam surfaces and the outer
peripheral surface of said clutch inner member;
and at least one roller disposed in each of said wedge-shaped spaces for
transmitting the rotative force of said armature rotary shaft to said
clutch inner member when said rollers provide engagement between said cam
surface and said outer peripheral surface of said clutch inner member.
3. A starter as claimed in claim 2 in which said epicyclic reduction gear
train further comprises:
a sun gear formed on said clutch inner member, an internal gear fixedly
disposed around said sun gear, planet gears meshed with both said sun gear
and sun internal gear, and a carrier rotatably disposed adjacent to said
planet gears so as to support said planet gears rotatably.
4. A starter as claimed in claim 3 wherein said armature core is
press-fitted on the outer peripheral portion of said armature rotary
shaft.
5. A starter as claimed in claim 4 wherein said clutch inner member is
rotatably supported through a bearing which is disposed at the end of said
armature rotary shaft.
6. A starter as claimed in claim 5 wherein a spring is disposed in each of
said wedge-shaped spaces so as to press said rollers in a direction in
which said rollers provide engagement between said cam surface and said
outer peripheral surface of said clutch inner member.
7. A starter as claimed in claim 6 wherein said sun gear is formed on the
outer peripheral surface of said clutch inner member.
8. A starter as claimed in claim 7 wherein said internal gear is formed on
a center bracket of a yoke of said motor means.
9. A starter as claimed in claim 8 wherein said motor means comprises a
d.c. motor.
10. A starter according to claim 9 wherein said means for transmitting the
rotative force of said carrier to said output rotary shaft is a tubular
member which engages with said output rotary shaft through a spline formed
in the outer peripheral surface of said output rotary shaft.
11. A starter as claimed in claim 10 wherein said tubular member is formed
integral with said carrier.
12. A starter as claimed in claim 11 wherein said means for sliding said
output rotary shaft in the axial direction is an electromagnetic switch
which is coaxially disposed with and arranged to cause said output rotary
shaft to slide at the same time as said d.c. motor is energized.
13. A starter as claimed in claim 12 wherein springs are disposed between
said output rotary shaft and said electromagnetic switch.
14. A starter as claimed in claim 13 wherein a pinion is formed at the
distal end of said output rotary shaft.
15. A starter for an engine comprising:
a motor having an armature which includes a hollow armature rotary shaft
and an armature core mounted on the outer periphery of said armature
rotary shaft;
an overrunning clutch coaxially disposed within said hollow armature rotary
shaft, said overrunning clutch comprising:
a clutch outer member comprising said hollow armature rotary shaft, cam
surface formed on the inner peripheral surface of said armature rotary
shaft, a tubular clutch inner member coaxially received and rotatably
supported inside said armature rotary shaft, wedge-shaped spaces defined
between said cam surfaces and the outer peripheral surface of said clutch
inner member, and at least one roller disposed in each of said
wedge-shaped spaces for transmitting the rotative forces of said armature
rotary shaft to said clutch inner member when said rollers provide
engagement between said cam surface and said outer peripheral surface of
said clutch inner member;
an output rotary shaft coaxially disposed inside said clutch inner member
and supported slidably in the axial direction;
an epicyclic reduction train for transmitting the rotative force of said
clutch inner member to said output rotary shaft, comprising a sun gear
formed on said clutch inner member, an internal gear fixedly disposed
around said sun gear, planet gears meshed with both said sun gear and said
internal gear, and a carrier rotatably disposed adjacent to said planet
gears so as to support said planet gears rotatably;
means for transmitting the rotative force of said carrier to said output
rotary shaft without preventing the axial sliding motion of said output
rotary shaft;
a pinion formed at the distal end of said output rotary shaft; and
means for sliding said output rotary shaft in the axial direction;
whereby the overrunning clutch is mounted within the hollow armature rotary
shaft that also serves as the clutch outer member of the overrunning
clutch, and the clutch inner member of the overrunning clutch engages with
the epicyclic reduction train through the sun gear formed on the clutch
inner member.
16. A starter according to claim 15, wherein said armature core is
press-fitted on the outer peripheral portion of said armature rotary
shaft.
17. A starter according to claim 15, wherein said clutch inner member is
rotatably supported through a bearing which is disposed at the end of said
armature rotary shaft.
18. A starter according to claim 15, wherein a spring is disposed in each
of said wedge-shaped spaces so as to press said rollers in a direction in
which said rollers provide engagement between said cam surface and said
outer peripheral surface of said clutch inner member.
19. A starter according to claim 15, wherein said sun gear is formed on the
outer peripheral surface of said clutch inner member.
20. A starter according to claim 15, wherein said internal gear is formed
on a center bracket of a yoke of said motor.
21. A starter according to claim 15, wherein said motor is a d.c. motor.
22. A starter according to claim 15, wherein said means for transmitting
the rotative force of said carrier to said output rotary shaft is a
tubular member which engages with said output rotary shaft through a
spline formed in the outer peripheral surface of said output rotary shaft.
23. A starter according to claim 22, wherein said tubular member is formed
integral with said carrier.
24. A starter according to claim 15, wherein said means for sliding said
output rotary shaft in the axial direction is an electromagnetic switch
which is arranged to cause said output rotary shaft to slide at the same
time as said d.c. motor is energized.
25. A starter according to claim 24, wherein springs are disposed between
said output rotary shaft and said electromagnetic switch. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a starter for an engine and, more
particularly, to a coaxial type starter used to start an engine of a
vehicle.
2. Description of the Prior Art
A conventional starter used to start an engine of a vehicle has heretofore
been arranged as shown in FIG. 3.
The conventional starter 1 shown in FIG. 3 comprises a d.c. motor 2, an
overrunning clutch 4 slidably fitted on an output rotary shaft 3, a
reduction gear 5 arranged to transmit the rotational force derived from an
armature rotary shaft 2a of the d.c. motor 2 to a clutch outer member 4a
of the overrunning clutch 4 after reducing the speed thereof, and a shift
lever 8 having one end thereof engaged with a plunger rod of an
electromagnetic switch 6 disposed at one side of the d.c. motor 2 and the
other end thereof engaged with an annular member 7 secured to the
overrunning clutch 4 in order to cause the overrunning clutch 4 to slide
on the output rotary shaft 3.
Thus, the conventional starter 1 needs the shift lever 8 in order to cause
the overrunning clutch 4 to slide on the output rotary shaft 3, and the
electromagnetic switch 6 which actuates the shift lever 8 and also turns
on the power supply for the d.c. motor 2 is disposed at the side of the
d.c. motor 2, that is, the starter 1 has the so-called biaxial
arrangement. Therefore, the types of engine layout that have been feasible
when designing a vehicle have heretofore been restricted to a substantial
extent.
In order to avoid the above-described problem, it has been proposed to
dispose the electromagnetic switch at one axial end of the d.c. motor so
that the starter may have a simple configuration such as a relatively long
and narrow tubular shape. According to this proposition, the starter is
basically arranged such that the armature rotary shaft of the d.c. motor
is made hollow and a rod, for example, a plunger rod, of the
electromagnetic switch which has heretofore been used to actuate the shift
lever is passed through the passage formed inside the armature rotary
shaft so as to extend as far as the output rotary shaft. Since the
armature rotary shaft of the d.c. motor and the rod of the electromagnetic
switch are disposed on the same axis, this starter is known as the coaxial
type starter.
The above-described coaxial type starter has a simplified overall
configuration, that is, a relatively long and narrow tubular shape, but it
suffers from the problem that, since the electromagnetic switch is
disposed at the rear end of the d.c. motor, the overall length of the
starter is increased by a large margin.
SUMMARY OF THE INVENTION
In view of the above-described problems of the prior art, it is a primary
object of the present invention to provide a starter for an engine which
has an overrunning clutch incorporated inside an armature rotary shaft of
a d.c. motor in order to reduce the overall length and which is also
provided with an epicyclic reduction gear.
To this end, the present invention provides a starter for an engine which
comprises a d.c. motor having a hollow armature rotary shaft incorporating
an overrunning clutch, an epicyclic reduction gear having a carrier for
supporting a plurality of planet gears which revolve while being in
engagement with a sun gear formed on a tubular clutch inner member
received and supported inside the armature rotary shaft, and an output
rotary shaft extending through a tubular member which is formed integral
with the carrier, the tubular member being in spline-engagement with the
output rotary shaft.
According to the present invention, when the electromagnetic switch of the
engine starter is energized, the output rotary shaft is pushed out by the
rod of the switch while compressing a return coil spring and, at the same
time, the power supply of the motor is turned on. As a result, the
rotational force derived from the armature rotary shaft of the motor is
transmitted to the clutch inner member through the overrunning clutch. The
rotation of the clutch inner member is transmitted to the carrier and the
tubular member after the speed thereof has been reduced through the
epicyclic reduction gear, and the rotation of the tubular member is
transmitted to the output rotary shaft to start the engine. After the
engine has been started, the electromagnetic switch is de-energized, and
the reverse rotation transmitted from the engine is cut off by the
overrunning clutch, thus preventing the armature rotary shaft of the motor
from being caused to rotate at high speed by the reverse transmission of
the rotational force.
BRIEF DESCRIPTION OF THE DRAWINGS
The above and other objects, features and advantages of the present
invention will become more apparent from the following description of the
preferred embodiment thereof, taken in conjunction with the accompanying
drawings, in which like reference numerals denote like elements, and in
which:
FIG. 1 is a sectional view of one embodiment of the starter for an engine
according to the present invention;
FIG. 2 is a sectional view taken along the line II--II of FIG. 1; and
FIG. 3 is a sectional view of a conventional starter for an engine.
DESCRIPTION OF THE PREFERRED EMBODIMENT:
The starter for an engine according to the present invention will be
described hereinunder in detail by way of one preferred embodiment and
with reference to the accompanying drawings.
FIGS. 1 and 2 show in combination a starter 10 for an engine according to
one embodiment of the present invention.
The engine starter 10 of this embodiment includes a d.c. motor 15
consisting mainly of permanent magnets 12 which are rigidly disposed at
spacings in the circumferential direction on the inner peripheral surface
of a yoke 11 which forms a magnetic circuit and which also defines an
outer wall of the starter 10, an armature 13 rotatably disposed in the
center of the yoke 11, and a face type commutator 14 provided at one axial
end of the armature 13.
The armature 13 of this d.c. motor 15 is composed of a hollow armature
rotary shaft 16 and an armature core 17 mounted on the outer periphery of
the armature rotary shaft 16. An enlarged-diameter portion, that is, a
recess, is formed in the inner peripheral portion of the hollow armature
rotary shaft 16. A plurality of circumferentially spaced cam surfaces 16a
(see FIG. 2) are formed in the peripheral surface of the recess. The face
type commutator 14 is fitted on the outer periphery of one end portion,
that is, the left-end portion as viewed in FIG. 1, of the armature rotary
shaft 16. The commutator 14 consists of a multiplicity of segments which
are disposed on a surface thereof which is at right angles to the axis of
the armature rotary shaft 16 so that the segments are in sliding contact
with a plurality of brushes 18 to effect commutation. Each segment is
connected with one end of an armature coil 19 which is wound on the
armature core 17.
The brushes 18 are supported by a brush holder 20 made of a plastic
material which is disposed on the outside of a rear bracket portion 11a.
The rear bracket portion 11a is formed integral with the yoke 11 to
constitute a grounded circuit. Each brush 18 is pressed against the slide
surface of the commutator 14 by a spring 21 through an opening formed in
the rear bracket portion 11a. A bearing 22 is fitted to the inner
peripheral surface of the central opening in the rear bracket portion 11a
to support the rear end portion of the armature rotary shaft 16, that is,
that end portion thereof which is closer to the commutator 14. The brush
holder 20 is composed of a fixed contact 23 which is connected to a
terminal (not shown), the fixed contact 23 being formed integral with the
rear end portion of the brush holder 20 by insert molding process, and a
terminal 25 rigidly secured to the fixed contact 23 by a screw 26, the
terminal 25 having a plus-side lead wire 24 for the brushes 18 welded
thereto.
The cam surfaces 16a that are formed on the circumferential surface of the
recess inside the armature rotary shaft 16 constitute one element of an
overrunning clutch mechanism. More specifically, a tubular clutch inner
member 27 is received in the hollow portion of the armature rotary shaft
16 in such a manner that the clutch inner member 27 extends over the cam
surfaces 16a, and the clutch inner member 27 is rotatably supported
through a bearing 28 which is disposed at the forward end (the right-hand
end as viewed in FIG. 1) of the armature rotary shaft 16. The clutch inner
member 27 has an extended portion which projects forwardly from the distal
end of the armature rotary shaft 16. The extended portion is rotatably
supported by a bearing 30 fitted to a boss-shaped portion of a center
bracket 29 which is secured to the forward end of the yoke 11. Thus, a
plurality of wedge-shaped spaces 16b are defined between the outer
peripheral surface of the clutch inner member 27 and the cam surfaces 16a
formed on the inner peripheral surface of the recess inside the armature
rotary shaft 16, as clearly shown in FIG. 2. In each wedge-shaped space
16b are disposed a roller 31 for providing engagement between the cam
surface 16a and the outer peripheral surface of the clutch inner member 27
and a spring 32 which presses the roller 31 in the direction in which said
engagement is made. Thus, the overrunning clutch mechanism is constituted
by the cam surfaces 16a, the clutch inner member 27, the rollers 31 and
the springs 32, and the armature rotary shaft 16 itself also serves as a
clutch outer member which carries out one function of the mechanism.
A pinion shaft 33 which defines an output rotary shaft is disposed in a
passage formed inside the armature rotary shaft 16 and the tubular clutch
inner member 27. The pinion shaft 33 is rotatably as well as axially
slidably supported at one end thereof through a bearing 34 which is fitted
to the inner peripheral portion of the clutch inner member 27. The other
end of the pinion shaft 33 passes through a tubular member 37 rotatably
supported through a bearing 36 which is fitted to a boss-shaped portion of
a front bracket 35, and this end of the pinion shaft 33 projects outward
from the front bracket 35. The projecting end of the pinion shaft 33 is
provided with a pinion 33a which is engageable with a ring gear (not
shown) of an engine. The pinion shaft 33 is in meshing engagement with the
tubular member 37 through a helical spline 33b which is formed in the
outer peripheral surface of the pinion shaft 33.
The extended portion of the clutch inner member 27 which is rotatably
supported by the center bracket 29 through the bearing 30 terminates
immediately in front of the tubular member 37. The terminating end portion
is carried by a bearing 38 fitted on the pinion shaft 33, and a sun gear
39a which constitutes an epicyclic reduction gear 39 is generated on the
peripheral surface of this end portion of the clutch inner member 27. An
internal gear 39b which is formed by utilizing the center bracket 29 is
disposed around the sun gear 39a, and a plurality of planet gears 39c are
disposed in an annular space defined between the sun gear 39a and the
internal gear 39b, the planet gears 39c being meshed with both the gears
39a and 39b. The planet gears 39c are mounted through respective pins 39e
on a carrier 39d which is supported through the aforementioned bearing 38.
The carrier 39d is formed integral with the tubular member 37. Therefore,
when the carrier 39d is caused to rotate by the revolution of the planet
gears 39c, the tubular member 37 rotates together with the carrier 39d in
one unit.
A recess 40 is formed in the rear end face of the pinion shaft 33. A first
holder 41 in the shape of a tube, one end of which is open, is loosely
fitted in the recess 40. A steel ball 42 which is thrust-bearing is
disposed between the closed end of the first holder 41 and the innermost
wall of the recess 40.
The engine starter 10 according to this embodiment further includes an
electromagnetic switch 43 (hereinafter referred to simply as "switch")
which causes the pinion shaft 33 to slide and which also has a switching
function whereby, when a key switch (not shown) of the vehicle is turned
on, the switch 43 causes contacts to be closed so as to enable the d.c.
motor 15 to be supplied with electric power from a battery. The switch 43
is connected to the outer end of the rear bracket portion 11a by means of
a bolt 44. The switch 43 consists of an exciting coil 46 which is wound on
a plastic bobbin supported by forward and rearward cores 45a 45b which
form a magnetic path together with a casing 43a, a plunger 47 slidably
disposed in the central opening formed in the bobbin, and a moving
assembly 48 secured to the plunger 47. The plunger 47 is subjected to
force from a coil spring 49 disposed between the same and the forward core
45a so that the plunger 47 returns to its original position shown in FIG.
1 when the key switch is turned off.
The moving assembly 48 has a rod 48a having one end thereof secured to the
plunger 47 and the other end disposed so as to face the first holder 41
provided on the rear end of the pinion shaft 33. A third holder 48c is
rigidly secured to the outer periphery of that end portion of the rod 48a
which is closer to the plunger 47, the holder 48c having an opening 48b
which opens toward the pinion shaft 33. A movable contact member is
slidably fitted on the outer peripheral portion of the third holder 48c,
the contact member having a movable contact 48e sandwiched between two
insulators 48d. A second holder 50 is fitted on the other end portion of
the rod 48a in such a manner that the holder 50 is axially slidable on the
outer peripheral surface of the rod 48a. Between the second holder 50 and
the inner end face of the opening 48b in the third holder 48c is disposed
a spring 51 which presses the pinion shaft 33 forward, that is, rightward
as viewed in FIG. 1. Between the second end face of the rod 48a and the
inner end face of the first holder 41 is also disposed a spring 52 which
presses the pinion shaft 33 forward. It should be noted that the reference
numeral 43b denotes a non-magnetic plate which closes the rear end of the
casing 43a. The plate 43b serves as a stopper for stopping the plunger 47
when it is returned rearward and also defines a rear wall of the
electromagnetic switch 43.
The operation of the above-described engine starter 10 according to the
embodiment will next be explained.
When the key switch (not shown) is off, the exciting coil 46 is in a
de-energized state and therefore not excited, and the plunger 47 is
subjected to the force from the spring 49 alone. Accordingly, the moving
assembly 48 is located at its rearward position, and the plunger 47 is in
contact with the plate 43b. In this state, the fixed contact 23 and the
movable contact 48e are separate from each other and the d.c. motor 15 is
therefore at rest. The pinion shaft 33 is also positioned at its rearward
position by the action of the spring which is provided between the bearing
34 and the retaining ring disposed at the rear end of the shaft 33.
When the key switch is turned on, the exciting coil 46 is energized and the
plunger 47 is thereby urged to move. In consequence, the moving assembly
48 moves forward, resulting in the movable contact 48e coming into contact
with the fixed contact 23. Accordingly, the armature coils 19 are
energized through the brushes 18 and the commutator 14, and the d.c. motor
15 is thus started.
The rotation of the armature rotary shaft 16 caused by the d.c motor 15
thus being started is transmitted to the clutch inner member 27 through
the rollers 31, and the rotation of the clutch inner member 27 causes each
of the planet gears 39c of the epicyclic reduction gear 39 to revolve
about the sun gear 38a. In consequence, the carrier 39d rotates together
with the tubular member 37 in one unit at a reduced speed. The rotation of
the tubular member 37 causes the pinion shaft 33 to rotate through the
engagement provided by the helical spline 33b.
On the other hand, the pinion shaft 33 is pressed forward by the springs
51, 52 of the moving assembly 48, thus causing the pinion 33a to mesh with
the ring gear which is rigidly secured to the outer periphery of a
flywheel of the engine at the same time as the start of the d.c. motor 15.
After the starting of the engine, when the clutch inner member 27 is
reversely urged by the ring gear through the pinion shaft 33, the tubular
member 37 and the epicyclic reduction gear 39 so as to rotate at a higher
speed than that of the armature rotary shaft 16, the engagement between
the clutch inner member 27 and the armature rotary shaft 16 is canceled by
the function of the one-way overrunning clutch, thus allowing the armature
rotary shaft 16 to rotate under no load. Upon the completion of the
starting of the engine, the key switch is turned off to cut off the power
supply, so that the moving assembly 48, together with the plunger 47, is
returned rearward by the action of the spring 49 provided inside the
electromagnetic switch 43 and the pinion shaft 33 is also returned
rearward by the action of the spring which is provided around its rear
end.
As has been described above, it is possible according to the present
invention to reduce by a large margin the overall length of a coaxial type
engine starter equipped with an epicyclic reduction gear by incorporating
the overrunning clutch inside the armature rotary shaft of the d.c. motor.
Although the present invention has been described through specific terms,
it should be noted here that the described embodiment is not necessarily
exclusive and that various changes and modifications may be imparted
thereto without departing from the scope of the invention which is limited
solely by the appended claim.
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Description |
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