Title of Invention

" A DUAL-POWERED HYBRID MOTORCYCLE WITH AN AUTOMATIC CENTRIFUGAL CLUTCH"

Abstract An automatic centrifugal clutch 16 is interposed in a power transmission system between an engine 12 and a driving wheel. A motor 13, which has a function to generate electricity and also is supplied with electricity from a battery 23 to generate auxiliary power, is connected to a crankshaft 36 of the engine 12. An acceleration data acquisition means is provided for acquiring the accelerator operation amount and the accelerator operation speed. A delay time setting means is provided for setting the delay time according to the acceleration data. A motor control means is provided for supplying the motor 13 with a magnitude of electricity in accordance with the acceleration operation amount after the delay time has elapsed from the moment when an accelerator grip was operated.
Full Text 07-07-18; 02:57PM; L. S. DAVAR&CO ; # 4/ 56
HYBRID MOTORCYCLE
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a hybrid motorcycle run
by power from an engine and auxiliary power from a motor.
2. Description of the Related Art
A conventional hybrid vehicle run by power from an engine
and auxiliary power from a motor is disclosed in, for example,
10 JP-A-2000-287306. The motor of the vehicle disclosed in
JP-A-2000-287306 is connected to a crankshaft of the engine,
and the operation of the motor is controlled by a control device.
The auxiliary power from the motor and the power from the engine
are added at the crankshaft, and transmitted to a driving wheel
as a resultant force. A power transmission system between the
engine and the driving wheel includes a manually operable
clutch.
The vehicle disclosed in JP-A-2000-287306 is run primarily
by the power from the engine, to which the power from the motor
is added, when the vehicle starts running, in order to increase
the driving force. The control device for controlling the
operation of the motor rotates the motor to generate a
predetermined torque when predetermined starting conditions
are satisfied. One of the starting conditions for this vehicle
25 is that the clutch mentioned above is engaged.
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This vehicle uses a clutch switch to detect whether or not
the clutch is engaged. In general, in vehicles such as
automobiles, a clutch is disengaged when the operator presses
a clutch pedal, and the clutch switch detects displacement of
the clutch pedal, or a detection element integrated with the
clutch pedal.
The present inventors thought of providing a scooter-type
hybrid motorcycle utilizing the conventional technique for
hybrid vehicles described above.
However, the scooter-type motorcycle is provided with an
automatic centrifugal clutch, rather than a manually operable
clutch, in the power transmission system between the engine and
the rear wheel, and thus it has not been easy to realize a
scooter-type hybrid motorcycle.
Different from the engine, the motor generates a large
torque at relatively low speed. Thus, if the clutch is not
completely engaged when applying auxiliary power from the motor
when the motorcycle starts running, transmission of this large
torque causes friction members in the clutch to slip, which
makes it impossible for the motorcycle to start running. That
is, if it is not possible to accurately detect the timing at
which the automatic centrifugal clutch is completely engaged,
that would be a problem in realizing a scooter-type hybrid
motorcycle.
The clutch switch used in JP-A-2000-287306 mentioned above
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merely detects displacement of a manually operable member, and
thus cannot detect the timing when the automatic centrifugal
clutch is completely engaged. Even if the clutch switch could
detect the engagement completion timing of the automatic
centrifugal clutch, providing such a clutch switch would
increase the cost, and if the clutch switch broke down,
auxiliary power could not even be generated.
SUMMARY OF THE INVENTION
The present invention has been made to solve the foregoing
problems, and therefore has an object to provide a hybrid
motorcycle with excellent start and acceleration performance,
in spite of including an automatic centrifugal clutch.
In order to solve the above problems, a first aspect of
the present invention provides a hybrid motorcycle having an
automatic centrifugal clutch interposed in a power transmission
system between an engine and a driving wheel, and a motor for
auxiliary power connected to a crankshaft of the engine, the
motor having a power generation function and also being supplied
with electricity from a battery to rotate, the hybrid motorcycle
including: an acceleration data acquisition means for acquiring
as acceleration data at least an accelerator operation amount
of an accelerator operating element, of accelerator operation
amount and accelerator operation speed thereof; a delay time
setting means for setting a delay time by which start of
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operation of the motor is delayed, according to the acceleration
data acquired by the acceleration data acquisition means; and
a motor control means for supplying the motor with a magnitude
of electricity in accordance with the acceleration data after
the delay time has elapsed from a moment when the accelerator
operating element in an idling state was operated.
The invention of a second aspect provides the hybrid
motorcycle according to the first aspect, further including:
an electricity supply restriction means for continuing supply
of electricity to the motor for a predetermined electricity
supply time and discontinuing the supply of electricity to the
motor after the electricity supply time has elapsed.
The invention of a third aspect provides the hybrid
motorcycle further including: a charge level detection means
for detecting a charge level of the battery, in which the
electricity supply restriction means shortens the electricity
supply time as the charge level detected by the charge level
detection means becomes lower.
The invention of a fourth aspect provides the hybrid
motorcycle further including: a charging means for causing the
motor to generate electricity after the electricity supply time
has elapsed and charging the battery with the generated
electricity.
The invention of a fifth aspect provides the hybrid
motorcycle, in which the acceleration data acquisition means
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acquires the accelerator operation amount and the accelerator
operation speed as the acceleration data, and the delay time
setting means uses a longer one of a first delay time and a second
delay time, the first delay time being obtained based on the
accelerator operation amount acquired by the acceleration data
acquisition means, and the second delay time being obtained
based on the accelerator operation speed acquired by the
acceleration data acquisition means.
The invention of a sixth aspect provides the hybrid
motorcycle, in which the motor control means includes a
prerotation means for rotating the motor in conjunction with
rotation of the engine after an engine start and in an operating
state in which power from the motor is not applied to the
crankshaft.
The invention of a seventh aspect provides the hybrid
motorcycle, in which a rotation start timing, at which the
prerotation means rotates the motor in conjunction with
rotation of the engine, is set to a timing after an engine start
and when an engine speed is lower than an idling speed.
The invention of an eighth aspect provides the hybrid
motorcycle further including: a charge level determination
means for determining whether or not the charge level of the
battery is lower than a predetermined minimum charge level; and
a precharging means for causing the motor to generate
electricity and charging the battery with the generated
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electricity after an engine start and in an operating state in
which power from the motor is not applied to the crankshaft,
if the charge level determination means determines that the
charge level of the battery is lower than the minimum charge
level.
According to the present invention, a delay time in
accordance with the acceleration data (operation amount of the
accelerator operating element, accelerator operation speed) is
set by the delay time setting means when the accelerator
operating element is operated from an idling state to the
acceleration side. The motor is supplied with electricity to
generate power when the delay time has elapsed from the moment
when the accelerator operating element was operated.
Meanwhile, the length of time from the start of an
accelerator operation to the completion of engagement of the
automatic centrifugal clutch (hereinafter simply referred to
as '"clutch engagement time") changes according to the
accelerator operation amount (magnitude of the output torque
from the engine) . That is, as the accelerator operation amount
becomes larger, the output torque becomes larger and hence the
clutch engagement time becomes longer.
According to the present invention, a delay time in
accordance with the clutch engagement time is set, and the motor
is caused to operate after a throttle operation is started and
after the delay time has elapsed. Thus, the auxiliary power
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from the motor can be applied to the automatic centrifugal
clutch with the clutch completely engaged.
Therefore, the present invention can provide a hybrid
motorcycle with excellent start and acceleration performance,
in which the power from the engine and the auxiliary power from
the motor can be efficiently transmitted via the automatic
centrifugal clutch to the driving wheel.
An existing sensor for use to control the rotation of the
engine can be used to detect the operation amount and the
operation speed of the accelerator operating element. Thus,
it is not necessary to provide a new member for detection
purposes, such as sensor or switch, in order to implement the
present invention. In this way, the present invention can be
implemented while reducing the cost.
The hybrid motorcycle 1 according to the present invention
does not include a sensor or a switch exclusively for detecting
the completion of engagement of the automatic centrifugal
clutch. Thus, according to the hybrid motorcycle, the
operation to apply auxiliary power can be performed with high
reliability compared to the case where a dedicated sensor or
switch is used to detect the completion of engagement of the
clutch.
According to the second aspect of the invention, the supply
of electricity to the motor is discontinued after the vehicle
starts running or accelerates. Thus, the consumption of
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electricity in the battery can be reduced compared to the case
where the supply of electricity to the motor is continued after
the vehicle starts running or accelerates.
According to the third aspect of the invention, the charge
level of the battery is not lowered excessively. Thus, it is
possible to secure electricity for use to cause the motor to
generate auxiliary power next time.
According to the fourth aspect of the invention, the battery
can be charged after electricity in the battery has been
consumed. Thus, it is possible to secure sufficient
electricity to be supplied to the motor 13 next time.
According to the fifth aspect of the invention, the delay
time can be set to be longer as the accelerator operation speed
is higher, even if the accelerator operation amount is constant.
Thus, the power from the motor can be applied to the automatic
centrifugal clutch at an appropriate timing in accordance with
the accelerator operation speed, even in the case of a
motorcycle which is often caused to start running or accelerate
with the accelerator fully open, such as motorcycle
incorporating a small-displacement engine.
Therefore, according to the present invention, the power
from the engine and the auxiliary power from the motor can be
more reliably transmitted to the rear wheel.
According to the sixth aspect of the invention, it is
possible to prevent the motor, which is not driving to generate
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auxiliary power, from serving as a load on the engine, which
can stabilize the rotation of the engine in an idling state.
According to the seventh aspect of the invention, the motor
is rotated after an engine start and before the engine speed
reaches an idling speed, which reduces a load on the engine.
Thus, the engine shifts to an idling state while rotating stably
after an engine start, even if the motor is connected to the
crankshaft. Therefore, the present invention can provide a
hybrid motorcycle in which the series of operations, including
starting the engine and the vehicle starting running and
accelerating, can be performed smoothly.
According to the eighth aspect of the invention, if the
charge level of the battery is low, the battery can be charged
when auxiliary power from the motor is not necessary, for
example when the vehicle is at a halt. Thus, according to the
present invention, the battery can be prevented from being
over-discharged, and it is possible to secure electricity for
use to cause the motor to generate auxiliary power next time.
20 BRIEF DESCRIPTION OF DRAWINGS
FIG- 1 is a side view of a hybrid motorcycle according to
the present invention;
FIG. 2 is a horizontal cross sectional view of a power unit;
FIG. 3 is a block diagram showing the configuration of a
control system of the hybrid motorcycle according to the present
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invention;
FIG. 4 is a block diagram showing the configuration of a
motor/generator control section;
FIG. 5 shows graphs for explaining how to set the delay
time;
FIG. 6 is a graph showing the relation between the APS angle
and the driving current for a motor;
FIG. 7 is a graph showing the relation between the charge
level of a battery and the electricity supply time to the motor;
FIG. 8 is a graph as a map for obtaining the charge level
of the battery based on the open circuit voltage of the battery;
FIG. 9 is a graph as a map for obtaining the charge level
of the battery based on the battery current and the battery
voltage;
FIG. 10 is a graph as a map for setting the charge current
and the discharge current for a charge level of the battery;
FIG. 11 is a flowchart for explaining the operation of the
hybrid motorcycle according to the present invention;
FIG. 12 is a flowchart for explaining the operation of a
control device after an engine start until auxiliary power is
generated by the driving of the motor;
FIG. 13 is a time chart for explaining the operation of
the hybrid motorcycle according to the present invention; and
FIG. 14 is a time chart for explaining the operation of
the hybrid motorcycle according to the present invention.
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DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
A description will hereinafter be made of an embodiment
of the hybrid motorcycle according to the present invention with
reference to FIGs. 1 to 14.
FIG. 1 is a side view of the hybrid motorcycle according
to the present invention. FIG. 2 is a horizontal cross
sectional view of a power unit, FIG. 3 is a block diagram
showing the configuration of a control system of the hybrid
motorcycle according to the present invention. FIG. 4 is a
block diagram showing the configuration of a motor/generator
control section.
FIG. 5 shows graphs for explaining how to set the delay
time, in which FIG. 5(A) is a graph as a map for obtaining a
first delay time based on the APS angle, FIG. 5 (B) is a graph
as a map for obtaining a second delay time based on the APS change
rate, and FIG. 5(C) is a graph showing changes in actual delay
time based on the first delay time and the second delay time.
FIG. 6 is a graph showing the relation between the APS angle
and the driving current for a motor. FIG. 7 is a graph showing
the relation between the charge level of a battery and the
electricity supply time to the motor. FIG. 8 is a graph as a
map for obtaining the charge level of the battery based on the
open circuit voltage of the battery. FIG. 9 is a graph as a
map for obtaining the charge level of the battery based on the
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battery current and the battery voltage. FIG. 10 is a graph
as a map for setting the charge current and the discharge current
for a charge level of the battery.
FIG. 11 is a flowchart for explaining the operation of the
hybrid motorcycle according to the present invention. FIG. 12
is a flowchart for explaining the operation of a control device
after an engine start until the motor generates auxiliary power.
FIGs . 13 and 14 are each a time chart for explaining the operation
of the hybrid motorcycle according to the present invention.
FIG. 13 corresponds to the case where an accelerator is operated
such that the accelerator operation amount increases generally
in proportion to the time from start to end of the operation.
FIG. 14 corresponds to the case where the accelerator is once
reversed slightly at the middle of the starting operation and
then the starting operation is performed again.
In the drawings, reference numeral 1 denotes a hybrid
motorcycle according to this embodiment. Reference numeral 2
denotes a front wheel of the motorcycle 1, 3 a front fork, 4
steering handlebars, 5 a rear wheel as the driving wheel, 6 a
power unit for driving the rear wheel 5,7 a seat, and 8 a body
cover.
The front wheel 2 can be steered to the left and right by
rotationally moving the steering handlebars 4 . An accelerator
grip 9 for increasing and decreasing the driving force of the
25 power unit 6 and a front wheel brake lever (not shown) are
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provided at an end of the steering handlebars 4 on the right
side of the vehicle body. The accelerator grip 9 constitutes
the accelerator operating element of the present invention.
As shown in FIG, 2, the accelerator grip 9 is supported
for free rotational movement on the steering handlebars 4,
although not shown. The accelerator grip 9 is provided with
an accelerator operation amount detector 11 (hereinafter simply
referred to as "APS" (accelerator position sensor)) for
detecting the operation amount (rotational angle relative to
the handlebars) of the accelerator grip 9.
The rear wheel 5 is supported for free rotation at the rear
end of the power unit 6 to be discussed later, in order to be
rotated by the power from an engine 12 and the auxiliary power
from a motor 13 provided in the power unit 6.
The power unit 6 is a unit swing type, and supported for
free vertical swinging movement on a body frame by a link
mechanism (not shown) coupled to the front end. As shown in
FIG. 1, a cushion unit 14 is interposed between the rear end
of the power unit 6 and the body frame (not shown).
As shown in FIG. 2, the power unit 6 is made up of an engine
12 and a motor 13 provided at its end on the front side of the
vehicle (on the right side in FIG. 2), a belt-type continuously
variable transmission 15 (hereinafter simply referred to as
"CVT") extending longitudinally on the left side of the vehicle
body, an automatic centrifugal clutch 16 provided at the rear
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end of the CVT 15, a gear-type speed reducer 18 provided between
the automatic centrifugal clutch 16 and an axle 17 of the rear
wheel 5, a control device 19 (see FIG. 3) for controlling the
operation of the engine 12 and the motor 13, etc.
A main switch 21, a start switch 22, a battery 23, etc.,
are connected to the control device 19. The start switch 22
is intended to start the engine 12, and in this embodiment uses
the motor 13 to start the engine 12. At the time of starting,
the motor 13 substantially functions as a starter motor.
Alternatively, a dedicated starter motor may be used to start
the engine 12, as in the case with common conventional
motorcycles.
The engine 12 is a 4-cycle engine including a crankcase
31 shown in FIG. 2, and a cylinder (not shown) provided in front
of the crankcase 31 and extending upward. An intake system
having a throttle valve 32 (see FIG. 3) and an exhaust system
having a muffler 33 (see FIG. 1) are connected to the cylinder.
The throttle valve 32 is connected to the accelerator grip
9 via a wire (not shown), and opens and closes through operation
of the accelerator grip 9. The throttle valve 32 is provided
with a throttle valve opening sensor (not shown) for detecting
the opening of the throttle valve 32. The throttle valve
opening sensor is connected to an engine control section 34 of
the control device 19 shown in FIG. 3 and to be discussed later,
and sends to the engine control section 34 the opening of the
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throttle valve 32 as detected data.
The engine 12 is arranged in such that the fuel injector
35 (see FIG. 3) injects fuel into an intake passage. The fuel
injection amount from the fuel injector 35 is set by the engine
control section 34 according to the opening of the throttle
valve 32 and the speed of the engine 12. The speed of the engine
12 is calculated utilizing the number of ignition pulses
generated by an ignition system having an ignition plug (not
shown). The ignition timing of the engine 12 is set by the
engine control section 34 based on the rotational angle of the
crankshaft 36.
The rotational angle of the crankshaft 36 is detected by
an electromagnetic pickup 37 (see FIG. 2) attached to the
crankcase 31. The electromagnetic pickup 37 is positioned to
face a tooth 38a provided to a rotor 38 (see FIG. 2) of the motor
13 to be discussed later, and sends a detection signal to the
engine control section 34 when it has detected the tooth 38a
magnetically.
As shown in FIG. 2, the crankshaft 36 of the engine 12 is
supported on the crankcase 31 by bearings 39, 40 for free
rotation. The crankcase 31 is made up of a left half 41 and
a right half 42. The left half 41 is formed integrally with
a longitudinally extending portion 41a extending
longitudinally on the left side of the rear wheel 5, to which
a transmission case cover 43 is attached.
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The left half 41 of the crankcase 31 and the transmission
case cover 43 constitute a transmission case 44 housing and also
supporting the CVT 15, the automatic centrifugal clutch 16, the
gear-type speed reducer 18, etc.
A motor housing 45 for the motor 13 to be discussed later
is attached to the right half 42 of the crankcase 31.
As shown in FIG. 2, a driving pulley 46 of the CVT 15 is
mounted to an end of the crankshaft 36 on the left side of the
vehicle body. The driving pulley 4 6 is made up of a fixed sheave
10 half 46a fixed to the crankshaft 36, a movable sheave half 46b
supported on the crankshaft 36 so as to move freely axially
thereof but not to rotate relative thereto, and a drive
mechanism (not shown) for moving the movable sheave half 4 6b
axially on the crankshaft 36.
The CVT 15 is made up of the above driving pulley 4 6, a
driven pulley 47 positioned on the rear side of the vehicle body,
and a V-belt 48 wrapped around both the pulleys 46, 47, As
conventionally well known, the CVT 15 continuously varies the
rotation of the crankshaft 36 for transmission to a rotary shaft
4 9 of the driven pulley 47. The driven pulley 47 is made up
of a fixed sheave half 47a fixed to the rotary shaft 4 9, and
a movable sheave half 47b supported on the rotary shaft 49 so
as to be movable axially thereof and also be urged toward the
fixed sheave half 47a by a compression coil spring (not shown).
The rotary shaft 49 is formed in the shape of a cylinder,
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and supported for free rotation through a bearing (not shown)
on an intermediate shaft 50 passing through the hollow part of
the rotary shaft 49. The intermediate shaft 50 is supported
for free rotation on the transmission case 44 through bearings
51, 52. An input part 16a of the automatic centrifugal clutch
16 is connected to an end of the rotary shaft 49 on the left
side of the vehicle body.
The automatic centrifugal clutch 16 is made up of the above
input part 16a having a clutch shoe 16b, and a clutch outer 16c
housing the input part 16a. The clutch outer 16c is fixed to
an end of the intermediate shaft 50 on the left side of the
vehicle body.
An end of the intermediate shaft 50 on the right side of
the vehicle body is connected to the axle 17 of the rear wheel
5 via the gear-type speed reducer 18, which is a two-staged type.
The axle 17 of the rear wheel 5 is supported for free rotation
on the transmission case 4 4 through bearings 53, 54.
With the thus constructed power unit 6, rotation of the
crankshaft 36 is transmitted from the driving pulley 46 via the
V-belt 4 8 to the driven pulley 47 of the CVT 15, and then from
the rotary shaft 49 to the input part 16a of the automatic
centrifugal clutch 16. As the rotation of the crankshaft 36
increases, the rotation of the input part 16a increases. Then,
a centrifugal force increases the diameter of the clutch shoe
16b, which causes the clutch shoe 16b to engage with the clutch
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outer 16c. This in turn causes the clutch outer 16c to rotate.
This rotation is transmitted from the intermediate shaft 50 via
the gear-type speed reducer 18 to the axle 17 (rear wheel 5).
As shown in FIG. 2, a rotor 38 of the motor 13 to be discussed
later is mounted to an end of the crankshaft 36 on the right
side of the vehicle body.
The motor 13 is intended to apply auxiliary power to the
crankshaft 36, and has a function to generate electricity by
being driven by the engine 12, The motor 13 includes the above
rotor 38 and a stator 61 fixed to the motor housing 45, and as
shown in FIG. 3, is connected to a motor/generator control
section 62 of the control device 19.
The rotor 38 is made up of a boss 38b fixed to the crankshaft
36, a disk 38c extending radially from an end of the boss 38b
on the left side of the vehicle body, a cylinder 38d housing
the disk 38c, and a permanent magnet 63 secured to an end surface
of the disk 38c on the right side of the vehicle body. The tooth
38a to be detected by the electromagnetic pickup 37 is formed
on the outer periphery of the cylinder 38d. The motor 13
directly drives the crankshaft 36.
The stator 61 incorporates a coil 64, and is fixed to the
motor housing 45 in such a manner as to be partially inserted
into the cylinder 38d and face the permanent magnet 63. The
stator 61 is provided on a circumference centered on the axis
of the crankshaft 36.
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The stator 61 of the motor 13 also incorporates an encoder
65 (see FIG. 3) for detecting the speed of the rotor 38 (speed
of the crankshaft 36).
The motor/generator control section 62 is intended to
control the timing for supplying the motor 13 with electricity
and the magnitude of the electricity, and also switch the motor
13 to function as a generator. As shown in FIG. 4, the
motor/generator control section 62 includes an acceleration
data acquisition means 71, a delay time setting means 72, a motor
control means 73, a charge level detection means 74, a charging
means 75, a charge level determination means 76, a precharging
means 77, an engine speed detection means 78 and a timer 79.
The acceleration data acquisition means 71 acquires the
accelerator operation amount (operation angle of the
accelerator grip 9) detected by the APS 11 and the accelerator
operation speed (speed at the time when the accelerator grip
9 is operated) as acceleration data.
The delay time setting means 72 sets the delay time, which
is a period from the moment when the accelerator operation is
started to the moment when the driving by the motor 13 is started,
in a method discussed later. The delay time is set to a length
necessary for the automatic centrifugal clutch 16 to be
completely engaged from the moment when the accelerator
operation is started.
For example, in the case where the accelerator grip 9 is
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operated greatly and rapidly, the power from the engine 12 to
be applied to the automatic centrifugal clutch 16 is relatively
increased, which requires a relatively long time for the
automatic centrifugal clutch 16 to be completely engaged. Thus,
the delay time is set to be relatively long. If the delay time
is not set, auxiliary power is generated by the driving of the
motor 13 right at the start of the accelerator operation, and
too large a torque is applied before the automatic centrifugal
clutch 16 has been completely engaged. Thus, the clutch shoe
16b may slip to prevent the vehicle from starting running.
The delay time setting means 72 selects a longer one of
a provisional delay time set based on the accelerator operation
amount (hereinafter referred to as "first delay time") and a
provisional delay time set based on the accelerator operation
speed (hereinafter referred to as "second delay time") , and sets
the selected one as final delay time.
Now, a detailed description will be made of how to set the
delay time. The delay time setting means 72 according to this
embodiment sets the final delay time using the maps shown in
FIGs. 5 (A) to 5(C) . FIG. 5 (A) is a graph as a map for obtaining
a set value A, which is equivalent to the first delay time in
accordance with the accelerator operation amount. FIG. 5(B)
is a graph as a map for obtaining a set value B, which is
equivalent to the second delay time in accordance with the
accelerator operation speed. FIG. 5(C) is a graph as a map for
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obtaining the final delay time based on the set value A and the
set value B.
As shown in FIG. 5(A), the set value A is set such that
the delay time becomes longer as the accelerator operation
amount becomes larger until the accelerator operation amount
reaches a predetermined upper limit, and such that the delay
time maintains a constant maximum time, even if the accelerator
operation amount increases, after the accelerator operation
amount has reached the upper limit.
As shown in FIG. 5(B), the set value B is set such that
the delay time becomes longer as the accelerator operation speed
becomes higher until the accelerator operation speed reaches
a predetermined upper limit, and such that the delay time
maintains a constant maximum time, even if the accelerator
operation speed increases, after the accelerator operation
speed has reached the upper limit.
The delay time setting means 72 reads a set value A in
accordance with the accelerator operation amount acquired by
the acceleration data acquisition means 71, from the map shown
in FIG. 5 (A) The delay time setting means 72 also reads a set
value B in accordance with the accelerator operation speed
acquired by the acceleration data acquisition means 71, from
the map shown in FIG. 5(B). The delay time setting means 72
then compares the set value A and the set value B, applies the
larger one of the set values A, B to the map shown in FIG. 5 (C)
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as a set value C, and reads the final delay time in accordance
with the set value C from the drawing.
The motor control means 73 includes an electricity supply
restriction means 81 and a prerotation means 82 to be discussed
later, and supplies the motor 13 with a magnitude of electricity
in accordance with the accelerator operation amount after the
delay time has elapsed from the moment when the accelerator grip
9 in an idling state was operated.
Whether or not the accelerator grip 9 is in an idling state
is detected using the accelerator operation amount acquired by
the acceleration data acquisition means 71. That is, the
accelerator grip 9 is determined to be in an idling state if
the accelerator operation amount is 0.
Whether or not the accelerator grip 9 has been operated
is detected by determining whether or not the accelerator
operation amount has changed from 0. The timer 79 measures the
time from the start of an accelerator operation until the delay
time elapses.
In supplying the motor 13 with a magnitude of electricity
in accordance with the accelerator operation amount, the motor
control means 73 reads a magnitude of driving current in
accordance with the accelerator operation amount, from the map
shown in FIG. 6, and controls the voltage such that the magnitude
of driving current flows through the motor 13. The motor
control means 73 supplies the motor 13 with electricity only
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when the charge level of the battery 23 is above a minimum charge
level to be discussed later.
The electricity supply restriction means 81 restricts the
length of time for the motor control means 73 to supply the motor
13 with electricity, to a predetermined electricity supply time.
The electricity supply time is set by an electricity supply time
setting means 83 to be discussed later. That is, the
electricity supply restriction means 81 continues the supply
of electricity to the motor 13 for the electricity supply time,
and discontinues the supply of electricity to the motor 13 after
the electricity supply time has elapsed.
The electricity supply time setting means 83 changes the
electricity supply time according to the charge level of the
battery 23 detected by the charge level detection means 74 to
be discussed later. In changing the electricity supply time,
the electricity supply time setting means 83 uses the map shown
in FIG. 7. FIG. 7 is a graph showing the driving time for a
charge level of the battery 23 (battery SOC). As shown in the
graph, the electricity supply time is set to be shorter as the
Charge level of the battery 23 becomes lower. The electricity
supply time setting means 83 reads an electricity supply time
in accordance with the present charge level of the battery 23,
from the map shown in FIG. 7, and sends the electricity supply
time to the electricity supply restriction means 81. That is,
the electricity supply restriction means 81 shortens the
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electricity supply time as the charge level detected by the
electricity supply time setting means 83 becomes lower.
The prerotation means 82 is intended to prevent the motor
13 not generating auxiliary power from serving as a load on the
engine 12, and arranged to start energization in order to rotate
the motor 13 when the speed of the engine 12 has reached a
predetermined prerotation speed. In this embodiment, the
prerotation speed is set to be lower than the speed of the engine
12 in an idling state (idling speed).
That is, in the hybrid motorcycle 1 according to this
embodiment, the prerotation means 82 rotates the motor 13 in
conjunction with the rotation of the engine 12 after an engine
start and when the engine speed has reached the prerotation
speed lower than the idling speed. The speed of the engine 12
is detected by the engine speed detection means 78. The engine
speed detection means 78 is arranged to obtain the speed of the
crankshaft 36 using the encoder 65.
The charge level detection means 74 obtains a charge level
(SOC) of the battery 23 in accordance with the release voltage
of the battery 23 using a map as the graph shown in FIG. 8, and
then adds, to this charge level, the current amount while the
battery 23 is charging and the current amount while the battery
23 is discharging to obtain the present charge level. The
battery release voltage is detected by the charge level
detection means 74 while electricity in the battery 23 is not
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consumed or while the battery 23 is not charged, for example
when the engine is stopped. The battery 23 is charged by the
charging means 75 to be discussed later. The current while
charging and the current while the battery 23 is discharging
are measured by a current detector 84 (see FIG. 3) provided in
the circuit connecting the battery 23 and the motor/generator
control section 62.
Instead of measuring and adding the charge current and the
discharge current each time as discussed above, a map as shown
in FIG- 9 may be used to detect the charge level of the battery
23 during engine operation. In the map shown in FIG. 9, the
charge level (SOC) of the battery 23 is defined by the battery
current and the battery voltage. The map shows the relation
between the voltage between the terminals of the battery 23 and
the current flowing through the battery 23 at each charge level
from 0% to 100%. In the case of using this map to obtain the
charge level of the battery 23, the charge level detection means
74 detects the present values of the current flowing through
the battery 23 and the voltage between the terminals of the
battery 23, and reads a charge level (SOC) in accordance with
these current and voltage values from the map.
The charging means 75 causes the motor 13 to function as
a generator and to generate electricity after the above
electricity supply time has elapsed, and charges the battery
23 with the generated electricity. The charging means 75 also
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changes the amount of electricity to be generated according to
the charge level detected by the charge level detection means
74. That is, the charging means 75 reduces the charge current
when the charge level of the battery 23 is relatively high, and
increases the charge current when the charge level of the
battery 23 is relatively low.
The charge level determination means 76 compares the charge
level of the battery 23 detected by the charge level detection
means 74 and the predetermined minimum charge level if auxiliary
power is not generated by the driving of the motor 13. The
charge level determination means 76 also sends a control signal
to the prerotation means 82 to discontinue the supply of
electricity to the motor 13, and sends a control signal to the
precharging means 77 to be discussed later to start charging,
when the charge level of the battery 23 is lower than the minimum
charge level. On receiving the control signal, the prerotation
means 82 stops the supply of electricity to the motor 13.
When the control signal is sent from the charge level
determination means 76, the precharging means 77 causes the
motor 13 to function as a generator and to generate electricity
if auxiliary power is not generated by the driving of the motor
13. The charge current while generating electricity is read
from the map shown in FIG. 10 and set. The map shows the charge
current and the discharge current of the battery 23 for a charge
level (SOC) of the battery 23.
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As can be understood from this map, the precharging means
77 according to this embodiment increases the charge current
as the charge level of the battery 23 becomes lower when the
charge level is between the minimum charge level Cl and a limit
value C2 lower than that. Also, the precharging means 77
performs charging at a constant maximum charge current when the
charge level is lower than the limit value C2. When the motor
13 is caused to function as a generator while the engine 12 in
low-speed operation, the engine control section 34 of the hybrid
motorcycle 1 increases the fuel injection amount from the
injector 35 so as to stabilize the rotation of the engine 12.
At this time, for example when the accelerator grip 9 is
in an idling position, the fuel injection amount is controlled
such that the engine speed reaches the idling speed during
normal operation. When the accelerator operation amount is
increased from the idling state, the engine control section 34
increases the fuel injection amount according to the increase
in accelerator operation amount. Thus, since the fuel
injection amount is increased according to an increase in load
due to electricity generation by the motor 13, the engine 12
can be prevented from stalling because of such an increase in
load due to electricity generation.
Now, a description will be made of the operation of the
motor/generator control section 62 constructed as described
above using the flowcharts shown in FIGs. 11 and 12 and the time
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chart shown in FIG. 13.
The engine 12 is started by turning ON the main switch 21
and then turning ON the start switch 22 in steps P1 to P3 of
the flowchart shown in FIG. 11.
The timing of turning ON the main switch 21 is indicated
as time Tl in FIG. 13, and the timing of turning ON the start
switch 22 is indicated as time T2 in FIG. 13.
After an engine start, the acceleration data acquisition
means 71 acquires acceleration data (accelerator operation
amount and accelerator operation speed) in step P4, and the
charge level determination means 76 determines in step P5
whether or not the charge level of the battery 23 is lower than
the minimum charge amount.
If the charge level of the battery 23 is equal to minimum
charge level or lower, the precharging means 77 reads a charge
current for the motor 13 from the map shown in FIG. 10 in step
P6, and causes the motor 13 to function as a generator and.to
generate electricity so as to obtain the charge current in step
P7. Then, the process returns to step P4 to repeat the above
20 processes. The timing of starting electricity generation in
step P7 is indicated as time T3 in FIG. 13.
On the other hand, if it is determined in step P5 that the
charge level of the battery 23 is higher than the minimum charge
level, the process proceeds to step P8, where the driving
current for the motor 13 is set. Here, the operation performed
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in step P8 is described with reference to the flowchart shown
in FIG. 12.
First of all, the speed of the engine 12 is detected in
step SI of the flowchart shown in FIG. 12, and energization is
5 started to rotate the motor 13 when the engine speed has reached
the prerotation speed as shown in steps S2 to S3. The
prerotation speed is indicated as symbol R in FIG. 13. Also,
the timing at which the motor 13 rotates in conjunction with
the rotation of the engine 12 is indicated as time T4 in FIG.
10 13.
Subsequently, acceleration data are acquired again in step
S4, and it is determined in step S5 whether or not an accelerator
operation has been performed. If an accelerator operation has
not been performed, the process returns to step S1. If an
accelerator operation has been performed, the timer 79 starts
counting the time in step S6. The timing at which the
accelerator operation has been performed is indicated as time
T5 in FIG. 13.
Then, a set value A (first delay time) in accordance with
the accelerator operation amount at that time is read from the
map shown in FIG. 5(A) in step S7, and a set value B (second
delay time) in accordance with the accelerator operation speed
at that time is read from the map shown in FIG. 5(B) in step
S8. Then, the larger one of the set value A and the set value
B (the one that brings about a longer delay time) is set as a
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set value C and used to read the final delay time from the map
shown in FIG. 5(C) in step S9.
After the delay time is set in this way, it is determined
in step S10 whether or not the delay time has elapsed from the
moment when a first throttle operation was performed {time T5) .
If the delay time has not elapsed, the process returns to step
S4. If the delay time has elapsed, the driving current for the
motor 13 is read from the map shown in FIG. 6 in step S11, and
the electricity supply time is read from the map shown in FIG.
7 in step S12. The electricity supply time becomes shorter as
the charge level of the battery 23 becomes lower. When the delay
time has elapsed, the timer 79 is stopped and reset.
After preparations have been made to cause the motor 13
to generate auxiliary power, the driving current is passed to
15 the motor 13 to generate auxiliary power by the driving of the
motor 13 in step P9 of the flowchart shown in FIG. 11. The timing
of generating auxiliary power is indicated as time T6 in FIG.
13. At this time, the timer 79 starts counting the time.
At this time, the delay time has elapsed from the start
of the accelerator operation {T5), and the automatic
centrifugal clutch 16 has completely been engaged. Thus, the
resultant force of the power from the engine 12 and the auxiliary
power from the motor 13 is transmitted from the automatic
centrifugal clutch 16 via the gear-type speed reducer 18 and
the axle 17 to the rear wheel 5.
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As a result, the acceleration at which this vehicle starts
running is large compared to common motorcycles that run only
on the power from the engine 12. Meanwhile, when the charge
level of the battery 23 is lower than the minimum charge level,
5 the electricity generation amount is increased from an
electricity generation amount for idling L to an electricity
generation amount for running H after the delay time has elapsed,
as shown in FIG. 13.
After auxiliary power is generated by the driving of the
motor 13 as discussed above, it is determined in step P1Q whether
or not the electricity supply time has elapsed from the start
of the driving of the motor 13. If the electricity supply time
has not elapsed, the process returns to step P9. If the
electricity supply time has elapsed, the supply of electricity
to the' motor 13 is discontinued in step P11. The timing of
stopping the supply of electricity is indicated as time T7 in
FIG. 13.
After the supply of electricity to the motor 13 is
discontinued, the motor 13 is caused to function as a generator
and to generate electricity in steps P6, P7. The timing of
starting the generation of electricity is indicated as time T8
in FIG. 13. The amount of electricity generated at this time
is also increased and decreased according to the charge level
of the battery 23.
Aside from when the vehicle starts running as discussed
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above, the motor 13 is also caused to generate auxiliary power
for example when the accelerator grip 9 is returned to an idling
position while the vehicle is running and then operated to
increase the running speed from a coasting state. Thus, also
5 at this time, the automatic centrifugal clutch 16 does not slip
and high acceleration performance can be achieved by the
auxiliary power by the driving of the motor 13.
In the operation example shown in FIG. 13, the operation
amount of the accelerator grip 9 is continuously increased from
the start of the operation until the vehicle starts running.
In the case where the accelerator is operated irregularly, an
operation similar to the above example where only the delay time
is different is performed. For example, in the case where the
accelerator grip 9 is once reversed slightly at the middle of
the starting operation and then the starting operation is
performed again, the operation as shown in FIG. 14 is performed.
In FIG. 14, the timing of starting the reversing operation
of the accelerator grip 9 at the middle of the starting operation
is indicated as time T10, and the timing at which the accelerator
grip 9 is completely reversed and the starting operation is
started again is indicated as time T11.
As shown in FIG. 14, the set value C, which represents the
delay time, is reduced by reversing the accelerator grip 9, and
increased by operating the accelerator grip 9 again. Also in
this case, the motor 13 is caused to generate auxiliary power
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when the delay time has elapsed (T6) from the start of the
accelerator operation (T5).
In the hybrid motorcycle 1 constructed as described above/
the auxiliary power from the motor 13 is applied to the automatic
centrifugal clutch 16 with the automatic centrifugal clutch 16
completely engaged. Thus, the resultant force of the power from
the engine 12 and the auxiliary power from the motor 13 can be
efficiently transmitted from the automatic centrifugal clutch
16 to the rear wheel 5 side without any loss of power in the
automatic centrifugal clutch 16,
Therefore, according to this embodiment, a hybrid
motorcycle 1 with excellent start and acceleration performance
can be manufactured.
Also, in this embodiment, an existing APS 11 for use to
control the rotation of the engine 12 is used to detect the
operation amount and the operation speed of the accelerator grip
9. Thus, it is not necessary to provide a new member for
detection purposes, such as sensor or switch, in order to
manufacture the hybrid motorcycle 1, which contributes to cost
reduction.
In the hybrid motorcycle 1 according to this embodiment,
a sensor or a switch for detecting the completion of engagement
of the automatic centrifugal clutch 16 is not exclusively used.
Thus, according to the hybrid motorcycle 1, the operation to
apply auxiliary power can be performed with high reliability
33

07-07-18;02:57PM; L. S. DAVAR&CO ; #37/56
compared to the case where a dedicated sensor or switch is used
to detect the completion of engagement of the automatic
centrifugal clutch.
In the hybrid motorcycle 1 according to this embodiment,
the supply of electricity to the motor 13 is discontinued after
the vehicle starts running or accelerates and when a
predetermined electricity supply time has elapsed. Thus, the
consumption of electricity in the battery 23 can be reduced
compared to the case where the supply of electricity to the motor
13 is continued after the vehicle starts running or accelerates.
In the hybrid motorcycle 1 according to this embodiment,
the electricity supply time becomes shorter as the charge level
of the battery 23 becomes lower. Thus, the charge level of the
battery 23 is not lowered excessively. Therefore, according
to the hybrid motorcycle 1, it is possible to secure electricity
for use to cause the motor 13 to generate auxiliary power next
time.
In the hybrid motorcycle 1 according to this embodiment,
the motor 13 generates electricity after the electricity supply
time has elapsed, and the battery 23 is charged with the
generated electricity In. this way, according to the hybrid
motorcycle 1, the battery 23 can be charged after electricity
in the battery 23 has been consumed. Thus, it is possible to
secure sufficient electricity to be supplied to the motor 13
next time.
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The hybrid motorcycle 1 according to this embodiment is
arranged to use a longer one of the first delay time obtained
based on the accelerator operation amount and the second delay
time obtained based on the accelerator operation speed. Thus,
according to the hybrid motorcycle 1, the power from the motor
13 can be applied to the automatic centrifugal clutch 16 at an
appropriate timing in accordance with the accelerator operation
speed, even if the accelerator grip 9 is operated to fully open
the throttle valve 32 in order for the vehicle to start running
or accelerate. As a result, in the hybrid motorcycle 1, the
power from the engine 12 and the auxiliary power from the motor
13 can be more reliably transmitted to the rear wheel 5.
The hybrid motorcycle 1 according to this embodiment is
arranged to rotate the motor 13 in conjunction with the rotation
of the engine 12 after an engine start and in an operating state
where the power from the motor 13 is not applied to the crankshaft
36. Thus, according to the hybrid motorcycle 1, it is possible
to prevent the motor 13 not generating auxiliary power from
serving as a load on the engine 12, which stabilizes the rotation
of the engine 12 in an idling state.
In the hybrid motorcycle 1 according to this embodiment,
the motor 13 is rotated after the start of the engine 12 and
before the speed of the engine 12 reaches an idling speed, which
reduces a load on the engine 12. Thus, the engine 12 shifts
to an idling state while rotating stably after an engine start,
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even if the motor 13 is connected to the crankshaft 36. As a
result, according to the hybrid motorcycle 1, the series of
operations, including starting the engine 12 and the vehicle
starting running and accelerating, can be performed smoothly.
In the hybrid motorcycle 1 according to this embodiment,
if the charge level of the battery 23 is low, the battery 23
can be charged when auxiliary power from the motor 13 is not
necessary, for example when the vehicle is at a halt. Thus,
according to the hybrid motorcycle 1, the battery 23 can be
prevented from being over-discharged, and it is possible to
secure electricity for use to cause the motor 13 to generate
auxiliary power next time.
In the above embodiment, the rotor 38 of the motor 13 is
mounted on the crankshaft 36. However, the motor 13 may be
formed separately from the engine 12. In such a case, the rotary
shaft of the motor 13 and the crankshaft 36 may be connected
directly or via a transmission means that can maintain the ratio
between the speeds of both the shafts to a constant value.
In the above embodiment, both the accelerator operation
amount and the accelerator operation speed are used to set the
delay time. However, only the accelerator operation amount may
be used to set the delay time. Also, in the above embodiment,
the driving current supplied to the motor 13 in order to cause
the motor 13 to generate auxiliary power is increased and
decreased in proportion to the accelerator operation amount.
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However, the driving current may be increased and decreased in
consideration of the accelerator operation speed as well.
In the above embodiment, the present invention is applied
to a scooter. However, the present invention is not limited
thereto, and may be applied to other types of motorcycle.
37

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WHAT IS CLAIMED IS:
1. A hybrid motorcycle having an automatic centrifugal
clutch interposed in a power transmission system between an
engine and a driving wheel, and a motor for auxiliary power
connected to a crankshaft of the engine, the motor having a power
generation function and also being supplied with electricity
from a battery to rotate, the hybrid motorcycle comprising:
an acceleration data acquisition means for acquiring as
acceleration data at least an accelerator operation amount of
an accelerator operating element, of accelerator operation
amount and accelerator operation speed thereof;
a delay time setting means for setting a delay time by which
start of operation of the motor is delayed, according to the
acceleration data acquired by the acceleration data acquisition
means; and
a motor control means for supplying the motor with a
magnitude of electricity in accordance with the acceleration
data after the delay time has elapsed from a moment when the
accelerator operating element in an idling state was operated.
2. The hybrid motorcycle as claimed in Claim 1, further
comprising:
an electricity supply restriction means for continuing
supply of electricity to the motor for a predetermined
electricity supply time and discontinuing the supply of
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07-07-18;02:57PM; L. S. DAVAR&CO ; # 42/ 56
electricity to the motor after the electricity supply time has
elapsed.
3. The hybrid motorcycle as claimed in Claim 2, further
comprising:
a charge level detection means for detecting a charge level
of the battery,
wherein the electricity supply restriction means shortens
the electricity supply time as the charge level detected by the
charge level detection means becomes lower.
4. The hybrid motorcycle as claimed in Claim 2, further
comprising:
a charging means for causing the motor to generate
electricity after the electricity supply time has elapsed and
charging the battery with the generated electricity.
5. The hybrid motorcycle as claimed in Claim 1,
wherein the acceleration data acquisition means acquires
the accelerator operation amount and the accelerator operation
speed as the acceleration data, and
the delay time setting means uses a longer one of a first
delay time and a second delay time, the first delay time being
obtained based on the accelerator operation amount acquired by
the acceleration data acquisition means, and the second delay
39

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time being obtained based on the accelerator operation speed
acquired by the acceleration data acquisition means.
6. The hybrid motorcycle as claimed in Claim 1,
wherein the motor control means comprises a prerotation
means for rotating the motor in conjunction with rotation of
the engine after an engine start and in an operating state in
which power from the motor is not applied to the crankshaft.
7. The hybrid motorcycle as claimed in Claim 6,
wherein a rotation start timing, at which the prerotation
means rotates the motor in conjunction with rotation of the
engine, is set to a timing after an engine start and when an
engine speed is lower than an idling speed.
8. The hybrid motorcycle as claimed in Claim 6, further
comprising:
a charge level determination means for determining whether
or not the charge level of the battery is lower than a
predetermined minimum charge level; and
a precharging means for causing the motor to generate
electricity and charging the battery with the generated
electricity after an engine start and in an operating state in
which power from the motor is not applied to the crankshaft,
if the charge level determination means determines that the
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07-07-18; 02:57PM; L. S. DAVAR&CO ; # 44/ 56
charge level of the battery is lower than the minimum charge
level.

41

An automatic centrifugal clutch 16 is interposed in a power
transmission system between an engine 12 and a driving wheel.
A motor 13/ which has a function to generate electricity and
also is supplied with electricity from a battery 23 to generate
auxiliary power, is connected to a crankshaft 36 of the engine
12. An acceleration data acquisition means is provided for
acquiring the accelerator operation amount and the accelerator
operation speed. A delay time setting means is provided for
setting the delay time according to the acceleration data. A
motor control means is provided for supplying the motor 13 with
a magnitude of electricity in accordance with the acceleration
operation amount after the delay time has elapsed from the
moment when an accelerator grip was operated.

Documents:

01021-kol-2007-abstract.pdf

01021-kol-2007-claims.pdf

01021-kol-2007-correspondence others 1.1.pdf

01021-kol-2007-correspondence others 1.2.pdf

01021-kol-2007-correspondence others 1.3.pdf

01021-kol-2007-correspondence others.pdf

01021-kol-2007-description complete.pdf

01021-kol-2007-drawings.pdf

01021-kol-2007-form 1.pdf

01021-kol-2007-form 18.pdf

01021-kol-2007-form 2.pdf

01021-kol-2007-form 3.pdf

01021-kol-2007-form 5.pdf

01021-kol-2007-priority document.pdf

1021-KOL-2007-(18-10-2011)-ABSTRACT.pdf

1021-KOL-2007-(18-10-2011)-AMANDED CLAIMS.pdf

1021-KOL-2007-(18-10-2011)-CORRESPONDENCE.pdf

1021-KOL-2007-(18-10-2011)-DESCRIPTION (COMPLETE).pdf

1021-KOL-2007-(18-10-2011)-DRAWINGS.pdf

1021-KOL-2007-(18-10-2011)-FORM 1.pdf

1021-KOL-2007-(18-10-2011)-FORM 2.pdf

1021-KOL-2007-(18-10-2011)-OTHERS.pdf

1021-KOL-2007-ABSTRACT.pdf

1021-KOL-2007-AMANDED CLAIMS.pdf

1021-KOL-2007-CORRESPONDENCE 1.4.pdf

1021-KOL-2007-CORRESPONDENCE 1.6.pdf

1021-KOL-2007-CORRESPONDENCE-1.5.pdf

1021-KOL-2007-DESCRIPTION (COMPLETE).pdf

1021-KOL-2007-DRAWINGS.pdf

1021-KOL-2007-EXAMINATION REPORT.pdf

1021-KOL-2007-FORM 1.pdf

1021-KOL-2007-FORM 18.pdf

1021-KOL-2007-FORM 2.pdf

1021-KOL-2007-FORM 3.pdf

1021-KOL-2007-FORM 5.pdf

1021-KOL-2007-GRANTED-ABSTRACT.pdf

1021-KOL-2007-GRANTED-CLAIMS.pdf

1021-KOL-2007-GRANTED-DESCRIPTION (COMPLETE).pdf

1021-KOL-2007-GRANTED-DRAWINGS.pdf

1021-KOL-2007-GRANTED-FORM 1.pdf

1021-KOL-2007-GRANTED-FORM 2.pdf

1021-KOL-2007-GRANTED-LETTER PATENT.pdf

1021-KOL-2007-GRANTED-SPECIFICATION.pdf

1021-KOL-2007-OTHERS 1.1.pdf

1021-KOL-2007-OTHERS.pdf

1021-KOL-2007-PA.pdf

1021-KOL-2007-PETITION UNDER RULE 137.pdf

1021-KOL-2007-REPLY TO EXAMINATION REPORT 1.1.pdf

1021-KOL-2007-REPLY TO EXAMINATION REPORT.pdf


Patent Number 252413
Indian Patent Application Number 1021/KOL/2007
PG Journal Number 20/2012
Publication Date 18-May-2012
Grant Date 14-May-2012
Date of Filing 19-Jul-2007
Name of Patentee YAMAHA HATSUDOKI KABUSHIKI KAISHA
Applicant Address 2500, SHINGAI, IWATA-SHI, SHIZUOKA-KEN
Inventors:
# Inventor's Name Inventor's Address
1 HIDEKI SHIRAZAWA C/O. YAMAHA HATSUDOKI KABUSHIKI KAISHA, 2500, SHINGAI, IWATA-SHI, SHIZUOKA 4388501
2 HIROSHI TANAKA C/O. YAMAHA HATSUDOKI KABUSHIKI KAISHA, 2500, SHINGAI, IWATA-SHI, SHIZUOKA 4388501
3 HEDEAKI SUZUKI C/O. YAMAHA HATSUDOKI KABUSHIKI KAISHA, 2500, SHINGAI, IWATA-SHI, SHIZUOKA 4388501
PCT International Classification Number B60K6/00
PCT International Application Number N/A
PCT International Filing date
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 2006-201857 2006-07-25 Japan