The air temperature controls are divided into 5 areas:
• | HVAC Control Components |
• | Heating and A/C Operation |
• | Automatic Operation |
• | Engine Coolant |
• | A/C Cycle |
The HVAC control module is a device that interfaces between the operator and the HVAC system to maintain air temperature and distribution settings. The control module sends switch input data to the instrument panel module (IPM), and receives display data from the IPM through signal and clock circuits. The ignition 3 voltage circuit provides a device on signal. The control module does not retain any HVAC DTCs or settings.
A function of the IPM operation is to process HVAC system inputs and outputs. Also, the IPM acts as the HVAC control module's class 2 interface. The battery positive voltage circuit provides power that the IPM uses for keep alive memory (KAM). If the battery positive voltage circuit loses power, then all HVAC DTCs and settings will be erased from KAM. The ignition 3 voltage circuit provides a device on signal. The IPM supports the following features:
Feature | Availability |
---|---|
Afterblow | Yes |
Purge | Yes |
Personalization | Optional |
Actuator Calibration | Yes |
The actuator is a 5-wire bi-directional electric motor that incorporates a feedback potentiometer. Ignition 3 voltage, low reference, control, 5-volt reference and position signal circuits enable the actuator to operate. The control circuit uses either a 0, 2.5 or 5 volt signal to command the actuator movement. When the actuator is at rest, the control circuit value is 2.5 volts. A 0 or 5 volt control signal commands the actuator movement in opposite directions. When the actuator shaft rotates, the potentiometer's adjustable contact changes the door position signal between 0-5 volts.
The IPM uses a range of 0-255 counts to index the actuator position. The door position signal voltage is converted to a 0-255 count range. When the module sets a commanded, or targeted, value, the control signal is changed to either 0 or 5 volts depending upon the direction that the actuator needs to rotate to reach the commanded value. As the actuator shaft rotates the changing position signal is sent to the module. Once the position signal and the commanded value are the same, the module changes the control signal to 2.5 volts.
The air temperature sensor is a 2 wire negative temperature co-efficient thermistor. The vehicle uses the following air temperature sensors:
• | Ambient |
• | Inside |
• | Duct |
A signal and low reference circuit enables the sensor to operate. As the air temperature surrounding the sensor increases, the sensor resistance decreases. The sensor signal decreases as the resistance decreases. The sensor operates within a temperature range between -40 to +150°C (-40 to +300°F). The sensor signal varies between 0-5 volts. The IPM converts the signal to a range between 0-255 counts.
The IPM uses the sensor signals to determine the air temperature door position. Left and right air temperature sensor inputs in a dual zone HVAC system are used to adjust the corresponding left and right air temperature door. In HVAC systems with upper and lower duct temperature sensors, the IPM uses the following sensor inputs with the indicated mode positions:
Temperature Sensor | Mode Position |
---|---|
Upper | Panel, Bi-level |
Lower | Defrost, Floor, Defog |
If the IPM detects a malfunctioning sensor, then the control module software will use a defaulted air temperature value. The default action ensures that the HVAC system can adjust the inside air temperature near the desired temperature until the condition is corrected.
The scan tool has the ability to update the displayed ambient air temperature. The ambient air temperature value is displayed or updated under the following conditions:
Conditions | Display | ||||
---|---|---|---|---|---|
| Displays real-time temperature | ||||
Engine coolant temperature is more than 10°C (18°F) above the sensor reading. | Displays last stores temperature | ||||
| Temperature is updated every second |
The sunload sensor is a 2 wire photo diode. The vehicle uses left and right sunload sensors. The two sensors are integrated into the sunload sensor assembly. Low reference and signal circuits enable the sensor to operate. As the light shining upon the sensor gets brighter, the sensor conductance increases. The sensor signal decreases as the conductance increases. The sensor operates within an intensity range between completely dark and bright. The sensor signal varies between 0-5 volts. The IPM converts the signal to a range between 0-255 counts.
The sunload sensor provides the IPM a measurement of the amount of light shining on the vehicle. Bright, or high intensity, light causes the vehicles inside temperature to increase. The HVAC system compensates for the increased temperature by diverting additional cool air into the vehicle.
If the IPM detects a malfunctioning sensor, then the control module software will use a defaulted sunload value. The default action ensures that the HVAC system can adjust the inside air temperature near the desired temperature until the condition is fixed.
The A/C refrigerant pressure sensor is a 3 wire piezoelectric pressure transducer. A 5-volt reference, low reference, and signal circuits enable the sensor to operate. The A/C pressure signal can be between 0-5 volts. When the A/C refrigerant pressure is low, the signal value is near 0 volts. When the A/C refrigerant pressure is high, the signal value is near 5 volts.
The A/C refrigerant pressure sensor protects the A/C system from operating when an excessively high or low pressure condition exists. The powertrain control module (PCM) disables the compressor clutch under the following conditions:
• | A/C pressure is more than 2968 kPa (430 psi). |
• | A/C pressure is less than 255 kPa (35 psi). |
The purpose of the heating and A/C system is to provide heated and cooled air to the interior of the vehicle. The A/C system will also remove humidity from the interior and reduce windshield fogging. The vehicle operator can determine the passenger compartment temperature by adjusting the air temperature switch. Regardless of the temperature setting, the following can effect the rate that the HVAC system can achieve the desired temperature:
• | Recirculation actuator setting |
• | Difference between inside and desired temperature |
• | Difference between ambient and desired temperature |
• | Blower motor speed setting |
• | Mode setting |
The IPM makes the following actions when an air temperature setting is selected:
• | Warmest position - The air temperature door diverts maximum air past the heater core. |
• | Coldest position - The air temperature door directs maximum air to bypass the heater core. |
• | Between the warmest and coldest positions - The following sensor inputs are monitored to determine the air temperature door position that diverts the appropriate amount of air past the heater core in order to achieve the desired temperature: |
- | Sunload |
- | Duct temperatures |
- | Ambient temperature |
- | Inside temperature |
The A/C system is engaged when the HVAC control module is in A/C, FRONT DEFROST mode or automatic operation. The A/C system can operate regardless of the temperature setting, as long as the outside ambient temperature is more than 3°C (37°F). If the driver tries to turn OFF the A/C while in FRONT DEFROST mode, the A/C OFF text on the HVAC control module display will flash, indicating that this is not allowed. If the A/C compressor is turned OFF due to low outside ambient temperatures, the compressor will not be activated until temperatures reach 6°C (42°F).
The IPM receives an A/C request from the HVAC control module. In order for the PCM to internally ground the A/C clutch relay control circuit, the dash integration module (DIM) and PCM must communicate with each other over the class 2 serial data circuits.
The PCM monitors:
• | A/C refrigerant line pressure |
• | Engine coolant temperature |
The DIM monitors:
• | A/C refrigerant line pressure |
• | Engine coolant temperature |
• | Battery voltage |
• | A/C request from the IPM |
The DIM will request A/C operation from the PCM if these parameters are within normal operating limits.
Once engaged, the compressor clutch will be disengaged for the following conditions:
• | Throttle position is 100 percent |
• | A/C Pressure is more than 2968 kPa (430 psi) |
• | A/C Pressure is less than 255 kPa (35 psi) |
• | Engine coolant temperature (ECT) is more than 121°C (250°F) |
• | Engine speed is more than 5,000 RPM |
• | Transmission shift |
• | PCM detects excessive torque load |
• | PCM detects insufficient idle quality |
• | PCM detects a hard launch condition |
When the compressor clutch disengages, the compressor clutch diode protects the electrical system from a voltage spike.
The right air temperature switch allows the passenger to offset air discharge temperatures on the right side of the vehicle. To activate the dual zone, the passenger turns the right air temperature switch to the desired offset. The word PASS will be displayed on the HVAC control module under the set temperature to show the temperature offset. The temperature offset is allowed as long as the driver's set temperature is not in the maximum hot or cold settings.
The IPM will position the right air temperature actuator, located on the right side of the HVAC module to a position to divert sufficient air past the heater core to achieve the desired passenger temperature.
In automatic operation, the IPM will maintain the comfort level inside of the vehicle by controlling the A/C compressor clutch, the blower motor, the air temperature actuators, mode actuator and recirculation.
To place the HVAC system in Automatic mode, the following is required:
• | The blower motor switch must be in the AUTO position. |
• | The air temperature switch must be in any other position other than 16°C (60°F) or 32°C (90°F). |
• | The mode switch must be in the Auto position. |
Once the desired temperature is reached, the blower motor, mode, recirculation and temperature actuators will automatically be adjusted to maintain the temperature selected. The IPM performs the following functions to maintain the desired air temperature:
• | Monitor the following sensors: |
- | Inside air temperature sensor |
- | Ambient air temperature sensor |
- | Upper air temperature sensor if cool air is required |
- | Lower air temperature sensor if warm air is required |
- | Sunload sensor |
• | Regulate blower motor speed. |
• | Position the air temperature actuator. |
• | Position the mode actuator. |
• | Position the recirculation actuator. |
• | Request A/C operation. |
The automatic HVAC system will warm and cool the vehicle in the most efficient manner. Selecting either the warmest or coldest temperature will not improve the system performance. If the warmest or coldest temperature setting is selected while the HVAC system is in automatic operation, then the following will occur:
• | Warmest position - The blower motor speed increases to maximum speed, and the air temperature actuator is placed in the warmest position. |
• | Coldest position - |
- | The blower motor speed increases to maximum speed. |
- | Air temperature actuator is placed in the coldest position. |
- | Mode actuator is placed in panel position. |
Recirculation actuator is set to the recirculation position.
Engine coolant is the key element of the heating system. The thermostat controls engine operating coolant temperature. The thermostat also creates a restriction for the cooling system that promotes a positive coolant flow and helps prevent cavitation. Coolant enters the heater core through the inlet heater hose, in a pressurized state.
The heater core is located inside the HVAC module. The heat of the coolant flowing through the heater core is absorbed by the ambient air drawn through the HVAC module. Heated air is distributed to the passenger compartment, through the HVAC module, for passenger comfort.
The amount of heat delivered to the passenger compartment is controlled by opening or closing the HVAC module air temperature door. The coolant exits the heater core through the return heater hose and recirculated back through the engine cooling system.
Refrigerant is the key element in an air conditioning system. R-134a is presently the only EPA approved refrigerant for automotive use. R-134a is a very low temperature gas that can transfer the undesirable heat and moisture from the passenger compartment to the outside air.
The A/C system used on this vehicle is a non-cycling system. Non-cycling A/C systems use a high pressure switch to protect the A/C system from excessive pressure. The high pressure switch will OPEN the electrical signal to the compressor clutch, if the refrigerant pressure becomes excessive. After the high and the low sides of the A/C system pressure equalize, the high pressure switch will CLOSE. This completes the electrical circuit to the compressor clutch. The A/C system is also mechanically protected with the use of a high pressure relief valve. If the high pressure switch were to fail or if the refrigerant system becomes restricted and refrigerant pressure continues to rise, the high pressure relief will pop open and release refrigerant from the system.
The A/C compressor is belt driven and operates when the magnetic clutch is engaged. The compressor builds pressure on the vapor refrigerant. Compressing the refrigerant also adds heat. The refrigerant is discharged from the compressor through the discharge hose, and forced through the condenser and then through the balance of the A/C system.
Compressed refrigerant enters the condenser at a high-temperature, high-pressure vapor state. As the refrigerant flows through the condenser, the heat is transferred to the ambient air passing through the condenser. Cooling causes the refrigerant to condense and change from a vapor to a liquid state.
The condenser is located in front of the radiator for maximum heat transfer. The condenser is made of aluminum tubing and aluminum cooling fins, which allows rapid heat transfer for the refrigerant. The semi-cooled liquid refrigerant exits the condenser and flows through the liquid line to the orifice tube.
The orifice tube is located in the liquid line between the condenser and the evaporator. The orifice tube is the dividing point for the high and the low pressure sides of the A/C system. As the refrigerant passes through the orifice tube, the pressure on the refrigerant is lowered, causing the refrigerant to vaporize at the orifice tube. The orifice tube also measures the amount of liquid refrigerant that can flow into the evaporator.
Refrigerant exiting the orifice tube flows into the evaporator core in a low-pressure, liquid state. Ambient air is drawn through the HVAC module and passes through the evaporator core. Warm and moist air will cause the liquid refrigerant to boil inside the evaporator core. The boiling refrigerant absorbs heat from the ambient air and draws moisture onto the evaporator. The refrigerant exits the evaporator through the suction line and flows back to the compressor in a vapor state, completing the A/C cycle of heat removal. At the compressor, the refrigerant is compressed again and the cycle of heat removal is repeated.
The conditioned air is distributed through the HVAC module for passenger comfort. The heat and moisture removed from the passenger compartment condenses, and discharges from the HVAC module as water.