Electricity: single generator systems – With physical starting and/or stopping of the generator – Connecting and/or disconnecting generator and driving means
Reexamination Certificate
2000-03-08
2001-11-06
Ponomarenko, Nicholas (Department: 2834)
Electricity: single generator systems
With physical starting and/or stopping of the generator
Connecting and/or disconnecting generator and driving means
C322S099000
Reexamination Certificate
active
06313613
ABSTRACT:
TECHNICAL FIELD
The present invention relates to a vehicle AC-generator controller for establishing a no-power-generation state in which no power is generated by cutting off the field current of a vehicle AC-generator when the vehicle AC-generator is brought into the no-power-generation state in order to reduce the load of an engine, for example, upon start of the engine.
BACKGROUND ART
FIG. 3
is a block diagram of a conventional vehicle AC-generator controller disclosed in, for example, Japanese Patent Publication No. 3-47058. In
FIG. 3
, an AC generator
1
includes a rotor winding
102
and three three-phase stator windings
101
R to
101
T connected with each other in a star-like manner. Diode bridges comprising a full-wave rectifier
2
are provided for each phase of the three stator windings
101
R to
101
T. Voltages induced in the stator windings
101
R to
101
T by the rotor winding
102
are full-wave rectified by the full-wave rectifier
2
and applied to a charge terminal B of a battery
8
through an output terminal
201
.
An output voltage of the AC generator
1
is adjusted by a voltage regulator
3
in accordance with a charge voltage detected by the charge terminal B of the battery
8
. A source voltage is supplied to the voltage regulator
3
by the battery
8
through an externally provided engine key
7
and transistor
5
.
The voltage regulator
3
includes a control monolithic IC
303
for detecting a charge voltage through the charge terminal B of the battery
8
to output a field-current control signal having a predetermined duty ratio corresponding to the level of the charge voltage as well as for detecting a no-power-generation state of the AC generator
1
in accordance with an induced voltage applied to the stator winding
101
S to output a no-power-generation detection signal, a power transistor
306
having a base adapted to be inputted by a field-current control signal, a grounded emitter and a collector connected to the positive side of the battery
8
through a reversely connected diode, and a power transistor
301
having a base adapted to be inputted by a no-power-generation detection signal, a grounded emitter and a collector connected to an end of a charge lamp
6
.
Moreover, when the power transistor
306
is turned on, a field current flows through the rotor winding
102
, power transistor
306
and ground from the battery
8
. Moreover, when the power transistor
301
is turned on, a current flows from the battery
8
to ground through the engine key
7
, charge lamp
6
and power transistor
301
to turn on the charge lamp
6
. Resistances
302
and
304
for applying a base voltage to the power transistors
301
and
306
are connected between the bases of the power transistors
301
and
306
and the power-supply line of the control monolithic IC
303
.
A transistor
301
constituting an external unit
4
is connected at its collector to the base of the transistor
5
for supplying a source voltage to the control monolithic IC
303
through a resistance
402
. An emitter of the transistor
301
is grounded and a signal indicative of the driving state of a vehicle (a driving-state signal) is input to the base of the transistor
301
from various sensors and switches (not shown).
In this case, the operation-state signal denotes a signal such as an on-output signal of an unillustrated starter switch or an engine-cooling-water-temperature signal of an unillustrated water temperature sensor. The external unit
4
inputs an off signal to the transistor
301
for a certain period of time in accordance with each signal in order to reduce the load of an engine when the engine is started. As a result, the transistor
5
is turned off, thereby cutting off the supply of power from the battery
8
to the control monolithic IC
303
and stopping the generation of a field current.
In the operation of a conventional controller, when the control monolithic IC
303
detects a voltage drop of the battery
8
after an engine is started, it turns on and off the power transistor
306
at a predetermined duty ratio to intermittently supply a field current to the rotor winding
102
from the battery
8
. By supplying the field current, an induced voltage is generated in the stator windings
101
R to lost by a magnetic field generated in the rotor winding
102
. Moreover, the generated induced voltage is full-wave rectified by the full-wave rectifier
2
, applied to the charge terminal B through the output terminal
201
, and charged to the battery
8
.
Moreover, when the control monolithic IC
303
detects a voltage drop of the battery
8
immediately after the engine key
7
has been turned on (i.e., immediately after the engine has been started), the monolithic IC
303
turns on the power transistor
306
to supply a field current to the rotor winding
102
from the battery
8
to thereby form a magnetic field in the AC generator
1
. In this case, however, because the engine is not operated to run, the AC generator
1
does not generate power, resulting in the no-power-generation state.
When the control monolithic IC
303
detects the no-power-generation state from the stator winding
101
S, it drives the power transistor
301
to turn on the charge lamp
6
, thus notifying the driver that the battery
8
is currently discharging.
However, when the AC generator
1
starts the power-generating operation by forming a magnetic field in the generator
1
immediately after an engine has started, particularly during a cold period when the function of a battery is deteriorated, the engine rotation becomes unstable due to fluctuation of the generator load torque. Therefore, immediately after start of the engine, the transistor
5
is turned off upon an operation-state signal being inputted to the transistor
301
in the form of the external unit
4
for a certain time until the speed of the engine reaches a predetermined value, thereby turning off the transistor
301
to cut off the supply of power to the control monolithic IC
303
. Because the supply of power is cut off, the control monolithic IC
303
stops generating an output to the power transistor
306
to thereby cut off the field current, and hence the AC generator
1
is forced into the no-power-generation state.
Thus, because the source voltage of the control monolithic IC
303
is cut off, no field current is supplied to the rotor winding
102
and the AC generator
1
is brought into the no-power-generation state. However, when the above configuration is used, the transistor
5
having a large current capacity for cutting off a power supply is necessary in addition to the external unit
4
and thus, a large-scale circuit configuration is required.
Moreover, if, for any reason, a leak current is supplied to the power-supply terminal of the control monolithic IC
303
due to a positive potential, a problem occurs in that the power supply cannot be cut off by the external unit
4
and thus, the no-power-generation state cannot be realized.
The present invention is intended to solve the above problems and its object is to provide a vehicle AC-generator controller capable of bringing an AC generator into a no-power-generation state by cutting off a field current in order to reduce the load of an engine upon starting thereof.
DISCLOSURE OF THE INVENTION
The present invention according to one aspect includes a vehicle AC-generator controller includes a storage battery to be charged by a rectification output of an AC generator having a field coil, a voltage regulator for controlling an output voltage of the AC generator to a predetermined value by controlling a field current flowing through the field coil, detection means for detecting a power-generation state and a no-power-generation state of the AC generator, an indicator lamp for indicating the power-generation state and the no-power-generation state of the AC generator, indicator-lamp driving means for turning on and off the indicator lamp in accordance with the detection result of the detection means, power-supply driving means for driving a power-s
Iwatani Shiro
Sasaki Katsuhiro
Mitsubishi Denki & Kabushiki Kaisha
Ponomarenko Nicholas
Sughrue Mion Zinn Macpeak & Seas, PLLC
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