O2 sensor TOYOTA PRIUS 2001 Service Owners Manual

CHASSIS ± BRAKES
182CH57
To Reservoir TankFrom Master Cylinder
Pressure
SensorPressure
Sensor
SLR
OFF
SLA
ON
SMC1
ON ONSMC2
Stroke
Simulator
ReservoirSS
ON
Pressure
SensorPressure
Sensor
SRrH
ONSFRH
ON
SRrR
ONSFRR
OFFSFLH
OFF
SFLR
OFF
Rear Wheel CylindersFront Wheel Cylinders P & B Valve11 7

Sample of ABS control 

CHASSIS ± BRAKES
Battery
Acceptance
Capacity
182CH58
Braking
Force
Regenerative
Braking ForceHydraulic
Braking Force
Vehicle SpeedRegenerative
Braking ForceHydraulic
Braking Force
Time
Changes in Regenerative Braking Force Changes in Braking Force Apportionment
Braking
Force
Driver's DemandDriver's Demand 11 8
2) Regenerative Brake Cooperative Control
a. General
The regenerative brake cooperative control uses the switching valves and linear solenoid valves to regu-
late the hydraulic pressure that is supplied to the wheel cylinders. It also operates cooperatively with
the regenerative braking force that is generated in the MG2 in accordance with the master cylinder pres-
sure.
b. Apportioning of the Brake Force
The apportioning of the brake force between the hydraulic brake and the regenerative brake varies by
the vehicle speed and time.
The apportioning of the brake force between the hydraulic brake and the regenerative brake is con-
trolled so that the total brake force of the hydraulic brake and the regenerative brake matches the brake
force that the driver requires.

Imagery Drawing 
c. Operation
Regenerative brake cooperative control is executed when the vehicle is driven in the shift position ªDº
or ªBº.
The master cylinder pressure that is generated when the driver presses on the brake pedal is detected
by the pressure sensor, and the brake ECU calculates the brake force request factor. A portion of the
brake force request factor is transmitted to the HV ECU in the form of a regenerative brake activation
request factor. The HV ECU executes generative braking by commanding the electric motor to generate
negative torque.
The brake ECU controls the opening of the linear solenoid valves, which are used for increasing / de-
creasing the hydraulic pressure, to regulate the wheel cylinder hydraulic pressure in relation to the mas-
ter cylinder hydraulic pressure, thus compensating for the brake force that is not provided sufficiently
by the regenerative brake.
While the regenerative brake cooperative control is being prohibited due to an abnormality in the sys-
tem, or when the shift lever is in a position other than D or B, the regenerative braking force is not gener-
ated. At this time, only the hydraulic braking force is applied by turning ON (opening) the linear sole-
noid valve SLA and turning OFF (closing) the SLR.

CHASSIS ± BRAKES
182CH59
Reservoir TankAccumulator
Pump Motor
Pressure Switches
Relief
Valve
Master Cylinder
Pressure Sensor
Pressure Sensor
SLR SLA
Stroke
Simulator ON
ON ON
SS
Reservoir
Pressure
Sensor
SRrH
OFF
SRrR
OFF
P & B Valve
Rear Wheel CylindersFront Wheel Cylinders SFRH
OFF
SFRR
OFFPressure
Sensor
SFLH
OFF
SFLR
OFF
SMC1
ON ONSMC2
11 9
i) Regenerative Brake Cooperative Control

CHASSIS ± BRAKES
SMC2 SMC1
182CH60
AccumulatorReservoir Tank
Pump Motor
Pressure Switches
Relief
Valve
Master Cylinder
Pressure Sensor
Pressure
Sensor
SLRSLA
Stroke Simulator
OFF
SS
ON ON
Reservoir
Pressure
Sensor
Pressure
Sensor
P & B Valve
Rear Wheel Cylinders Front Wheel CylindersSRrH
OFF
SRrR
OFFSFRH
OFF
SFRR
OFFSFLH
OFF
SFLR
OFF
ON ON
120
ii) Without Regenerative Brake Cooperative Control (Hydraulic Brake Only)

CHASSIS ± BRAKES
182CH61
Reservoir Tank
Pump Motor
Pressure Switches
Relief
Valve
Master Cylinder
Pressure
SensorPressure Sensor
SLRSLA
OFF
Stroke Simulator
SS
OFF
Reservoir
Pressure
Sensor
Pressure
Sensor
SRrR
OFF
P & B Valve
Rear Wheel Cylinders Front Wheel CylindersOFF
SMC2 SMC1
SRrH
OFFSFRH
OFF
SFRR
OFFSFLH
OFF
SFLR
OFF
OFF OFF
Accumulator121
3) Fail-Safe Control
If a malfunction occurs in the brake ECU, in the input signals from the sensors, or in the actuator system,
this function prohibits the current from flowing to the brake actuator.
As a result, the solenoids in the brake actuator turn off, enabling the braking force of the hydraulic brake
to take effect. The relief function is provided in order to ensure the proper wheel cylinder hydraulic pres-
sure even if the linear solenoid valve SLA is OFF (closed). Only if the regenerative brake system cannot
be used, such as in the case of a malfunction in the communication with the HV ECU, this function
switches controls to enable the hydraulic brake to generate the entire brake force.

CHASSIS ± STEERING
182CH62
122
STEERING
DESCRIPTION
A vehicle-speed sensing type EMPS (Electric Motor-assisted Power Steering) has been adopted. The
EMPS uses the EMPS ECU to control a DC motor that is mounted on the steering gear in accordance with
the signals received from various sensors to provide power assist to the steering effort.
A rack and pinion type steering gear and a stepless tilt steering have been adopted.
The steering column has adopted an energy absorbing mechanism that uses energy absorbing plate.

Specifications 
Gear Ratio (Overall)16.4
18.3
No. of Turns Lock to Lock3.99
Rack Stroke mm (in.)149.6 (5.89)

CHASSIS ± STEERING
182CH68
Rear Wheel
Speed SensorsBrake ECU
Torque Sensor Signal 1
Torque Sensor Signal 2
EMPS
ECUMeter ECU
Gateway ECUDLC3
Display ECU
Multi-information
Display
123
EMPS (Electric Motor-assisted Power Steering)
1. General
In accordance with sensor information such as that provided by the rear wheel speed sensors, the torque sen-
sor that is mounted on the steering gear, and the EMPS ECU determines the direction and the force of the
power assist and actuates the DC motor that is mounted on the steering gear to provide power assist to the
steering effort.
The EMPS in the Prius the following features:
This system can provide power assist even when the engine is stopped.
This system offers excellent fuel economy characteristics because power assist is provided by the DC mo-
tor that is mounted on the steering gear, and this motor consumes energy only when power assist is re-
quired.
Unlike the conventional hydraulic power steering system, this system excels in serviceability because it
does not require pipes or the power steering fluid.

System Diagram 

CHASSIS ± STEERING
182CH69
Meter ECU
EMPS ECU
Relay
DC MotorRear Wheel Speed
Sensors and Rotors
Brake ECU Multi-information Display 124
2. Layout of Main Components
3. Function of Main Components
ComponentsFunction
St i
Torque Sensor
Detects the twist of the torsion bar, converts the torque that is applied
to the torsion bar into an electrical signal, and outputs this signal to
the ECU.
Steering
Gear
DC MotorGenerates power assist in accordance with a signal received from the
EMPS ECU.
Reduction
MechanismReduces the rotation of the DC motor and transmits it to the pinion
shaft.
EMPS ECU
Actuates the DC motor mounted on the steering gear for providing
power assist, based on the signals received from various sensors and
the rear wheel speed signal.
Meter ECUOutputs a signal for displaying the PS warning on the center display
in case of a malfunction in the system.
Brake ECURear wheel speed signals are outputted to EMPS ECU.
RelaySupplies power to the DC motor for power assist.
Multi-information DisplayDisplays the PS warning in case of a malfunction in the system.

CHASSIS ± STEERING
182CH70
182CH71
182CH72
Torque
Sensor
Rack and
PinionDC Motor
Reduction Mechanism
Motor
Shaft
Stator
Rotor
Pinion Gear
Motor Shaft
DC Motor
Ring Gear
Pinion Shaft125
4. Construction and Operation of Main Components
Steering Gear
1) General
The steering gear consists of the rack and pin-
ion, DC motor, reduction mechanism, and
torque sensor. The front suspension compo-
nents have been optimized to reduce the load
on the DC motor. Also, the components have
been optimally allocated to ensure ample rack
travel and wheel turning angle, resulting in
excellent cornering performance.
2) DC Motor
The DC motor is mounted on the gear hous-
ing. The DC motor consists of the motor shaft
that is integrated with the hypoid pinion to
transmit the torque that has been generated by
the drive force of DC motor to the pinion
shaft, the rotor and stator.
3) Reduction Mechanism
A reduction mechanism that transmits the
rotation of the motor to the pinion shaft has
been mounted on the steering gear. The reduc-
tion mechanism consists of the ring gear that
is secured to the pinion shaft and the pinion
gear that is integrated with the motor shaft.
The power assist of the motor is transmitted
by the reduction mechanism to the pinion
shaft, which provides power assist to the
steering effort.

CHASSIS ± STEERING
182CH73
Contact 1 Resistor 1
Upward
Resistor 2
DownwardContact 2
Contacts Torque
Sensor
Resistor
182CH74
Resistor
Basic
Position
Contact
Straightline 126
4) Torque Sensor
A torque sensor that detects the torque that is input by the steering wheel has been mounted on the pinion
shaft. The torque sensor has been integrated with the pinion shaft, and the pinion shaft's input and output
shafts are linked via the torsion bar. Resistors for the torque sensor are mounted on the input shaft of the
pinion shaft, and contacts for the torque sensor are mounted on the output shaft of the pinion shaft. Oper-
ating the steering wheel causes the torsion bar to twist, creating a displacement between the pinnion
shaft's input and output. Two systems of torque sensors detect this displacement in the form of voltage
changes, which are then output to the EMPS ECU.
i) Straightline Driving
If the vehicle is driven straight and the driv-
er does not turn the steering, torque is not
generated in the pinion shaft's input shaft.
Thus, the torsion bar does not twist, and no
changes in resistance occur in the torque
sensor.