The system uses an amber ABS indicator lamp in the instrument cluster in order to show system operation and malfunctions.
A bulb check occurs each time the ignition switch is turned to the RUN position. The ANTILOCK and BRAKE lamps should turn on, remain on for about two seconds, then turn off. The ABS indicator lamp also indicates system malfunctions. When the EBCM detects a malfunction in the system, the EBCM turns the ANTILOCK and sometimes the BRAKE lamp on. The lamp may remain on or turn off depending on the malfunction. In order to determine the specific cause of the malfunction, refer to A Diagnostic System Check .
Correct tire size, proper inflation, accurate alignment and even wear are needed for good brake performance. These items are essential for proper ABS performance.
Use of the spare tire supplied with the vehicle will not affect the performance of the system.
If the replacement tires are not the same size as the original tires, you must change the tire size calibration within the EBCM using a Scan Tool . Refer to Tire Size Calibration portion of ABS Description . Failure to change the tire calibration when replacing the original tires with a different size tire can affect the performance of the ABS.
The ABS performs the following two system self-tests:
• | The first self-test is performed when the ignition is turned to RUN. Both the ABS indicator lamp and the BRAKE warning lamp will turn on for 2 seconds, then they will turn off. This test confirms correct operation of the EBCM and the lamps. If one of the lamps remains on, either the ABS or the base brake system will require service. |
• | The second self-test is performed when the vehicle reaches a speed of greater than 4.8 km/h (3 mph). At this time the internal EBCM relay, six solenoid coils and BPMV pump motor are cycled and checked for shorts/opens. The BPMV pump will make a slight sound when this function occurs. |
Refer to Normal Braking Mode in Brake Pressure Module Valve Hydraulic Flow Chart .
During normal braking, pressure is applied through the brake pedal. Fluid travels from the master cylinder, through the combination valve and into the BPMV. Once in the BPMV, the fluid travels through the normally-open isolation valves, through the normally-closed dump valves and out into the brakes.
During normal braking, the pumps are not turned on. The low pressure accumulators and attenuators are empty. Only residual pressure is stored in these accumulators and attenuators.
The EBCM constantly monitors wheel speed sensor inputs for rapid deceleration. If the ABS becomes disabled for any reason, the driver will always have base brakes. The normally-open isolation valves and normally-closed dump valves will remain in these positions in order to allow normal fluid pressure to the wheels.
ABS will not operate without wheel slip. The vehicle must be going at least 13 km/h (8 mph) in order to begin ABS operation.
The ABS will monitor the four-wheel speed sensors and control the hydraulic pressure changes at each wheel until the vehicle has come to a complete stop or until the driver has released the brake pedal. The system operates through the following process:
Refer to Isolation Mode in Brake Pressure Module Valve Hydraulic Flow Chart .
Isolation will occur when the driver applies excessive braking for the given road conditions, causing the wheels to decelerate at a rate which exceeds the vehicle's capability.
If the information from the wheel speed sensors indicate excessive wheel deceleration (imminent lock-up), the first step in the antilock sequence is to isolate the brake pressure being applied by the driver.
The EBCM applies a voltage to the isolation coil in order to close the rear isolation valve. This will prevent any additional brake pressure applied by the driver from reaching the wheel. With the isolation valve closed, further increases in brake pressure from the driver will be prohibited.
Refer to Dump Mode in Brake Pressure Module Valve Hydraulic Flow Chart .
Once the pressure is isolated, it must be reduced in order to get the wheels rolling once again. Reducing pressure is accomplished by dumping a portion of the brake fluid pressure into the rear low pressure accumulator (LPA).
The EBCM energizes the dump valve coil(s) in order to open the rear dump valve, allowing fluid from the wheels to be dumped into the LPA. Very short activation pulses open and close the dump valve passageway in order to control this action. Brake pressure is lowered at the wheel and allows the affected wheel to begin rolling again.
The fluid taken from the wheels forces a spring back. The fluid is stored in the LPA at approximately 1034 kPa (150 psi). A portion of the fluid also primes the pump so it can begin building reapply pressure. The dump valves are opened independently in order to control the deceleration of the wheel.
Refer to Reapply Mode in Brake Pressure Module Valve Hydraulic Flow Chart .
The reapply sequence is initiated in order to obtain optimum braking at each wheel. The rear isolation valve is momentarily pulsed open in order to allow the master cylinder and rear pump pressure to reach the brakes. This controlled pressure rise continues until the wheel is at optimum brake output or until the brake pressure is brought up to the master cylinder output pressure.
If more pressure is required, more fluid is drawn from the master cylinder and applied to the brakes. The driver will feel pedal pulsations or pedal drop. This is normal and expected when in the antilock mode.
As fluid is reapplied, the wheels begin to slow down at the optimum rate. If the wheels approach imminent lock-up again, the module will isolate, dump and reapply. These control cycles (isolation, dump and reapply) occur in millisecond intervals, allowing several cycles to occur each second.
At the end of the antilock stop, when the driver releases the brake pedal, the motor will remain on for a short time in order to help drain any fluid left in the LPA. As the fluid drains back into the system, the spring force in the LPA pushes the piston to the home position. The isolation valve is turned off and fluid returns through the isolation orifice.