U.S. patent application number 09/736319 was filed with the patent office on 2001-06-21 for engine stall prevention apparatus for hybrid vehicle.
This patent application is currently assigned to Honda Giken Kogyo Kabushiki Kaisha. Invention is credited to Izumiura, Atsushi, Kitajima, Shinichi, Matsubara, Atsushi, Sawamura, Kazutomo, Wakashiro, Teruo.
Application Number | 20010004203 09/736319 |
Document ID | / |
Family ID | 18475298 |
Filed Date | 2001-06-21 |
United States Patent
Application |
20010004203 |
Kind Code |
A1 |
Matsubara, Atsushi ; et
al. |
June 21, 2001 |
Engine stall prevention apparatus for hybrid vehicle
Abstract
This invention relates to an engine stall prevention apparatus
for a hybrid vehicle. This engine stall prevention apparatus
comprises a clutch operation detection device which detects an
operation of a clutch; a clutch state determination device which
determines the state of the clutch based on the relationship
between the vehicle speed and the engine speed; a throttle opening
degree determination device which determines the degree of throttle
opening of the engine; a first engine speed modification device
(S010) which modifies a charging/regeneration allowing lower limit
engine speed value above which deceleration regeneration by the
electric motor is allowed; and a half-engaged clutch determination
maintaining device (S008) which outputs a determination signal
indicating that the clutch is half-engaged for a predetermined
period of time when the throttle is completely closed and the
clutch is determined to be half-engaged. When a half-engaged clutch
determination is maintained, the first engine speed modification
device elevates the charging/regeneration allowing lower limit
engine speed value.
Inventors: |
Matsubara, Atsushi;
(Wako-shi, JP) ; Sawamura, Kazutomo; (Wako-shi,
JP) ; Kitajima, Shinichi; (Wako-shi, JP) ;
Izumiura, Atsushi; (Wako-shi, JP) ; Wakashiro,
Teruo; (Wako-shi, JP) |
Correspondence
Address: |
ARMSTRONG, WESTERMAN, HATTORI
McLELAND & NAUGHTON
Suite 1000
1725 K Street, N.W.
Washington
DC
20006
US
|
Assignee: |
Honda Giken Kogyo Kabushiki
Kaisha
Tokyo
JP
|
Family ID: |
18475298 |
Appl. No.: |
09/736319 |
Filed: |
December 15, 2000 |
Current U.S.
Class: |
322/16 ;
180/65.1; 180/65.27; 180/65.28; 290/40C; 903/903; 903/919; 903/945;
903/946; 903/947 |
Current CPC
Class: |
Y10S 903/919 20130101;
B60W 20/00 20130101; B60W 10/02 20130101; B60W 10/06 20130101; B60W
2510/0225 20130101; Y10S 903/945 20130101; B60L 50/15 20190201;
Y02T 10/7072 20130101; Y10S 903/947 20130101; B60W 10/08 20130101;
B60W 20/13 20160101; Y02T 10/72 20130101; Y02T 10/64 20130101; Y10S
903/946 20130101; Y02T 10/70 20130101; B60W 2510/0208 20130101;
Y10S 903/903 20130101; B60L 2240/525 20130101; B60L 2240/507
20130101; B60L 15/2054 20130101 |
Class at
Publication: |
322/16 ;
290/40.00C; 180/65.1 |
International
Class: |
B60K 001/00 |
Foreign Application Data
Date |
Code |
Application Number |
Dec 20, 1999 |
JP |
11-361919 |
Claims
1. An engine stall prevention apparatus for a hybrid vehicle which
comprises an engine which outputs driving force to drive a vehicle;
an electric motor which assists the driving force of the engine;
and a power storage unit which stores electric power generated by
the electric motor when the electric motor is functioning as a
power generator or when deceleration regeneration is performed by
the electric motor; the engine stall prevention apparatus
comprising: a clutch operation detection device which detects an
operation of a clutch by a driver; a clutch state determination
device which determines the state of the clutch based on the
relationship between vehicle speed and engine speed; a throttle
opening degree determination device which determines a degree of
throttle opening of the engine; a first engine speed modification
device which modifies a charging/regeneration allowing lower limit
engine speed value above which deceleration regeneration by the
electric motor is allowed; and a half-engaged clutch determination
maintaining device which outputs a determination signal indicating
that the clutch is half-engaged for a predetermined period of time,
when the clutch operation detection device detects that the clutch
is not disengaged, the throttle opening degree determination device
determines that the degree of throttle opening of the engine is no
more than a predetermined degree, and the clutch state
determination device determines that the clutch is half-engaged;
wherein the first engine speed modification device elevates the
charging/regeneration allowing lower limit engine speed value while
the half-engaged clutch determination maintaining device outputs a
determination signal indicating that the clutch is
half-engaged.
2. An engine stall prevention apparatus according to claim 1,
further comprising a second engine speed modification device which
modifies a fuel cut lower limit engine speed value above which a
fuel amount to be supplied to the engine is cut during deceleration
regeneration, wherein the second engine speed modification device
elevates the fuel cut lower limit engine speed value while the
half-engaged clutch determination maintaining device outputs a
determination signal indicating that the clutch is
half-engaged.
3. An engine stall prevention apparatus according to claim 1,
further comprising an engine start allowing device which allows the
electric motor to start the engine or to assist the output of the
engine, wherein the engine start allowing device drives the
electric motor to start the engine or to assist the output of the
engine, while the half-engaged clutch determination maintaining
device outputs a determination signal indicating that the clutch is
half-engaged, and engine speed becomes lower than a predetermined
engine speed value.
4. An engine stall prevention apparatus according to claim 2,
further comprising an engine start allowing device which allows the
electric motor to start the engine or to assist the output of the
engine, wherein the engine start allowing device drives the
electric motor to start the engine or to assist the output of the
engine, while the half-engaged clutch determination maintaining
device outputs a determination signal indicating that the clutch is
half-engaged, and engine speed becomes lower than a predetermined
engine speed value.
Description
BACKGROUND OF THE INVENTION
[0001] 1. Field of the Invention
[0002] The present invention relates to an engine stall prevention
apparatus for a hybrid vehicle. In particular, the present
invention relates to a technique which can prevent an engine stall
when the clutch is half-engaged.
[0003] 2. Description of Related Art
[0004] Parallel hybrid vehicles are a type of hybrid vehicles in
which electric motors are used for assisting the output of engines.
In these parallel hybrid vehicles, various controls are performed,
for example, as shown in Japanese Unexamined Patent Application,
First Publication No. Hei 7-123509, when the vehicle accelerates,
the motor assists the output of the engine, and when the vehicle
decelerates, the motor generates electric power by deceleration
regeneration to charge the battery. Therefore, it is possible to
constantly maintain electrical energy (the remaining battery
charge) in the battery and to respond to demands by the driver of
the vehicle.
[0005] As described above, in a parallel hybrid vehicle, when
deceleration regeneration is performed, the electric motor is
driven by the rotational force of the driving wheels to function as
a power generator.
[0006] However, in a parallel hybrid vehicle having a manual
transmission, because the output shaft of an engine is directly
connected to the output shaft of the motor, if the clutch is
disengaged to disengage the driving wheels and the output shaft of
the engine when the motor is performing deceleration regeneration,
the torque of the driving wheels is not transmitted to the motor,
and all of the torque generated by the regeneration in the motor is
applied to the engine as a large load. In general, when a vehicle
decelerates, since the degree of throttle opening is small and the
output of the engine is limited to a small value, if deceleration
regeneration is performed in such a state, there will be a problem
that the engine speed may suddenly drop causing the engine to stall
and the engine may be overloaded.
SUMMARY OF THE INVENTION
[0007] The object of the present invention is to provide an engine
stall prevention apparatus for a hybrid vehicle which can detect
the half-engaged state of a clutch and can securely prevent an
engine stall without overloading the engine.
[0008] To accomplish this object, the engine stall prevention
apparatus of the present invention comprises: a clutch operation
detection device which detects an operation of a clutch by a
driver; a clutch state determination device which determines the
state of the clutch based on the relationship between the vehicle
speed and the engine speed; a throttle opening degree determination
device which determines the degree of throttle opening of the
engine; a first engine speed modification device which modifies a
charging/regeneration allowing lower limit engine speed value above
which deceleration regeneration by the electric motor is allowed;
and a half-engaged clutch determination maintaining device which
outputs a determination signal indicating that the clutch is
half-engaged for a predetermined period of time, when the clutch
operation detection device detects that the clutch is not
disengaged, the throttle opening degree determination device
determines that the degree of throttle opening of the engine is no
more than a predetermined degree, and the clutch state
determination device determines that the clutch is half-engaged.
The first engine speed modification device elevates the
charging/regeneration allowing lower limit engine speed value while
the half-engaged clutch determination maintaining device outputs a
determination signal indicating that the clutch is
half-engaged.
[0009] According to the engine stall prevention apparatus of the
present invention, when a half-engaged clutch determination is
maintained, the charging/regeneration allowing lower limit engine
speed value, below which the charging and regeneration is
forbidden, is increased. Therefore, the load applied to the engine
can be reduced by stopping charging/regeneration earlier than
usual, and engine stalls due to the regeneration operation in a
half-engaged clutch state can be effectively prevented.
[0010] The engine stall prevention apparatus of the present
invention may further comprise a second engine speed modification
device which modifies a fuel cut lower limit engine speed value
above which a fuel amount to be supplied to the engine is cut
during deceleration regeneration, and the second engine speed
modification device elevates the fuel cut lower limit engine speed
value while the half-engaged clutch determination maintaining
device outputs a determination signal indicating that the clutch is
half-engaged.
[0011] In this case, when a half-engaged clutch determination is
maintained, the second engine speed modification device increases
the fuel cut lower limit engine speed value, and the engine speed
value at which fuel supply to the engine is restarted is elevated.
Therefore, the load applied to the engine can be reduced by
restarting fuel supply to the engine earlier than usual, and engine
stalls due to the load increase in the half-engaged clutch state
can be more effectively prevented.
[0012] The engine stall prevention apparatus may further comprise
an engine start allowing device which allows the electric motor to
start the engine or to assist the output of the engine. The engine
start allowing device drives the electric motor to start the engine
or to assist the output of the engine, while the half-engaged
clutch determination maintaining device outputs a determination
signal indicating that the clutch is half-engaged, and the engine
speed becomes lower than a predetermined engine speed value.
[0013] According to this aspect, when the present engine speed
becomes lower than the forced motor start engine speed value, the
engine start allowing device drives the electric motor to start the
engine. Therefore, it is possible to forcedly drive the engine when
the engine is likely to stall, and engine stalls can be more
effectively prevented.
BRIEF DESCRIPTION OF THE DRAWING
[0014] FIG. 1 is a block diagram of a hybrid vehicle according to a
first embodiment of the present invention.
[0015] FIG. 2 is a flowchart showing a process for determining the
motor operation mode according to the first embodiment.
[0016] FIG. 3 is a flowchart showing a process for maintaining the
determination signal indicating that the clutch is half-engaged
according to the first embodiment.
[0017] FIG. 4 is a flowchart showing a process for determining the
gear engagement state according to the first embodiment.
[0018] FIG. 5 is a flowchart showing a process for determining the
gear position according to the first embodiment.
[0019] FIG. 6 is a flowchart showing a process for determining the
fuel cut lower limit engine speed value according to the first
embodiment.
[0020] FIG. 7 is a flowchart showing a process for determining the
hysteresis of the fuel cut lower limit engine speed value according
to the first embodiment.
[0021] FIG. 8 is a flowchart showing a process for forcedly driving
a motor according to the first embodiment.
[0022] FIG. 9 is a graph explaining the process for determining the
gear position shown in FIG. 5.
[0023] FIG. 10 is a graph of a fuel cut table used in the process
shown in FIG. 7.
[0024] FIG. 11 is a graph showing the variation in engine speed
when the half-engaged clutch determination process according to the
present invention is not performed.
[0025] FIG. 12 is a graph showing the variation in engine speed
when the half-engaged clutch determination process according to the
present invention is performed.
DETAILED DESCRIPTION OF THE INVENTION
[0026] Hereinafter, a preferred embodiment of an engine stall
prevention apparatus for a hybrid vehicle according to the present
invention will be explained referring to the figures.
[0027] FIG. 1 is a block diagram illustrating a parallel hybrid
vehicle in which an embodiment of the present invention is applied.
The vehicle comprises an engine E which is activated by the
combustion energy of a fuel, and an electric motor M which is
activated by electric power and assists the engine E. The driving
force generated by both the engine E and the electric motor M is
transmitted via a transmission T consisting of a manual
transmission to a pair of driving wheels (in this embodiment, the
front wheels) Wf. At the time of the deceleration of the hybrid
vehicle, the driving force is transmitted from the driving wheels
Wf to the electric motor M, and the electric motor M functions as a
generator. That is, the electric motor M recovers the kinetic
energy of the vehicle body as electric energy, and the recovered
electric energy is used for charging a battery 3 which will be
explained later. The vehicle has also a pair of rear wheels Wr.
[0028] The driving of the motor M and the regenerating operation of
the motor M are controlled by a power drive unit 2 according to
control commands transmitted from a motor ECU 1. A high voltage
battery 3 for sending and receiving electric energy to and from the
motor M is connected to the power drive unit 2. The battery 3
includes a plurality of modules connected in series, and in each
module, a plurality of cells are connected in series. The hybrid
vehicle includes a 12-V auxiliary battery 4 for driving various
accessories. The auxiliary battery 4 is connected to the battery 3
via a downverter 5. The downverter 5 is controlled by an FIECU 11,
and reduces the voltage from the battery 3 so as to charge the
auxiliary battery 4.
[0029] The motor ECU 1 controls the electric motor M under the
control of the FIECU 11. An electric current sensor S8 and a
voltage sensor S9 are provided for measuring the electric current
and voltage supplied from the battery 3, an electric current sensor
S10 is provided for measuring the three phase electric current
supplied to the electric motor M from the power drive unit 2, and
the outputs of these sensors S8, S9, and S10 are input to the motor
ECU 1. The motor ECU 1 controls the power drive unit 2 in
accordance with the signals from these sensors S8, S9, and S10.
[0030] The FIECU 11 controls, in addition to the motor ECU 1 and
the downverter 5, a fuel supply amount controller 6 for controlling
the amount of fuel supplied to the engine E, a starter motor 7, the
ignition timing, etc. Therefore, the FIECU 11 receives (i) a signal
from a speed sensor S1 for detecting the vehicle speed based on the
rotation of the drive shaft of transmission T, (ii) a signal from
an engine (rotational) speed sensor S2 for detecting the engine
(rotational) speed, (iii) a signal from a neutral position switch
S3 for detecting the neutral position of the transmission T, (iv) a
signal from a brake switch S4 for detecting operation of a brake
pedal 8, (v) a signal from a clutch switch S5 for detecting the
operation of a clutch pedal 9, (vi) a signal from a throttle
opening-degree sensor S6 for detecting the degree of opening TH of
the throttle (valve), and (vii) a signal from an air-intake passage
pressure sensor S7 for detecting the air-intake passage (negative)
pressure PB. As shown in FIG. 1, a battery ECU 31 is provided for
protecting the battery 3, and the battery ECU 31 calculates the
remaining capacity SOC of the battery 3.
[0031] This hybrid vehicle can enter various control modes, such as
an "idle stop mode", "idle mode", a "deceleration mode", an
"acceleration mode", and a "cruise mode". Referring to the
flowchart shown in FIG. 2, the process for determining the above
four motor control modes will be explained.
[0032] First, in step S001, it is determined whether the present
state is an in-gear state in accordance with the flow shown in FIG.
4. This flow will be explained later in detail. When the present
state is determined to be an off-gear state in step S001, the flow
proceeds to step S014, and it is determined whether an idle stop is
being performed. If an idle stop is being performed, the flow
proceeds to step S015, and the driving mode of the vehicle is set
to an idle stop mode. In this idle stop mode, for example, when the
vehicle is stopped, the engine E will be stopped upon predetermined
conditions. In contrast, if it is determined in step S014 that an
idle stop is not performed, the flow proceeds to step S016, and the
driving mode of the vehicle is set to the idle mode. In the idle
mode, fuel is continuously supplied to the engine E so as to
maintain the engine in an idling state.
[0033] In step S001, if it is determined that the gears are engaged
(that is, an in-gear state), the flow proceeds to step S002, and it
is determined whether the throttle is completely closed. If the
throttle is not completely closed, the flow proceeds to step S003
in order to determine whether an assistance trigger is being
output. If an assistance trigger is being output, the flow proceeds
to step S004, the driving mode of the vehicle is set to the
acceleration mode, and then, the flow ends. In this acceleration
mode, the electric motor M assists the output of the engine E.
[0034] When it is determined in step S002 that the throttle is
completely closed, or when it is determined in step S003 that an
assistance trigger is not output, the flow proceeds to step
S005.
[0035] In step S005, it is determined whether the vehicle speed is
zero. If the vehicle speed is zero, the flow proceeds to step S014.
If the vehicle speed is not zero, the flow proceeds to step S006,
and it is determined whether an idle stop is being performed. If it
is determined in step S006 that an idle stop is being performed,
the flow proceeds to step S015. If an idle stop is not performed in
step S006, the flow proceeds to step S007, and it is determined
whether a steep drop in engine speed has occurred. If it is
determined in step S007 that a steep drop in engine speed has
occurred, the flow proceeds to step S016, and the driving mode is
set to the idle mode. By changing to the idle mode, for example, in
the case where the deceleration regeneration is being performed,
the deceleration regeneration is stopped so as to reduce the load
of the engine E, and engine stalls can be prevented. If it is
determined in step S007 that there is not a steep drop in engine
speed, the flow proceeds to step S008. The threshold of engine
speed change for determining whether there is a steep drop in
engine speed is, for example, 300 rpm/100 msec.
[0036] In step S008, if it is determined whether the half-engaged
clutch determination described later is maintained, by means of
determining whether a half-engaged clutch determination maintaining
flag F_HALFCL is "1". The flow for setting this half-engaged clutch
determination maintaining flag F_HALFCL will be explained later. If
it is determined in step S008 that a half-engaged clutch
determination is not maintained, the flow proceeds to step S009. In
step S009, an engine speed value corresponding to the present gear
position is retrieved in a predetermined table, the retrieved
engine speed value is set as a charging/regeneration allowing lower
limit engine speed value above which the charging of the battery 3
and regeneration by the electric motor M are allowed, and the flow
proceeds to step S011.
[0037] If it is determined in step S008 that a half-engaged clutch
determination is maintained, the flow proceeds to step S010. In
step S010, an engine speed value corresponding to the present gear
position is retrieved in the predetermined table, and a
predetermined value .alpha. is added to the retrieved engine speed
value. The obtained value is set as a charging/regeneration
allowing lower limit engine speed value above which the charging of
the battery 3 and regeneration by the electric motor M are allowed,
and the flow proceeds to step S011. For example, the predetermined
value .alpha. is 1000 rpm, and in this case, the
charging/regeneration allowing lower limit engine speed value is
1500 rpm.
[0038] In this way, when a half-engaged clutch determination is
maintained, because the charging/regeneration allowing lower limit
engine speed value is increased by adding the predetermined
compensating value .alpha., the upper limit value, below which the
charging of the battery 3 and regeneration by the electric motor M
are not performed, is raised, and the load of the engine E can be
reduced. Therefore, engine stalls can be prevented.
[0039] In step S011, the present engine speed is compared with the
charging/regeneration allowing lower limit engine speed value.
Here, the charging/regeneration allowing lower limit engine speed
value used in step S011 is a value having hysteresis as is
explained later.
[0040] If it is determined in step S011 that the present engine
speed is equal to or below the charging/regeneration allowing lower
limit engine speed value, the flow proceeds to step S016, and the
driving mode is set to the idle mode.
[0041] If it is determined in step S011 that the present engine
speed is higher than the charging/regeneration allowing lower limit
engine speed value, the flow proceeds to step S012, and it is
determined whether deceleration fuel cut is being performed. If it
is determined in step S012 that the deceleration fuel cut is being
performed, the flow proceeds to step S013, and the driving mode is
set to the deceleration mode. In this deceleration mode,
regeneration braking is performed by the electric motor M.
[0042] In contrast, If it is determined in step S012 that the
deceleration fuel cut is not being performed, the flow proceeds to
step S017, and the driving mode is set to the cruising mode. In
this cruising mode, the electric motor M is not activated, and only
the engine E drives the vehicle.
[0043] Next, referring to FIG. 3, the flow for determining whether
a half-engaged clutch determination is maintained will be
explained.
[0044] In step S021, it is determined whether the gears are engaged
in accordance with a process which will be explained later. If it
is determined in step S021 that the gears are engaged, the flow
proceeds to step S022, and it is determined whether the throttle is
completely closed. If it is determined in step S022 that the
throttle is not completely closed, the flow proceeds to step S023,
and the half-engaged clutch determination maintaining flag F_HALFCL
is set to "0" so that the half-engaged clutch determination is
halted. If it is determined in step S021 that the gears are not
engaged, the flow ends. According to this flow, when the driver of
the vehicle depresses an acceleration pedal, the half-engaged
clutch determination is halted. Therefore, it is possible to
rapidly halt the half-engaged clutch determination according to an
action by the driver.
[0045] In step S022, if it is determined that the throttle is
completely closed, the flow proceeds to step S024, and it is
determined whether a half-engaged clutch determination allowance
timer value is "0". If the half-engaged clutch determination
allowance timer value is "0", the flow proceeds to step S025. If
the half-engaged clutch determination allowance timer value is not
"0", the flow ends. This half-engaged clutch determination
allowance timer value will be set in step S055 shown in FIG. 5
which will be explained later.
[0046] In step S025, it is determined whether the gear position is
shifted to the higher ratio position. If it determined in step S025
that the gear position is not shifted to the higher ratio position,
the flow proceeds to step S026, and it is further determined
whether the engine speed has steeply dropped. If it is determined
in step S026 that the engine speed has steeply dropped, the flow
proceeds to step S027, and the half-engaged clutch determination
maintaining flag F_HALFCL is set to "1" so that the half-engaged
clutch determination is maintained. Thus, the flow ends. In
contrast, if it is determined in step S026 that the engine speed
has not steeply dropped, the flow ends.
[0047] Next, with regard to step S001 shown in FIG. 2 and step S021
shown in FIG. 3, the flow for determining whether the gears are
engaged will be explained referring to FIG. 4. In step S031, it is
determined whether the clutch switch S5 is in the OFF state, in
order to determine whether the clutch is engaged. If it is
determined in step S031 that the clutch switch S5 is in the ON
state, the flow proceeds to step S034, and the present state is
determined to be an off-gear state. Then, the flow ends. If it is
determined in step S031 that the clutch switch S5 is in the OFF
state, the flow proceeds to step S032, and it is determined whether
the neutral switch S3 is in the OFF state in order to determine
whether the gears are engaged.
[0048] If it is determined in step S032 that the neutral switch S3
is in the OFF state, the flow proceeds to step S033, and it is
determined that the gears are engaged (that is, in an in-gear
state). Then, the flow ends. If it is determined in step S032 that
the present state is not an in-gear state, the flow proceeds to
step S034, and it is determined that the gears have been
disengaged.
[0049] Next, FIG. 5 illustrates a flowchart for determining gear
position, and this flow will be explained referring to the graph
shown in FIG. 9.
[0050] First, the reason why the gear position can be determined
based on the engine speed NE and the vehicle speed V will be
explained. In a manual transmission vehicle, when the gears are
engaged (that is, the gear position is other than the neutral
position), and further when the clutch is engaged, the output shaft
of the engine E and the driving wheels Wf are directly connected.
At this time, as shown in FIG. 9, the relationship between the
vehicle speed V and the engine speed NE is a proportional
relationship at each gear ratio determined by the gear position,
and the gradient of each graph corresponds to the gear ratio.
[0051] Therefore, when the output shaft of the engine E and the
driving wheels Wf are connected, a coordinate expressed by an
engine speed NE and a vehicle speed V which are respectively
measured can be positioned on one of the graphs shown in FIG. 9.
Therefore, by determining which graph includes the measured
coordinate, the present gear position can be estimated.
[0052] In this embodiment, as shown in FIG. 9, a first boundary
line L1 is provided between the linear graphs corresponding
respectively to the first and second shift positions. As well,
second to fourth boundary lines L2 to L4 are respectively provided
between the neighboring linear graphs corresponding to the second
to fifth shift positions. Furthermore, in order to detect a change
from the fifth shift position, a fifth boundary line L5 is provided
between the linear graph corresponding to the fifth shift position
and an imaginary linear graph corresponding to an imaginary sixth
shift position which does not actually exist. Therefore, the engine
speed NE vs. vehicle speed V plane is divided into six areas by the
first to fifth boundary lines L1 to L5, and by determining the area
to which the measured coordinate belongs, it is possible to
determine the present gear position.
[0053] The actual gear position determination is performed as
follows. In step S051, it is determined whether the engine E is
stalling. If it is determined that the engine E is stalling, the
flow proceeds to step S067, and it is determined that the present
gear position is the first shift position. If it is determined in
step S051 that the engine E is not stalling, the flow proceeds to
step S052, and it is determined whether the vehicle speed sensor S1
has failed. If the vehicle speed sensor S1 has failed, the flow
proceeds to step S067. If the vehicle speed sensor S1 has not
failed, the flow proceeds to step S053, and it is further
determined whether the state of the clutch switch S5 has
changed.
[0054] If a change is detected in the state of the clutch switch
S5, the flow proceeds to step S054, and a stabilizing timer is set
for waiting for stabilization after engaging the clutch. Then, the
flow proceeds to step S055, and a half-engaged clutch determination
maintenance allowing timer is set for allowing maintenance of the
half-engaged clutch determination.
[0055] If a change is not detected in the state of the clutch
switch S5 in step S053, the flow proceeds to step S056, and it is
determined whether the value of the stabilizing timer is "0". If
the value of the stabilizing timer is not "0", the flow ends. In
contrast, if the value of the stabilizing timer is "0" in step
S056, the flow proceeds to step S057, and it is determined whether
the coordinate corresponding to the present engine speed NE and the
present vehicle speed V is positioned at the left side of first
boundary line L1 in FIG. 9 (that is, whether the ratio V/NE of the
coordinate is smaller than the ratio V/NE of the boundary line
L1).
[0056] If it is determined in step S057 that the ratio V/NE of the
coordinate is smaller than the ratio V/NE of the boundary line L1,
the flow proceeds to step S067, and it is determined that the
present gear position is the first shift position. Then, the flow
ends.
[0057] If it is determined in step S057 that the ratio V/NE of the
coordinate is equal to or greater than the ratio V/NE of the
boundary line L1, the flow proceeds to step S058, and it is further
determined whether the ratio V/NE of the coordinate is smaller than
the ratio V/NE of the boundary line L2. If it is determined in step
S058 that the ratio V/NE of the coordinate is smaller than the
ratio V/NE of the boundary line L2, the flow proceeds to step S066,
and it is determined that the present gear position is the second
shift position. Then, the flow ends.
[0058] If it is determined in step S058 that the ratio V/NE of the
coordinate is equal to or greater than the ratio V/NE of the
boundary line L2, the flow proceeds to step S059, and it is further
determined whether the ratio V/NE of the coordinate is smaller than
the ratio V/NE of the boundary line L3. If it is determined in step
S059 that the ratio V/NE of the coordinate is smaller than the
ratio V/NE of the boundary line L3, the flow proceeds to step S065,
and it is determined that the present gear position is the third
shift position. Then, the flow ends.
[0059] If it is determined in step S059 that the ratio V/NE of the
coordinate is equal to or greater than the ratio V/NE of the
boundary line L3, the flow proceeds to step S060, and it is further
determined whether the ratio V/NE of the coordinate is smaller than
the ratio V/NE of the boundary line L4. If it is determined in step
S060 that the ratio V/NE of the coordinate is smaller than the
ratio V/NE of the boundary line L4, the flow proceeds to step S064,
and it is determined that the present gear position is the fourth
shift position. Then, the flow ends.
[0060] If it is determined in step S060 that the ratio V/NE of the
coordinate is equal to or greater than the ratio V/NE of the
boundary line L4, the flow proceeds to step S060A, and it is
determined whether the clutch switch S5 is in the OFF state. If the
clutch switch S5 is in the ON state, the flow proceeds to step
S063, and it is determined that the present gear position is the
fifth shift position. Then, the flow ends.
[0061] If it is determined in step S060A that the clutch switch S5
is in the ON state, the flow proceeds to step S061, and it is
determined whether the ratio V/NE of the coordinate is smaller than
the ratio V/NE of the boundary line L5. If it is determined in step
S061 that the ratio V/NE of the coordinate is smaller than the
ratio V/NE of the boundary line L5, the flow proceeds to step S063,
and it is determined that the present gear position is the fifth
shift position. Then, the flow ends.
[0062] If it is determined in step S061 that the ratio V/NE of the
coordinate is equal to or greater than the ratio V/NE of the
boundary line L5, the flow proceeds to step S062, and it is
determined that the present gear position is the fifth over shift
position. Then, the flow ends. When the gear position is determined
to be the fifth over shift position, because the clutch switch S5
is not in the OFF state and the clutch is not completely
disengaged, the gear potion is determined to be the half-engaged
clutch state.
[0063] Next, referring to FIG. 6, the flow for determining a fuel
cut lower limit engine speed value, above which a fuel amount to be
supplied to the engine is cut, will be explained.
[0064] In this hybrid vehicle, when the vehicle decelerates, the
fuel amount to be supplied to an engine is cut so as to reduce the
fuel consumption during the deceleration. Then, when the engine
speed becomes lower than a predetermined lower limit engine speed
value below which the engine cannot drive the vehicle by itself,
the fuel supply is restarted so as to maintain the engine speed at
the lower limit. On the other hand, in the case where the fuel cut
is continued until an idle stop, the lower limit engine speed above
which the fuel cut is performed is lowered.
[0065] However, in such a case, if the clutch is half-disengaged
when deceleration fuel cut is being performed, because the
rotational force of the driving wheels is not transmitted to the
motor, the most of the deceleration regeneration torque by the
motor is applied to the engine, and the engine speed steeply drops.
Therefore, even if the fuel supply is restarted when the engine
speed reaches the predetermined lower limit engine speed value,
there will be the problems that the engine will stall or that an
excessive load will be applied to the engine. In order to overcome
these problems, in the present embodiment, when a half-engaged
clutch state is detected, the fuel cut lower limit engine speed
value is elevated, and fuel supply is restarted at an engine speed
higher than usual. Thus, in the present embodiment, the
effectiveness in preventing engine stalls can be improved. In the
following embodiment, when a half-engaged clutch state is detected,
the fuel cut lower limit engine speed value is relatively high in
comparison with the usual value by stopping the lowering of the
fuel cut lower limit engine speed value which is performed in the
usual occasion.
[0066] In step S071 shown in FIG. 6, it is determined whether the
gears are engaged. If the present state is an in-gear state, the
flow proceeds to step S072, and it is further determined whether
the gear position is the first shift position. If it is determined
in step S072 that the gear position is other than the first shift
position, the flow proceeds to step S073, and it is determined
whether the half-engaged clutch determination is maintained by
determining whether the half-engaged clutch determination
maintaining flag F_HALFCL is "1".
[0067] In step S072, if the half-engaged clutch determination is
not maintained, the flow proceeds to step S074, and it is
determined whether the brake is in the ON state. If it is
determined in step S074 that the brake is in the ON state, the flow
proceeds to step S075, and a predetermined value for a brake-on
state is set as a value to be subtracted from the fuel cut lower
limit engine speed value. Then the flow proceeds to step S077. If
it is determined in step S074 that the brake is in the OFF state,
the flow proceeds to step S076, and a predetermined value for a
brake-off state is set as a value to be subtracted from the fuel
cut lower limit engine speed value. Then the flow proceeds to step
S077.
[0068] In step S077, the value selected in step S075 or S076 is
subtracted from a basic table retrieved value which is obtained in
advance by retrieving in a basic table, and the resulted value is
set as the fuel cut lower limit engine speed value. Then the flow
ends.
[0069] On the other hand, when it is determined in step S071 that
the gears are in the OFF state, or when it is determined in step
S072 that the gear position is the first shift position, or when it
is determined in step S073 that the half-engaged clutch
determination is maintained, the flow proceeds to step S078, and
the basic table retrieved value, which is obtained in advance by
retrieving in a basic table, is set as the fuel cut lower limit
engine speed value. Then the flow ends.
[0070] Therefore, the fuel cut lower limit engine speed value
obtained in step S078 is greater than that obtained in step S077 by
the subtracted value. By means of this, when the half-engaged
clutch determination is maintained, because the fuel cut lower
limit engine speed value becomes greater than usual, the
effectiveness in preventing engine stalls can be improved, and it
is also possible to prevent an excessive load from being applied to
the engine E.
[0071] Next, referring to the flowchart shown in FIG. 7, a control
flow for applying hysteresis in the fuel cut lower limit engine
speed value will be explained. By applying hysteresis, it is
possible to prevent hunting from occurring in a range neighboring
the fuel cut lower limit engine speed value. Even in this control
flow, it is determined whether the half-engaged clutch
determination is maintained.
[0072] In step S081, it is determined whether the gears are
engaged. If the gears are in an in-gear state, the flow proceeds to
the step S082, and it is determined whether the half-engaged clutch
determination is maintained. If it is determined in step S082 that
the half-engaged clutch determination is not maintained, the flow
proceeds to step S083, and it is determined whether the temperature
of the cooling water in the engine E is equal to or higher than a
predetermined temperature. If the cooling water temperature is
equal to or higher than the predetermined temperature, the flow
proceeds to step S084, and it is determined whether the vehicle is
cruising. If it is determined in step S084 that the vehicle is not
cruising, the flow proceeds to step S085. Also, when the gears are
in an off-gear state in step S081, or when the half-engaged clutch
determination is maintained in step S082, or when the temperature
of the cooling water in the engine E is lower than the
predetermined temperature in step S083, the flow proceeds to step
S085.
[0073] In step S085, it is determined whether a fuel cut is being
performed. If a fuel cut is being performed, the flow proceeds to
step S087, an engine speed value is obtained by inputting the
target idle speed in the lower graph (LOW) in the basic table shown
in FIG. 10, and the obtained value is set as the fuel cut lower
limit engine speed value. Then the flow ends. If it is determined
in step S084 that the vehicle is cruising, the flow also proceeds
to step S087, and the above procedure is performed.
[0074] On the other hand, if it is determined in step S085 that a
fuel cut is not being performed, the flow proceeds to step S086, an
engine speed value is obtained by inputting the target idle speed
in the upper graph (HIGH) in the basic table shown in FIG. 10, and
the obtained value is set as the fuel cut lower limit engine speed
value. Then the flow ends.
[0075] According to the above flow, if a half-engaged clutch
determination is maintained, regardless of the temperature of the
engine cooling water and whether the vehicle is cruising, it is
determined only whether a fuel cut is being performed, and based on
the determination, a fuel cut lower limit engine speed value is
retrieved in the basic table shown in FIG. 10.
[0076] Next, referring to the flowchart shown in FIG. 8, the
control flow for performing a forced motor start will be explained.
The purpose of this flow is to forcedly start the electric motor M
when the engine E is likely to stall.
[0077] In step S101, it is determined, by judging whether a forced
motor start preliminary condition determination flag F_EMGMOTP is
"1", whether the forced motor start preliminary conditions are
satisfied. The forced motor start preliminary conditions will be
explained later.
[0078] If the forced motor start preliminary conditions are not
satisfied, that is, if the forced motor start preliminary condition
determination flag F_EMGMOTP is "0", the flow proceeds to step
S102, and it is determined whether a fuel cut was performed in the
previous cycle. If it is determined in step S102 that a fuel cut
was not performed in the previous cycle, the flow proceeds to step
S114, and the forced motor start preliminary condition
determination flag F_EMGMOTP is set to "0" so that the forced motor
start preliminary conditions are reset. Then, the flow proceeds to
step S115, the forced motor start procedure is cancelled, and the
flow returns.
[0079] If it is determined in step S102 that a fuel cut was
performed in the previous cycle, the flow proceeds to step S103,
and it is determined whether a fuel cut is being performed in the
present cycle. If it is determined in step 103 that a fuel cut is
being performed in the present cycle, the flow proceeds to step
S114. If it is determined in step 103 that a fuel cut is not
performed in the present cycle, the flow proceeds to step S104, and
it is determined whether the fuel cut lower limit engine speed
value was reduced in the previous cycle. If it is determined in
step S104 that the fuel cut lower limit engine speed value was not
reduced in the previous cycle, the flow proceeds to step S114.
[0080] In contrast, if it is determined in step S104 that the fuel
cut lower limit engine speed value was reduced in the previous
cycle, the flow proceeds to step S105. In this case, because the
forced motor start preliminary condition is satisfied, the forced
motor start preliminary condition determination flag F_EMGMOTP is
set to "1", and the flow proceeds to step S106. In step S106, a
forced motor start maintenance allowing timer is set, and the flow
proceeds to step S107.
[0081] As well, if it is determined in step S101 that the forced
motor start preliminary condition is satisfied, the flow proceeds
to step S107.
[0082] That is, in the case where, a fuel cut was performed in the
previous cycle (the determination in step S103 is Yes), a fuel cut
is not performed in the present cycle (the determination in step
S104 is No), and the fuel cut lower limit engine speed value was
reduced in the previous cycle (the determination in step S104 is
Yes), the forced motor start preliminary conditions are
satisfied.
[0083] In step S107, it is determined whether the value of the
forced motor start maintenance allowing timer is "0", and if it is
"0", the flow proceeds to step S114. If it is determined in step
S107 that the value of the timer is "1", the flow proceeds to step
S108, and it is determined whether the gears are engaged.
[0084] If it is determined in step S108 that the gears are engaged,
the flow proceeds to step S109. If it is determined in step S108
that the gears are not engaged, the flow proceeds to step S112, and
it is determined whether the present engine speed is lower than a
forced motor start engine speed at which the electric motor is to
be started. If it is determined in step S112 that the present
engine speed is equal to or greater than the forced motor start
engine speed, the flow proceeds to step S115. In step S112, if the
present engine speed is smaller than the forced motor start engine
speed, the flow proceeds to step S113, and the forced motor start
is performed. Then, the flow returns. According to the above flow,
engine stalls can be prevented.
[0085] In step S109, it is determined whether the throttle is
completely closed. If the throttle is not completely closed, that
is, the degree of the throttle opening is not the degree of idle
throttle opening, the flow proceeds to step S114. If it is
determined in step S109 that the throttle is completely closed,
that is, the degree of the throttle opening is the degree of the
idle throttle opening, the flow proceeds to step S110, and it is
determined whether an idle stop is allowed. If it is determined in
step S110 that an idle stop is allowed, the flow proceeds to step
S115. On the other hand, if it is determined in step S110 that an
idle stop is not allowed, the flow proceeds to step S111, and it is
determined whether a half-engaged clutch determination is
maintained by detecting whether the half-engaged clutch
determination maintaining flag F_HALFCL is "1".
[0086] In step S111, if the half-engaged clutch determination is
maintained, the flow proceeds to step S112. In contrast, if the
half-engaged clutch determination is not maintained, the flow
proceeds to step S115. Therefore, in the case where, the forced
motor start preliminary conditions are satisfied, the half-engaged
clutch determination is maintained, and the present engine speed is
lower than the forced motor start engine speed, the electric motor
M will be forcedly started so as to prevent engine stalls.
[0087] According to the above embodiment, it is possible to
securely detect a half-engaged clutch state. The clutch switch S5
is constructed not to enter the ON state unless the clutch pedal is
fully depressed so that the OFF state of the clutch can be securely
detected even when the clutch is abraded. In a half-engaged clutch
state, the clutch pedal is not fully depressed but is only slightly
depressed, and it is not possible to detect the half-engaged clutch
state only based on the ON/OFF state of the clutch switch S5.
[0088] In contrast, according to the present embodiment, when the
determination in step S060A shown in FIG. 5 is "Yes" (that is, when
the clutch pedal is not fully depressed), and further when the gear
position is determined to be the fifth over shift position, it is
determined that the clutch is half-engaged. Thus, an half-engaged
clutch state can be precisely detected.
[0089] Furthermore, when an half-engaged clutch state is detected
in the present embodiment, the half-engaged clutch determination is
maintained for a predetermined period of time, and the control is
performed so as to correspond to the half-engaged clutch state.
Therefore, unstable variations in the engine speed can thereby be
prevented.
[0090] For example, in a conventional hybrid vehicle, when the
clutch is half-disengaged from a fully-engaged state during the
deceleration regeneration, because the driving force of the driving
wheels is not transmitted to the electric motor, the whole
regeneration torque generated by the electric motor is suddenly
applied to the engine as a large load. This phenomenon will
repeatedly occur each time the clutch is half-disengaged, and, as
shown in FIG. 11, it results in repeating variations in the engine
speed.
[0091] In contrast, according to the present embodiment, by
maintaining the half-engaged clutch determination as shown in FIG.
12, such repeating variations in the engine speed can be prevented
as shown in the same figure.
[0092] In addition, because the half-engaged clutch determination
will be cancelled in step S022 shown in FIG. 3 as soon as the
throttle valve is slightly opened, the cancellation of the
half-engaged clutch determination can be rapidly and automatically
performed in accordance with the intent of the driver.
[0093] Moreover, when a half-engaged clutch determination is
maintained, in step S010 shown in FIG. 2, the charging/regeneration
allowing lower limit engine speed value is set to a value to which
a predetermined value a is added. In this way, because the
charging/regeneration allowing lower limit engine speed value,
below which the charging and regeneration is forbidden, is
increased when a half-engaged clutch determination is maintained,
the load applied to the engine can be reduced. Therefore, engine
stalls due to the regeneration operation in a half-engaged clutch
state can be effectively prevented.
[0094] Furthermore, according to the present embodiment, when a
half-engaged clutch determination is maintained, the fuel cut lower
limit engine speed value is increased by canceling the cut down
thereof which is to be performed in the other case. Therefore, even
in this point, engine stalls due to the load increase in the
half-engaged clutch state can be effectively prevented.
[0095] In addition, according to the present embodiment, as shown
in FIG. 7, if a half-engaged clutch determination is maintained,
regardless of the temperature of the engine cooling water and
whether the vehicle is cruising, it is determined only whether a
fuel cut is being performed, and based on this determination, a
fuel cut lower limit engine speed value is retrieved from the basic
table shown in FIG. 10. Thus, by applying hysteresis to the fuel
cut lower limit engine speed value, it is possible to prevent
hunting from occurring.
[0096] Furthermore, according to the present embodiment, in the
case where, the forced motor start preliminary conditions are
satisfied, the half-engaged clutch determination is maintained, and
the present engine speed is lower than the forced motor start
engine speed value, the electric motor will start to rotate the
output shaft of the engine E. Therefore, it is possible to forcedly
drive the engine E when the engine E is likely to stall, and engine
stalls can be prevented.
* * * * *