Air Intake System Description. Pontiac Vibe

For 1990-2009 cars only

Makes 🢒 Pontiac 🢒 2006 🢒 Vibe - AWD 🢒 Engine 🢒 Engine Controls - 1.8L (LNK) 🢒 Air Intake System Description

The air induction system provides air with oxygen, for the combustion process. The air cleaner keeps dirt from entering the engine. Outside air is drawn into the air cleaner lower assembly (4) and passes through the air cleaner element (3). Next, the air enters the air cleaner upper assembly (2) and flows past the mass air flow (MAF) sensor (1). The air then flows through the duct, to the throttle body, and into the intake manifold. Finally, the air travels into the cylinder head and through the intake port, ending in the combustion chamber. The air cleaner upper assembly (2) contains the MAF sensor (1) and the auxiliary intake air control solenoid (6). The upper air cleaner (ACL) housing also contains a carbon filter element. The carbon filter absorbs fuel vapors that may be emitted from the combustion chamber, after the engine is turned off.

The following components are directly or indirectly, a part of the air supply system.

Mass Air Flow (MAF) Sensor


(1)	Mass Air Flow (MAF) Sensor
(2)	Platinum Hot-Wire Element
(3)	Intake Air Temperature (IAT) Sensor Thermistor

The mass air flow (MAF) sensor (1) measures the changes in the intake air volume that result from the changes in the throttle opening and the air density. The airflow measurements are used by the powertrain control module (PCM) in order to determine the engine fueling requirements.

The MAF sensor is a hot-wire design. A platinum hot-wire (2) and a thermistor (3) are located in the intake air bypass passage of the MAF sensor housing. The temperature of the platinum hot-wire is affected by exposure to air flow and by exposure to air temperature. The platinum hot-wire is maintained at a set temperature by controlling the current flow through the wire. The MAF sensor converts the changes in current flow to a voltage signal. The voltage signal from the MAF sensor enables the PCM to detect changes in the air density and changes in the air volume.

The MAF sensor also contains the intake air temperature (IAT) sensor. The IAT sensor cannot be serviced separately from the MAF sensor.

Throttle Body Assembly

The throttle body contains a throttle valve that controls the amount of air entering the engine. The throttle position (TP) sensor and the idle air control (IAC) valve are both attached to the throttle body. The throttle body has an engine coolant passage that provides warming of the throttle body housing and prevents icing.

The throttle body contains vacuum ports that are located above and below the throttle valve. These vacuum ports provide the vacuum signals used by various components.

Idle Air Control (IAC) Valve

The idle air control (IAC) valve is attached to the underside of the throttle body with 4 bolts. The IAC valve enables the powertrain control module (PCM) to easily control the engine idle speed by precisely metering the engines air intake at closed throttle. The IAC valve opens and closes the idle air bypass passage according to signals from the PCM. The IAC valve contains an engine coolant passage that enables the IAC valve to operate more efficiently at cold temperatures. The PCM determines the correct engine idle speed by using input from various sensors and switches in order to assess the engine status and requirements.

Operation


(1)	Throttle Body
(2)	Air
(3)	Coolant
(4)	Idle Air (Bypass) Passage
(5)	IAC Valve
(6)	Coolant Passage
(7)	Magnet
(8)	Rotary Valve
(9)	Throttle Valve

The powertrain control module (PCM) uses the idle air control (IAC) valve in order to control the engine idle speed. The PCM communicates with the IAC valve by varying the ON time of a repeating ON/OFF duty cycle. A magnet inside the IAC valve operates a rotary valve that controls the opening of the idle air bypass passage in the throttle body. The idle air passage allows air to enter the engine without passing over the throttle valve. The strength of the magnet in the IAC valve is related to the current flow in the IAC circuit.

The PCM increases the ON time of the IAC valve command in order to increase the idle air passage opening. A larger idle air passage opening allows more air to enter the intake resulting in an increase in engine speed.

The IAC valve contains an engine coolant passage that enables the IAC valve to operate more efficiently at cold temperatures. The IAC valve enables the PCM to easily control engine idle speed by precisely metering the engine's air intake at closed throttle.

Engine Idle Speed Control

The engine idle speed is controlled by the powertrain control module (PCM) through the idle air control (IAC) valve. There are several reasons for idle speed control:

In order to maintain the engine idle speed at the specified RPM at all times. The engine idle speed can vary due to any of the following reasons:

•	A change in the load applied to engine such as when the rear defogger is operating, the automatic transaxle is shifted to R, D, 2 or L ranges, the A/C is turned ON, the headlights or stop lights are turned ON, etc.

•	A change in the atmospheric pressure.

•	A change in engine condition over time.

In order to improve the starting performance of the engine.
In order to improve the driveability of the engine during warm up.
In order to compensate for the change in the air/fuel mixture ratio when decelerating.

Intake Air Temperature (IAT) Sensor

The intake air temperature (IAT) sensor is an integral part of the mass air flow (MAF) sensor that is mounted in the air cleaner assembly. The IAT sensor measures the temperature of the air entering the intake manifold. The IAT sensor provides temperature information to the circuitry of the MAF sensor and the PCM.

The IAT sensor is a thermistor--a resistor whose resistance changes as a function of temperature. When the temperature is low, the resistance is high. The resistance decreases as the temperature increases. The IAT sensor is a 2-wire circuit with a reference or signal voltage and a ground coming from the PCM.

IAT Sensor Operation

Temperature	Resistance	Voltage
Low	High	High
High	Low	Low

Throttle Position (TP) Sensor

The throttle position (TP) sensor is a potentiometer connected to the throttle shaft on the throttle body. By monitoring the voltage on the signal line, the powertrain control module (PCM) calculates the throttle position. As the throttle valve angle changes when the accelerator pedal is moved, the TP sensor signal also changes. At a closed throttle position, the output of the TP sensor is low. As the throttle valve opens, the output increases so that at wide open throttle, the output voltage should be more than 3.3 volts.

Because the position of the throttle valve controls the air supply to the engine, the PCM can modify the fuel delivery based on the throttle angle. For example, power enrichment occurs when the throttle angle approaches wide-open throttle. The PCM looks primarily for changes in the TP sensor output to control fuel delivery. Acceleration enrichment occurs when the throttle angle increases, similar to the accelerator pump on a carburetor equipped vehicle.

Auxiliary Intake Air Control System


(1)	Vacuum Supply Hose
(2)	Manifold Vacuum to Solenoid
(3)	Manifold Vacuum to Intake Air Door
(4)	Auxiliary Intake Air Control Solenoid
(5)	Upper Air Cleaner Housing
(6)	Vacuum Storage Chamber
(7)	Intake Air Door Motor
(8)	Vacuum Check Valve

The auxiliary intake air control system supplies additional air to the engine during hard acceleration and when operating under high engine loads. The lower air cleaner (ACL) housing has 2 inlet air ducts. The auxiliary inlet air duct is opened or closed by a vacuum operated door. Manifold vacuum is supplied to the door motor (7) by a vacuum solenoid (4). The solenoid is low side controlled by the powertrain control module (PCM). A constant supply of vacuum pressure is assured by the use of a vacuum check valve (8) and a vacuum storage chamber (6). The auxiliary intake air door is open when there is no vacuum applied. The PCM closes the door for most driving conditions. For diagnosis of the auxiliary intake air system refer to Auxiliary Intake Air System Diagnosis .