O.k some of you guys wanted to know what was new or revised on the Ecotec since it first appeared on the Js in mid-2002 model year. I post this because maybe some will like to retrofit the new items, would like to update it,or just have more knowledge on what is the latest.
For the record, the Ecotec that we all know started life in the Saturn L-series in 2000 model year.
Enjoy!


2005 Improvements

-Improved Block Structure
-Improved main and rod bearing material and shape
-Added polymer coating to piston and changed piston profile for noise reduction
-Added boss on oil pan for powertrain stiffening
-Acoustic cover for (Chevrolet Cobalt)
-Electronic throttle (Saturn ION and Chevrolet Cobalt)
-New fuel rail supplier (Chevrolet Cobalt.)
-Modified timing chain tensioner for noise improvement.
-New evap valve and tube.
-E16A controller (Chevrolet Cobalt and Saturn ION)

The Ecotec 2.2-liter (L61) gets one new application for model year 2005, starting with the all-new, Chevrolet Cobalt . The Cobalt Ecotec 2.2 is essentially the same as the variant used in the Saturn VUE sport utility vehicle, and it features electronic throttle control (ETC) and an electric power steering pump. As in the VUE and Saturn ION, the Cobalt Ecotec 2.2 also has a low-evaporation ``returnless’’ fuel injection system.

The Cobalt Ecotec 2.2-also features an electrically operated power steering pump, rather than a hydraulic pump driven by a camshaft gear. A cam-driven pump is the most efficient hydraulic system available, but the electric pump goes one better. Because the pump is operated by electricity from the vehicle’s charging system, there is no parasitic power loss running the power steering system. Fuel economy and performance are improved.

The Ecotec 2.2 will be the base engine in the 2005 Cobalt; GM Powertrain’s new Ecotec 2.4L I-4 and Ecotec 2.0L Supercharged I-4 engines will be offered as options. The Ecotec 2.2 will be the only engine offered in the Chevrolet Cavalier and Pontiac Sunfire, which continue in 2005. They have mechanical throttle control, hydraulic power steering and fuel injection with return lines.

MORE EFFICIENT CATALYTIC CONVERTERS IN UNDER-FLOOR APPLICATIONS
The Ecotec 2.2s in the Chevrolet Cobalt and Saturn ION have a new catalytic converter. The converter’s size and volume do not change. The difference lies in the mix of precious metals used in the catalyst’s “brick.’’

A combination of metals such as platinum, palladium and rhodium in the converter’s catalytic substrate create the chemical reaction the turns exhaust emissions into oxygen and water vapor. For 2005, the Ecotec 2.2s in the Cobalt and ION, the combination has been reformulated for improved catalytic converter performance

2004 Improvements

-Standard engine in the 2004 Chevrolet Malibu and Malibu Classic
-Unitized exhaust manifold/catalytic converter (Malibu)
-Higher compression and output (Saturn L-Series)
-Air-injection reaction (AIR) eliminated in all applications
-Fuel-pulse dampener for returnless fuel injection
-More efficient catalytic converters in under-floor applications.


FULL DESCRIPTIONS OF NEW OR CHANGED FEATURES

STANDARD ENGINE IN 2004 CHEVROLET MALIBU AND MALIBU CLASSIC
The Ecotec 2.2-liter (L61) gets two new applications for model year 2004, starting with the all-new, Epsilon-platform Chevrolet Malibu. The Malibu Ecotec 2.2 is essentially the same as the variant used in the Saturn VUE sport utility vehicle, and it features electronic throttle control (ETC) and an electric power steering pump. As in the VUE and Saturn ION, the Malibu Ecotec 2.2 also has a low-evaporation ``returnless’’ fuel injection system.

ETC is increasingly common on premium V-8 engines, but still rare on four-cylinders. There is no mechanical link between the accelerator pedal and the throttle. A potentiometer at the gas pedal measures pedal angle and sends a signal to the Throttle Actuation Controller (TAC) and the Powertrain Control Module (PCM), which then direct an electric motor to open the throttle at the appropriate rate. ETC delivers a number of benefits to the customer. It uses several data sources, including the transmission's shift patterns and traction at the drive wheels, in determining how far to open the throttle. ETC delivers outstanding throttle response and greater reliability than a mechanical connection, which typically uses a cable that wears and requires adjustment. Cruise control electronics are integrated in the throttle, further improving reliability and simplifying engine assembly.

The Malibu Ecotec 2.2-also features an electrically operated power steering pump, rather than a hydraulic pump driven by a camshaft gear. A cam-driven pump is the most efficient hydraulic system available, but the electric pump goes one better. Because the pump is operated by electricity from the vehicle’s charging system, there is no parasitic power loss running the power steering system. Fuel economy and performance are improved.

The Malibu Ecotec 2.2 is also distinguished from many North American applications by its returnless fuel-injection system. The sequential fuel injection in all L61s is essentially the same up to the Multec II fuel injectors, but most have a return line that manages fuel pressure by bleeding off excess fuel and returning it to the gas tank. The Malibu Ecotec 2.2 has no return line. It uses a mechanical pressure regulator to manage fuel pressure. The returnless system greatly reduces potential fuel evaporation because it transports the minimum amount of fuel required and limits churning in the gas tank. As a result, the Malibu Ecotec 2.2 surpasses all government evaporative emissions standards.

The Ecotec 2.2 will be the base engine in the 2004 Malibu; GM Powertrain’s new High-Value3.5-liter (LX9) V6 will be offered as an option. The Ecotec 2.2 will be the only engine offered in the Malibu Classic, which continues in 2004 as one of North America’s best-selling fleet automobiles. The Malibu Classic engine is identical to variants used in the Chevrolet Cavalier, Oldsmobile Alero and Pontiac Grand Am and Sunfire. It has mechanical throttle control, hydraulic power steering and fuel injection with return lines.

FUEL-PULSE DAMPENER FOR RETURNLESS FUEL INJECTION
Ecotec 2.2s with returnless fuel injection (those in the Chevrolet Malibu, Saturn ION and Saturn VUE) now have a fuel-pulse dampener installed in the fuel-line between the gas tank and the engine. The dampener is essentially a diaphragm that softens pulses or waves in the fuel line as fuel travels from the tank to the injectors. The dampener virtually eliminates a slight pulsing sound previously generated in the fuel lines and improves overall noise, vibration and harshness control.

MORE EFFICIENT CATALYTIC CONVERTERS IN UNDER-FLOOR APPLICATIONS
Ecotec 2.2s in the Chevrolet Cavalier and Malibu Classic, the Oldsmobile Alero, and the Pontiac Grand Am and Sunfire have a new catalytic converter. The converter’s size and volume do not change. The difference lies in the mix of precious metals used in the catalyst’s “brick.’’

A combination of metals such as platinum, palladium and rhodium in the converter’s catalytic substrate create the chemical reaction the turns exhaust emissions into oxygen and water vapor. For 2004 Ecotec 2.2s with under-floor converters, the combination has been reformulated using more of the more common varieties of these metals and less of the rarest types. The metal reformulation means equal or improved catalytic converter performance with a reduction in the overall quantity of precious metals and a significant reduction in cost.


2003 Improvements

-New Fuel rail
-Reinforced block

Ecotec 2.2 capable of operating on compressed natural gas (RPO L42). Available in the Chevrolet Cavalier, this bi-fuel engine runs on either gasoline or CNG and switches seamlessly for one fuel to the other. CNG is the L42’s primary fuel, and it uses CNG as long as there is sufficient pressure in the storage tank. If pressure drops below a prescribed level, the L42 automatically switches to gasoline operation without driver intervention.



2002 Improvement done over the Saturn's L-series' Ecotec

-Cylinder head casting revisions
-Common oil pan for all applications
-Purge valve relocated for Saturn L-Series
-Engine block bosses
-Revised thermostat housing
-Starter
-New common powertrain control module (PCM)
-Heated rear oxygen (02) sensor
-Engine block heater
-Higher compression 9.5:1 to 10.0:1





>>>For Sale? Clicky!<<<
-----The orginal Mr.Goodwrench on the JBO since 11/99-----

neato, good info there goodwrench

thanks

usefull info for the fact files

Do you have any idea what would be involed in converting a 2003 to an electronic throddle?





My 2k3 cavalier | Nebraska Region SCCA

why would you want to do that every car I have been in that is throttle by wire (electronic) sux performance wise --

useless! convert to electrick power sterring



___________________________________________________________
-=Motegi mr7 chrome 17'' for sale 1000$(canadian) +shipping e-mail me=-

I really don't see any advantages in the Electronic Throttle, well maybe one less cable...
Personally I don't like the electronics controling the throttle.





>>>For Sale? Clicky!<<<
-----The orginal Mr.Goodwrench on the JBO since 11/99-----

wow. not that i would actually run on CNG, but how would you get a tank and hook it up to the fuel system to run cng?
on the 05 changes...
"-Improved Block Structure
-Improved main and rod bearing material and shape
-Added polymer coating to piston and changed piston profile for noise reduction"
what benefits do these give?

eletrinic controled throttle has its ups and down, a down side (on VW's fy by wire) is the throttle has to be adapted everytime you clear codes or los battry power. Some of it is so they can control abuse, on Vw's fly by wire will not let you "brake torque" the car, but at the same time it smore effiecient for accaleration, for expample sometime you give it to much gas at to low of an RPM and the car can bog a bit, this eliminates that, it sees hey he/she is flooring it they want to go right now, and the car opens the throttle for most accelration. ANother thing it can do is if it sees major problems going on with he car the throttle will go into limp mode, where you can barely go above idle in hopes of not havng you push it and destroy the engine. Basically its an attempt to make the car alittle more idiot proof and more efficient.

True^^
But in the case of the Mercedes-Benz it gives you one of the laziest throttle ever. The only throttle in the M-B line up that works like the driver asks is on the S/SL/CL-600&65.
Still it does not convince me.

JB wrote:wow. not that i would actually run on CNG, but how would you get a tank and hook it up to the fuel system to run cng?
on the 05 changes...
"-Improved Block Structure
-Improved main and rod bearing material and shape
-Added polymer coating to piston and changed piston profile for noise reduction"
what benefits do these give?

It takes lots of work for the CNG.
"Improved Block Structure" "Improved main and rod bearing material and shape" is mostly structural enhancement to make it more sturdier.
"Polymer coating" like as stated, to reduce noise mostly.



>>>For Sale? Clicky!<<<
-----The orginal Mr.Goodwrench on the JBO since 11/99-----

how do you improve the main and rod bearing shape?


2004 Cavalier, 2.2L Ecotec
1965 El Camino, 396 BBC, 14:1, 800 BHP

Bringing back from the dead.
I have seen so many people here that want to know what have Ecos have changed through out its time.



>>>For Sale? Clicky!<<<
-----The orginal Mr.Goodwrench on the JBO since 11/99-----

would you be able to just bolt on the electronic power stering in the same spot as the mechanical?

hmmmmmm......



05's engine in the 04........lol



^^Home made sig^^ ghetto, I know. http://members.cardomain.com/blackoutfire

i feel sad i have an 02 now



1989 Turbo Trans Am #82, 2007 Cobalt SS G85

lol it doesnt matter, you'll be boosted soon enough.


<img src="http://memimage.cardomain.net/member_images/3/web/831000-831999/831395_11_full.jpg">

damn sucks to be an 03 i guess

I guess I need to see what car my 04 came out of now.

Update for you guys that have Ecotecs, maybe you can find interchangeable parts and may want to improve on it.
This will carry from the 2006 Ecotecs and on.

2006 improvements
ECOTEC 2.2L L4 (L61) CAR AND TRUCK ENGINE
2006 model year summary

• New application: Chevrolet HHR
• Acoustic cover for Chevrolet Cobalt and Saturn ION
• Larger intake plenum for HHR
• Block modifications for increased strength
• New emissions standards
• Teflon front and rear crankshaft seals
• Two mounting bosses added to oil pan for increased rigidity

Full descriptions of new or changed features

New application: Chevrolet HHR
The HHR Ecotec 2.2-liter (L61) is essentially the same variant used in the Saturn VUE sport utility vehicle. The HHR application uses electronic throttle control (ETC) and an electric power steering pump. Because the steering pump is powered by an electric motor, there is no parasitic loss on the engine when demand is high for steering assist. Both fuel economy and performance improve as a result.

Acoustic cover for Chevrolet Cobalt and Saturn Ion
A cover is added to block noise from the engine.

Larger intake plenum for HHR
Because of the additional space under the hood of the HHR body, the intake plenum was made larger, and interior volume is increased. The larger plenum volume reduces intake noise.

Block modifications for increased strength
The main bearing cap attachment points are enlarged to increase their strength, and the water jacket passages are extended inside the engine block to increase cooling ability.

New emissions standards
The BIN5/SULEV and LEV2 Enhanced Evaporation standards are applied to the Saturn Ion and Chevrolet Cobalt applications, and secondary air injection system is also used for SULEV applications. -
The mix of precious metals in the catalytic converters is optimized for SULEV applications as well. As in the VUE and Cobalt, the HHR Ecotec 2.2 also has a low-evaporation returnless fuel injection system.

Teflon front and rear crankshaft seals
The crankshaft seals are changed to Teflon to increase durability and extend the life of the seals during operating temperature extremes.

Two mounting bosses added to oil pan to increase rigidity
The oil pan is common between the 2.2-liter L61 and the new 2.4-liter LE5, and for 2006 two mounting bosses are added to the oil pan. This allows the oil pan to be rigidly connected to the lower part of the crankcase (also called the bedplate) which increases the torsional rigidity of the engine/transmission unit.


2007 improvements
2007 Ecotec 2.2L I4 ( L61 )
ECOTEC 2.2L I4 (L61) CAR AND TRUCK ENGINE


• Gen II Engine Block
• Cylinder Head Improvements
• New Camshaft Design
• E37 Engine Control Module
• 58X Crankshaft Reluctor Ring
• Digital Crank and Cam Sensors
• Individual Coil-on-Plug Ignition
• Vented Starter Solenoid
• New MAP Sensor
• New Intake Manifold Seals
• New Oil Filter Element
• Improved Emissions Performance



Full Description of New and Updated Features

Gen II Engine Block
The Ecotec 2.2L starts with a refined engine block, introduced for 2006 with the Ecotec 2.4L VVT (RPO LE5). The Gen II block was developed with data acquired in racing programs and the latest math-based tools. Both the bore walls and bulkheads, or the structural elements that support the crank bearings, have been strengthened, with only a minimal weight increase (approximately 2.5 pounds). The coolant jackets have been expanded, allowing more precise bore roundness and improving the block’s ability to dissipate heat. Coolant capacity increases approximately .5 liter.

The cylinder block is the engine’s foundation, and crucial to its durability, output and smooth operation. For GM, the common Gen II Ecotec block increases assembly efficiency. For the customer, the result is more efficient cooling, more strength to accommodate additional power, as in the new Ecotec 2.0L direct-injection Turbo (RPO LNF) and better noise, vibration and harshness control.

Cylinder Head Improvements
The Ecotec 2.2L also benefits from cylinder head refinements introduced on the 2.4L VVT. The exhaust ports have been enlarged slightly with machining improvements to expel exhaust gas more efficiently. Both engines share a common nodular cast iron exhaust manifold, chosen for its durability and sound-deadening properties. The improvements to the cylinder head increase Ecotec 2.2L horsepower slightly in most applications (see specs).

New Camshaft Design
The exhaust cam has been re-profiled to take advantage of refinements in the cylinder head. Maximum exhaust valve lift does not change, but duration increases slightly. The cams also feature a new 4X timing reluctor, replacing timing sensors previously contained in the ignition-coil cassette (see Individual Coil-On-Plug ignition, below). The powder metal reluctor wheel is pressed onto the camshaft at the rear. The 4X reluctor improves ignition timing accuracy and maintains precise consistency over the life of the engine.

Individual Coil-On-Plug Ignition
The Ecotec 2.2.L is equipped with individual coil-on-plug ignition, or four separate coils. Each coil sits directly over a spark plug, with no wire in between. Previous Ecotec 2.2Ls had two coils in a single cassette, with each coil shared by two spark plugs. Individual coil-on-plug delivers maximum voltage and the most consistent spark density. The 2.2L’s cast aluminum cam cover has been redesigned to accommodate the four coils.

E37 Engine Control Module
An advanced controller manages the multitude of operations that occur within the Ecotec 2.2L every split second. The E37 is the S-3 Controller within GM’s new family of three engine control modules (ECM) that will direct nearly all the engines in Powertrain’s line-up. The E37 is the high-value variant, yet it’s anything but basic. It features 32-bit processing, compared to the conventional 16-bit processing in previous Ecotec 2.2Ls. It operates at 59 MHz, with 32 megabytes of flash memory, 128 kilobytes of RAM and a high-speed CAN bus, and it synchronizes several dozen functions, from spark timing to cruise control operation to traction control calculations. The E37 works roughly 50 times faster than the first computers used on internal combustion engines in the late 1970s, which managed five or six functions.

The family strategy behind GM’s new ECMs allows engineers to apply standard manufacturing, software and service procedures to all powertrains, and quickly upgrade certain engine technologies and calibration capabilities while leaving others alone. It creates both assembly and procurement efficiencies, as well as volume sourcing. In short, it creates a solid, flexible, efficient foundation, allowing engineers to focus on innovations and get them to market more quickly. The family of controllers means the ECM and corresponding connectors can be packaged and mounted identically in virtually every GM vehicle. Powertrain creates all the software for the three ECMs, which share a common language and hardware interface that’s tailored to each vehicle.

The E37 also applies a new, rate-based monitoring protocol sometimes known as run-at-rate diagnostics. Rate-based diagnostics improve the robustness of the Onboard Diagnostics System (OBD II) and ensure optimal performance of emissions control systems. The new software increases the frequency at which the ECM checks various Ecotec 2.2L systems, and particularly emissions-control systems such as the catalytic converter and oxygen sensors. Rate-based diagnostics more reliably monitor real-world operation of these systems, and allow regulatory agencies to more easily measure and certify emissions compliance.

58X Crankshaft Reluctor Ring
The Ecotec 2.2L has an advanced 58X crankshaft position encoder to ensure that ignition timing is accurate throughout its operating range. The 58X ignition system uses a unique crankshaft ring and sensor to provide the new E37 ECM more immediate information on the crankshaft’s position during rotation. This allows the controller to adjust ignition timing with greater precision, which optimizes performance and economy. Engine starting also is more consistent with reduced crank time. The powder metal 58X reluctor ring is bolted to a crankshaft counterweight.

Digital Crank and Cam Sensors
New digital sensors are common with the Ecotec 2.4L VVT and, with the 4X intake cam and 58X crank reluctors along with the new E37 ECM, they complete the ignition timing loop. This dual-position sensing system ensures extremely accurate timing for the life of the engine.

Vented Starter Solenoid
A new starter solenoid helps ensure starting performance in extreme cold temperatures. The solenoid case now has a micromesh-covered vent and an O-ring between the case and the starter motor. The mesh protects the solenoid from debris particles but prevents moisture buildup in the case. When the Ecotec 2.2L is warm, any moisture on the solenoid evaporates through the vent. The vented solenoid virtually eliminates the possibility of cold-start problems associated with solenoid icing.

New MAP Sensor
An advanced manifold absolute pressure (MAP) sensor completes upgrades to the Ecotec 2.2L’s control system. The MAP sensor is a variable resistor used to monitor the difference between atmospheric and manifold pressure, which tends to increase when the engine is operating under a higher load or at wide-open throttle. The ECM uses information from the MAP sensor to adjust spark timing and fuel delivery to optimize performance and minimize emissions. The new MAP sensor improves fidelity, or accuracy, and takes full advantage of the E37 ECM’s capabilities.

New Intake Manifold Seals
The Ecotec 2.2L is equipped with new intake manifold and throttle body sealing gaskets manufactured from a fluorocarbon material. The new gaskets are more resistant to most chemicals, for maximum durability, and particularly impermeable to hydrocarbon molecules. Gasoline vapor cannot penetrate the new seals, virtually eliminating evaporative emissions.

New Oil Filter Element
The paper element in the Ecotec 2.2L oil filter has been improved. The engine’s innovative filter design uses a replaceable cartridge without the conventional metal filter can, which traps waste oil that can not easily be removed. The cartridge can also be changed from under the hood, without getting under the car, and it virtually eliminates spillage during replacement. The new element filters particles from the oil more effectively without disrupting oil flow.

Improved Emissions Performance
The Ecotec 2,2L now meets BIN5 tailpipe emissions mandates in all applications. To achieve this standard, the mix of precious metals in the catalytic converter has been reformulated. Metals such as platinum, palladium and rhodium in the converter’s catalytic substrate create the chemical reaction that turns the majority of exhaust emissions into harmless gases and water vapor. With the new intake sealing gaskets, the 2.2L also meets PZEV (Partial Zero Emission Vehicle) Enhanced Evaporation standards.


2008 improvements
2008 Ecotec 2.2L I4 ( L61 )
ECOTEC 2.2L I4 (L61) CAR AND TRUCK ENGINE
2008 Model Year Summary

Carryover Key features from 2007 model year product
• Gen II Engine Block
• Cylinder Head Improvements
• Camshaft Design
• E37 Engine Control Module
• 58X Crankshaft Reluctor Ring
• Digital Crank and Cam Sensors
• Individual Coil-on-Plug Ignition
• Vented Starter Solenoid
• MAP Sensor
• Intake Manifold Seals
• Oil Filter Element
• Improved Emissions Performance

Full Description of Carryover Features and Benefits from 2007 model year.

Gen II Engine Block
The Ecotec 2.2L starts with a refined engine block, introduced for 2006 with the Ecotec 2.4L VVT (RPO LE5). The Gen II block was developed with data acquired in racing programs and the latest math-based tools. Both the bore walls and bulkheads, or the structural elements that support the crank bearings, have been strengthened, with only a minimal weight increase (approximately 2.5 pounds). The coolant jackets have been expanded, allowing more precise bore roundness and improving the block’s ability to dissipate heat. Coolant capacity increases approximately .5 liter.

The cylinder block is the engine’s foundation, and crucial to its durability, output and smooth operation. For GM, the common Gen II Ecotec block increases assembly efficiency. For the customer, the result is more efficient cooling, more strength to accommodate additional power, as in the new Ecotec 2.0L direct-injection Turbo (RPO LNF) and better noise, vibration and harshness control.

Cylinder Head Improvements
The Ecotec 2.2L also benefits from cylinder head refinements introduced on the 2.4L VVT. The exhaust ports have been enlarged slightly with machining improvements to expel exhaust gas more efficiently. Both engines share a common nodular cast iron exhaust manifold, chosen for its durability and sound-deadening properties. The improvements to the cylinder head increase Ecotec 2.2L horsepower slightly in most applications (see specs).

Camshaft Design
In 2007, the exhaust cam has been re-profiled to take advantage of refinements in the cylinder head. Maximum exhaust valve lift does not change, but duration increases slightly. The cams also feature a new 4X timing reluctor, replacing timing sensors previously contained in the ignition-coil cassette (see Individual Coil-On-Plug ignition, below). The powder metal reluctor wheel is pressed onto the camshaft at the rear. The 4X reluctor improves ignition timing accuracy and maintains precise consistency over the life of the engine.

Individual Coil-On-Plug Ignition
The Ecotec 2.2.L is equipped with individual coil-on-plug ignition, or four separate coils. Each coil sits directly over a spark plug, with no wire in between. Previous Ecotec 2.2Ls had two coils in a single cassette, with each coil shared by two spark plugs. Individual coil-on-plug delivers maximum voltage and the most consistent spark density. The 2.2L’s cast aluminum cam cover has been redesigned to accommodate the four coils.

E37 Engine Control Module
An advanced controller manages the multitude of operations that occur within the Ecotec 2.2L every split second. The E37 is the S-3 Controller within GM’s new family of three engine control modules (ECM) that will direct nearly all the engines in Powertrain’s line-up. The E37 is the high-value variant, yet it’s anything but basic. It features 32-bit processing, compared to the conventional 16-bit processing in previous Ecotec 2.2Ls. It operates at 59 MHz, with 32 megabytes of flash memory, 128 kilobytes of RAM and a high-speed CAN bus, and it synchronizes several dozen functions, from spark timing to cruise control operation to traction control calculations. The E37 works roughly 50 times faster than the first computers used on internal combustion engines in the late 1970s, which managed five or six functions.

The family strategy behind GM’s new ECMs allows engineers to apply standard manufacturing, software and service procedures to all powertrains, and quickly upgrade certain engine technologies and calibration capabilities while leaving others alone. It creates both assembly and procurement efficiencies, as well as volume sourcing. In short, it creates a solid, flexible, efficient foundation, allowing engineers to focus on innovations and get them to market more quickly. The family of controllers means the ECM and corresponding connectors can be packaged and mounted identically in virtually every GM vehicle. Powertrain creates all the software for the three ECMs, which share a common language and hardware interface that’s tailored to each vehicle.

The E37 also applies a new, rate-based monitoring protocol sometimes known as run-at-rate diagnostics. Rate-based diagnostics improve the robustness of the Onboard Diagnostics System (OBD II) and ensure optimal performance of emissions control systems. The new software increases the frequency at which the ECM checks various Ecotec 2.2L systems, and particularly emissions-control systems such as the catalytic converter and oxygen sensors. Rate-based diagnostics more reliably monitor real-world operation of these systems, and allow regulatory agencies to more easily measure and certify emissions compliance.

58X Crankshaft Reluctor Ring
The Ecotec 2.2L has an advanced 58X crankshaft position encoder to ensure that ignition timing is accurate throughout its operating range. The 58X ignition system uses a unique crankshaft ring and sensor to provide the new E37 ECM more immediate information on the crankshaft’s position during rotation. This allows the controller to adjust ignition timing with greater precision, which optimizes performance and economy. Engine starting also is more consistent with reduced crank time. The powder metal 58X reluctor ring is bolted to a crankshaft counterweight.

Digital Crank and Cam Sensors
New digital sensors are common with the Ecotec 2.4L VVT and, with the 4X intake cam and 58X crank reluctors along with the new E37 ECM, they complete the ignition timing loop. This dual-position sensing system ensures extremely accurate timing for the life of the engine.

Vented Starter Solenoid
In 2007, we introduced a new starter solenoid which helps ensure starting performance in extreme cold temperatures. The solenoid case now has a micromesh-covered vent and an O-ring between the case and the starter motor. The mesh protects the solenoid from debris particles but prevents moisture buildup in the case. When the Ecotec 2.2L is warm, any moisture on the solenoid evaporates through the vent. The vented solenoid virtually eliminates the possibility of cold-start problems associated with solenoid icing.

MAP Sensor
In 2007, an advanced manifold absolute pressure (MAP) sensor completes upgrades to the Ecotec 2.2L’s control system. The MAP sensor is a variable resistor used to monitor the difference between atmospheric and manifold pressure, which tends to increase when the engine is operating under a higher load or at wide-open throttle. The ECM uses information from the MAP sensor to adjust spark timing and fuel delivery to optimize performance and minimize emissions. The MAP sensor improves fidelity, or accuracy, and takes full advantage of the E37 ECM’s capabilities.

Intake Manifold Seals
The Ecotec 2.2L is equipped with intake manifold and throttle body sealing gaskets manufactured from a fluorocarbon material. The gaskets are more resistant to most chemicals, for maximum durability, and particularly impermeable to hydrocarbon molecules. Gasoline vapor cannot penetrate the new seals, virtually eliminating evaporative emissions.

Oil Filter Element
In 2007, the paper element in the Ecotec 2.2L oil filter had been improved. The engine’s innovative filter design uses a replaceable cartridge without the conventional metal filter can, which traps waste oil that can not easily be removed. The cartridge can also be changed from under the hood, without getting under the car, and it virtually eliminates spillage during replacement. The new element filters particles from the oil more effectively without disrupting oil flow.

Improved Emissions Performance
The Ecotec 2,2L meets BIN5 tailpipe emissions mandates in all applications. To achieve this standard, the mix of precious metals in the catalytic converter has been reformulated. Metals such as platinum, palladium and rhodium in the converter’s catalytic substrate create the chemical reaction that turns the majority of exhaust emissions into harmless gases and water vapor. With the new intake sealing gaskets, the 2.2L also meets PZEV (Partial Zero Emission Vehicle) Enhanced Evaporation standards.


2009 improvements
2009 Ecotec 2.2L I-4 VVT ( LAP )
ECOTEC 2.2L I-4 (LAP) CAR ENGINE
2009 Model Year Features and Benefits Summary

• Gen II Engine Block
• New XFE models for Chevrolet Cobalt and Pontiac G5
• Cylinder Head Improvements
• E37 Engine Control Module
• Piston features
• Oil Pump NVH improvement
• Front Cover enhancement
• Intake manifold
• Secondary Air Injection ( S.A.I. ) for SULEV applications
• Variable Valve Timing
• Split Catalytic Converter

Full Description of Features and Benefits for 2009 model year.

New Engine for 2009 Chevrolet Cobalt and Pontiac G5 and Cobalt XFE and G5 XFE
The Ecotec 2.2L I-4 VVT (LAP) powers the Chevrolet Cobalt and Pontiac G5 for 2009 model year. This Ecotec engine is installed transversely, and equipped with either a Hydra-Matic 4T45 (MN5) FWD automatic or a Getrag F23/5 (M86) manual transmission. Horsepower improvements of up to seven horsepower gain will be realized in these applications and consistent with all new GM Powertrain engine rpo’s, the (LAP) will be SAE Certified for 2009 model year. Additionally, the XFE models are now available which incorporate mechanical, aerodynamic, and mass reducing enhancements to deliver improved fuel economy.

Gen II Engine Block
The Ecotec 2.2L starts with a refined engine block, introduced for 2006 with the Ecotec 2.4L VVT (RPO LE5). The Gen II block was developed with data acquired in racing programs and the latest math-based tools. Both the bore walls and bulkheads, or the structural elements that support the crank bearings, have been strengthened, with only a minimal weight increase (approximately 2.5 pounds). The coolant jackets have been expanded, allowing more precise bore roundness and improving the block’s ability to dissipate heat. Coolant capacity increases approximately .5 liter.

The cylinder block is the engine’s foundation, and crucial to its durability, output and smooth operation. For GM, the common Gen II Ecotec block increases assembly efficiency. For the customer, the result is more efficient cooling, more strength to accommodate additional power, and better noise, vibration and harshness control.

Cylinder Head Improvements
The Ecotec 2.2L VVT I-4 also benefits from cylinder head refinements introduced on the 2.4L VVT. The exhaust ports have been enlarged slightly to expel exhaust gas more efficiently. The improvements to the cylinder head increase Ecotec 2.2L horsepower slightly in most applications (see specs). A semi –permanent mold (SPM), casting process with improved material properties was selected for these new heads. Upgraded valve seats on both the intake and exhaust ports improve durability and allow the flex fuel version of the LAP (RPO LE8) to run on E85 fuel. Both engines share a common High Silicon Molybdenum cast nodular iron exhaust manifold, chosen for its durability and sound-deadening properties.

E37 Engine Control Module
An advanced controller manages the multitude of operations that occur within the Ecotec 2.2L every split second. The E37 is the S-3 Controller within GM’s new family of three engine control modules (ECM) that will direct nearly all the engines in Powertrain’s line-up. The E37 is the high-value variant, yet it’s anything but basic. It features 32-bit processing, compared to the conventional 16-bit processing in previous Ecotec 2.2Ls. It operates at 59 MHz, with 32 megabytes of flash memory, 128 kilobytes of RAM and a high-speed CAN bus, and it synchronizes several dozen functions, from spark timing to cruise control operation to traction control calculations. The E37 works roughly 50 times faster than the first computers used on internal combustion engines in the late 1970s, which managed five or six functions.

The family strategy behind GM’s new ECMs allows engineers to apply standard manufacturing, software and service procedures to all powertrains, and quickly upgrade certain engine technologies and calibration capabilities while leaving others alone. It creates both assembly and procurement efficiencies, as well as volume sourcing. In short, it creates a solid, flexible, efficient foundation, allowing engineers to focus on innovations and get them to market more quickly. The family of controllers means the ECM and corresponding connectors can be packaged and mounted identically in virtually every GM vehicle. Powertrain creates all the software for the three ECMs, which share a common language and hardware interface that’s tailored to each vehicle.

The E37 also applies a new, rate-based monitoring protocol sometimes known as run-at-rate diagnostics. Rate-based diagnostics improve the robustness of the Onboard Diagnostics System (OBD II) and ensure optimal performance of emissions control systems. The new software increases the frequency at which the ECM checks various Ecotec 2.2L systems, and particularly emissions-control systems such as the catalytic converter and oxygen sensors. Rate-based diagnostics more reliably monitor real-world operation of these systems, and allow regulatory agencies to more easily measure and certify emissions compliance.

New Piston Features
The 2009 LAP pistons have valve pockets to allow full use of the variable cam phaser and an anodized upper ring groove for improved durability. The oil control ring has lower tension for reduced friction and the upper compression ring is made of a new, more durable material, compatible with E85 fuel.

Front Cover Enhancements
For 2009, all Ecotec engine front covers incorporate a more efficient “Goosehead" port oil pump design, reducing cavitation at higher engine speeds and results in a measurable reduction in noise at the customer's ear, especially in cold-start and drive-away operation. The oil pump also includes a pressure-balanced oil relief valve, further improving the durability and reliability of the lubrication system, as well as a lower friction crank seal.

Intake manifold
The (LAP) intake manifold features a LE5 style welded seam composite manifold which contributes to engine mass reduction and NVH improvements while maintaining the
improved flow characteristics for improved engine performance numbers.

Secondary Air Injection ( S.A.I. ) for SULEV applications
The secondary air injection system for the Ecotec 2.2L I-4 VVT ( LAP ) is common with the LE5 hardware and will contribute to reduced emissions for those designated SULEV applications.

Variable Valve Timing
Variable Valve Timing (VVT) is included in these applications, and allows the powertrain system to take advantage of dual independent continuously variable valve timing for greater efficiency. Dual Independent VVT eliminates the compromise inherent in conventional fixed valve timing and allows a previously unattainable mix of low-rpm torque, even torque delivery over a broad range of engines speeds, and free-breathing high-rev horsepower.

The dual-independent cam phasers adjust intake and exhaust camshaft timing independent from one another for both intake and exhaust valves. A vane-type phaser is installed on the cam sprocket of both the intake and exhaust camshafts to turn these camshafts relative to the sprockets, thereby adjusting the timing of the valve operation. The vane phaser is actuated by hydraulic pressure from engine oil, and managed by a solenoid that controls oil pressure on the phaser. The phaser uses a wheel or rotor with five vanes (like a propeller) to turn the camshaft relative to the cam sprocket, which turns at a fixed rate via chain from the crankshaft. The solenoid directs oil to pressure ports on either side of the five phaser vanes; the vanes, and camshaft, turn as directed by this pressure. The more pressure, the more the phaser and camshaft turn. The engine control module directs the phaser to advance or retard cam timing, depending on driving demands. The dual-independent phasers can turn their respective camshafts over a range of 25 degrees relative to the cam sprocket, or 50 cam degrees from their parked positions.

The benefits are considerable. The cam phasers change valve timing on the fly, maximizing engine performance for given demands and conditions. At idle, for example, the intake cam is retarded and the exhaust cam is advanced which minimizes valve overlap, and allows for exceptionally smooth idling. Under other operating demands, the phasers adjust to deliver optimal valve timing for performance, drivability and fuel economy. At high rpm, the intake phaser might retard intake timing to maximize airflow through the engine and increase horsepower. At low rpm, the intake phaser advances to increase torque. Under a light load (say, casual everyday driving), the phasers are calibrated to select the optimum valve centerlines to maximize fuel economy. Without cam phasing, a cam design and valve timing must be biased toward one strength or another—high-end horsepower or low-end torque, for example—or profiled at some median level that maximizes neither.

The cam phaser is timed to hold the intake valve open a short time longer than a normal engine, allowing a reverse flow into the intake manifold. This reduces the effective compression ratio, allowing the expansion ratio to increase while retaining normal combustion pressures. Efficiency is gained because the high expansion ratio delivers a longer power stroke and reduces the heat wasted in the exhaust. This increase in efficiency comes at the expense of some power from the lower effective compression ratio, but that can be compensated for by the overall higher mechanical compression ratio.

Variable valve timing allows linear delivery of torque, with near-peak levels over a broad rpm range, and high specific output (horsepower per liter of displacement) without sacrificing overall engine response, or drivability. It also provides another effective tool for controlling exhaust emissions because it manages valve overlap at optimum levels.

Split Catalytic Converter (Improved Emissions Performance)
The Ecotec 2.2L I-4 VVT (LAP) engine mates up with a split converter architecture system in order to meet emission / diagnostic requirements. Ecotec engines meet BIN5 tailpipe emissions mandates in all applications. Bin 4 emissions levels in E85 equipped packages, and SULEV emissions levels in certain select applications for California. To achieve this standard, the mix of precious metals in the catalytic converter has been reformulated. Metals such as platinum, palladium and rhodium in the converter’s catalytic substrate create the chemical reaction that turns the majority of exhaust emissions into harmless gases and water vapor. The 2.2L also meets PZEV (Partial Zero Emission Vehicle) Enhanced Evaporation standards


2010 improvements
2010 Ecotec 2.2L I-4 VVT ( LAP )
ECOTEC 2.2L I-4 (LAP) CAR ENGINE
2010 Model Year Features and Benefits Summary

• Gen II Engine Block
• XFE model for Chevrolet Cobalt
• Cylinder Head features
• E37 Engine Control Module
• Piston features
• Oil Pump NVH feature
• Front Cover features
• Intake manifold
• Secondary Air Injection ( S.A.I. ) for SULEV applications
• Variable Valve Timing
• Split Catalytic Converter

Full description of features and benefits for 2010 model year.

Ecotec engine for Chevrolet Cobalt and Cobalt XFE
The Ecotec 2.2L I-4 VVT (LAP) powers the Chevrolet Cobalt for 2010 model year. This Ecotec engine is installed transversely, and equipped with either a Hydra-Matic 4T45 (MN5) FWD automatic or a Getrag F23/5 (M86) manual transmission. Horsepower improvements of up to seven horsepower gain will be realized in these applications and consistent with GM engine rpo’s, the (LAP) is SAE Certified for 2010 model year. Additionally, the XFE models are now available which incorporate mechanical, aerodynamic, and mass reducing enhancements to deliver improved fuel economy.

Gen II Engine Block
The Ecotec 2.2L starts with a refined engine block, introduced for 2006 with the Ecotec 2.4L VVT (RPO LE5). The Gen II block was developed with data acquired in racing programs and the latest math-based tools. Both the bore walls and bulkheads, or the structural elements that support the crank bearings, have been strengthened, with only a minimal weight increase (approximately 2.5 pounds). The coolant jackets have been expanded, allowing more precise bore roundness and improving the block’s ability to dissipate heat. Coolant capacity increases approximately .5 liter.

The cylinder block is the engine’s foundation, and crucial to its durability, output and smooth operation. For GM, the common Gen II Ecotec block increases assembly efficiency. For the customer, the result is more efficient cooling, more strength to accommodate additional power, and better noise, vibration and harshness control.

Cylinder head features
The Ecotec 2.2L VVT I-4 also benefits from cylinder head refinements introduced on the 2.4L VVT. The exhaust ports have been enlarged slightly to expel exhaust gas more efficiently. The improvements to the cylinder head increase Ecotec 2.2L horsepower slightly in most applications (see specs). A semi –permanent mold (SPM), casting process with improved material properties was selected for these new heads. Upgraded valve seats on both the intake and exhaust ports improve durability and allow the flex fuel version of the LAP (RPO LE8) to run on E85 fuel. Both engines share a common High Silicon Molybdenum cast nodular iron exhaust manifold, chosen for its durability and sound-deadening properties.

E37 Engine Control Module
An advanced controller manages the multitude of operations that occur within the Ecotec 2.2L every split second. The E37 is the S-3 Controller within GM’s new family of three engine control modules (ECM) that will direct nearly all the engines in GM’s line-up. The E37 is the high-value variant, yet it’s anything but basic. It features 32-bit processing, compared to the conventional 16-bit processing in previous Ecotec 2.2Ls. It operates at 59 MHz, with 32 megabytes of flash memory, 128 kilobytes of RAM and a high-speed CAN bus, and it synchronizes several dozen functions, from spark timing to cruise control operation to traction control calculations. The E37 works roughly 50 times faster than the first computers used on internal combustion engines in the late 1970s, which managed five or six functions.

The family strategy behind GM’s new ECMs allows engineers to apply standard manufacturing, software and service procedures to all powertrains, and quickly upgrade certain engine technologies and calibration capabilities while leaving others alone. It creates both assembly and procurement efficiencies, as well as volume sourcing. In short, it creates a solid, flexible, efficient foundation, allowing engineers to focus on innovations and get them to market more quickly. The family of controllers means the ECM and corresponding connectors can be packaged and mounted identically in virtually every GM vehicle. GM creates all the software for the three ECMs, which share a common language and hardware interface that’s tailored to each vehicle.

The E37 also applies a new, rate-based monitoring protocol sometimes known as run-at-rate diagnostics. Rate-based diagnostics improve the robustness of the Onboard Diagnostics System (OBD II) and ensure optimal performance of emissions control systems. The new software increases the frequency at which the ECM checks various Ecotec 2.2L systems, and particularly emissions-control systems such as the catalytic converter and oxygen sensors. Rate-based diagnostics more reliably monitor real-world operation of these systems, and allow regulatory agencies to more easily measure and certify emissions compliance.

Piston features
The 2010 LAP pistons have valve pockets to allow full use of the variable cam phaser and an anodized upper ring groove for improved durability. The oil control ring has lower tension for reduced friction and the upper compression ring is made of a new, more durable material, compatible with E85 fuel.

Front cover features
For 2010, all Ecotec engine front covers incorporate a more efficient “Goosehead" port oil pump design, reducing cavitation at higher engine speeds and results in a measurable reduction in noise at the customer's ear, especially in cold-start and drive-away operation. The oil pump also includes a pressure-balanced oil relief valve, further improving the durability and reliability of the lubrication system, as well as a lower friction crank seal.

Intake manifold
The (LAP) intake manifold features a LE5 style welded seam composite manifold which contributes to engine mass reduction and NVH improvements while maintaining the
improved flow characteristics for improved engine performance numbers.

Secondary Air Injection ( S.A.I. ) for SULEV applications
The secondary air injection system for the Ecotec 2.2L I-4 VVT ( LAP ) is common with the LE5 hardware and will contribute to reduced emissions for those designated SULEV applications.

Variable Valve Timing ( VVT )
Variable Valve Timing (VVT) is included in these applications, and allows the powertrain system to take advantage of dual independent continuously variable valve timing for greater efficiency. Dual Independent VVT eliminates the compromise inherent in conventional fixed valve timing and allows a previously unattainable mix of low-rpm torque, even torque delivery over a broad range of engines speeds, and free-breathing high-rev horsepower.

The dual-independent cam phasers adjust intake and exhaust camshaft timing independent from one another for both intake and exhaust valves. A vane-type phaser is installed on the cam sprocket of both the intake and exhaust camshafts to turn these camshafts relative to the sprockets, thereby adjusting the timing of the valve operation. The vane phaser is actuated by hydraulic pressure from engine oil, and managed by a solenoid that controls oil pressure on the phaser. The phaser uses a wheel or rotor with five vanes (like a propeller) to turn the camshaft relative to the cam sprocket, which turns at a fixed rate via chain from the crankshaft. The solenoid directs oil to pressure ports on either side of the five phaser vanes; the vanes, and camshaft, turn as directed by this pressure. The more pressure, the more the phaser and camshaft turn. The engine control module directs the phaser to advance or retard cam timing, depending on driving demands. The dual-independent phasers can turn their respective camshafts over a range of 25 degrees relative to the cam sprocket, or 50 cam degrees from their parked positions.

The benefits are considerable. The cam phasers change valve timing on the fly, maximizing engine performance for given demands and conditions. At idle, for example, the intake cam is retarded and the exhaust cam is advanced which minimizes valve overlap, and allows for exceptionally smooth idling. Under other operating demands, the phasers adjust to deliver optimal valve timing for performance, drivability and fuel economy. At high rpm, the intake phaser might retard intake timing to maximize airflow through the engine and increase horsepower. At low rpm, the intake phaser advances to increase torque. Under a light load (say, casual everyday driving), the phasers are calibrated to select the optimum valve centerlines to maximize fuel economy. Without cam phasing, a cam design and valve timing must be biased toward one strength or another—high-end horsepower or low-end torque, for example—or profiled at some median level that maximizes neither.

The cam phaser is timed to hold the intake valve open a short time longer than a normal engine, allowing a reverse flow into the intake manifold. This reduces the effective compression ratio, allowing the expansion ratio to increase while retaining normal combustion pressures. Efficiency is gained because the high expansion ratio delivers a longer power stroke and reduces the heat wasted in the exhaust. This increase in efficiency comes at the expense of some power from the lower effective compression ratio, but that can be compensated for by the overall higher mechanical compression ratio.
Variable valve timing allows linear delivery of torque, with near-peak levels over a broad rpm range, and high specific output (horsepower per liter of displacement) without sacrificing overall engine response, or drivability. It also provides another effective tool for controlling exhaust emissions because it manages valve overlap at optimum levels.

Split Catalytic Converter (Improved Emissions Performance)
The Ecotec 2.2L I-4 VVT (LAP) engine mates up with a split converter architecture system in order to meet emission / diagnostic requirements. Ecotec engines meet BIN5 tailpipe emissions mandates in all applications. Bin 4 emissions levels in E85 equipped packages, and SULEV emissions levels in certain select applications for California. To achieve this standard, the mix of precious metals in the catalytic converter has been reformulated. Metals such as platinum, palladium and rhodium in the converter’s catalytic substrate create the chemical reaction that turns the majority of exhaust emissions into harmless gases and water vapor. The 2.2L also meets PZEV (Partial Zero Emission Vehicle) Enhanced Evaporation standards.






>>>For Sale? Clicky!<<<
-----The orginal Mr.Goodwrench on the JBO since 11/99-----

Good info!


-Aaron
www.TurboTechRacing.com

Performance Parts For Cavalier, Sunfire, Cobalts and More!!!

Mr.Goodwrench-G.T. wrote:

2003 Improvements

-New Fuel rail
-Reinforced block

Ecotec 2.2 capable of operating on compressed natural gas (RPO L42). Available in the Chevrolet Cavalier, this bi-fuel engine runs on either gasoline or CNG and switches seamlessly for one fuel to the other. CNG is the L42’s primary fuel, and it uses CNG as long as there is sufficient pressure in the storage tank. If pressure drops below a prescribed level, the L42 automatically switches to gasoline operation without driver intervention.

I should also add to this... .

Ecotec 2.2 (L61/L42) Car Engine
2003 Model Year Summary

• Application in Saturn ION
• Fuel System for Chevrolet Cavalier and Pontiac Sunfire
• Bi-fuel for Chevrolet Cavalier
• Air Injection Reaction (AIR) deleted from Saturn LS Automatic
• New assembly plant in Spring Hill, Tenn.


FUEL SYSTEM FOR CHEVROLET CAVALIER AND PONTIAC SUNFIRE
The new fuel system of the fuel system on the Ecotec 2.2-liter (L61) is essentially the same in design and function, with Multec II fuel injectors, from the previous version. It continues to manage fuel pressure with a return line that bleeds excess fuel back to the gas tank. The new system does add insulators around each injector that reduce conductive heat transfer from the cylinder head, much like those used on the returnless fuel system in the ION and VUE.

For 2003, the Ecotec 2.2-liter is standard in gasoline-powered Cavaliers and Sunfires. It was optional in these applications for 2002.

APPLICATION IN SATURN ION
The Ecotec 2.2-liter (L61) powers the 2003 Saturn ION sedan and coupe. For this application, it is configured as it is in the Saturn VUE sport-utility vehicle, with one significant difference -- in place of the VUE’s electronic throttle control (ETC), the ION has a mechanically operated throttle. The ION shares the low-profile mechanical throttle body used in the Chevrolet Cavalier and Pontiac Sunfire and Grand Am, which in turn is different from the throttle body used for the Saturn L-Series. Throttle diameter is the same in both cases, but the low-profile version is fitted more closely to the engine for packaging in ION, Cavalier, Sunfire and Grand Am.

Like the VUE variant, the ION's 2.2-liter engine has a higher compression ratio and more aggressive cam profiles than the variant used in the Saturn L-Series. The higher compression (10.0:1 compared to 9.5:1 in the Saturn L-Series) is a function of flat-top pistons. Where the engine in the Saturn L-Series has a slight dish in the piston dome (approximately 2 mm deep), pistons in the ION and VUE variants are flat. The cam lobe profiles in the ION/VUE engines are also different from those in the Saturn L-Series. Maximum valve lift and duration are essentially the same in all of the engines, but the ramp--up rate--the speed at which the valves reach maximum lift--is higher in the ION and VUE version. The net result is more horsepower and torque (see product specifications).

Several other features distinguish the ION and VUE engine from other North American applications. The fuel–delivery system on the other applications has a return line from the fuel injectors that manages fuel pressure by bleeding off excess fuel and returning it to the tank. Fuel delivery in all 2.2-liter engines is essentially the same up to the fuel injector. The 2.2-liter engines in the ION and VUE have no return line. These variants use an electric pressure regulator to manage fuel pressure. Injectors on the returnless system have an insulator the reduces conductive heat transfer from the cylinder head.

The Ecotec 2.2-liter in the ION and VUE has an electric power steering pump, rather than a hydraulic pump driven by a cam gear. Because the pump is operated by electricity from the vehicle’s charging system, there is no parasitic power loss operating the power steering, and fuel economy is improved. The ION and VUE have a plate over the cam cover where the power steering pump would otherwise mount. The ION and VUE variant also has a different flex plate (the mating surface between engine and transmission) to accommodate the VTi variable transmission, which is offered as an option on both. The flex plate has a unique bolt pattern.

The ION and VUE engines also differ from other North American applications in their use of a separate engine control module (ECM) and transmission control module (TCM) rather than an integrated powertrain control module (PCM). While the ECM/TCM concept is the same with the ION and VUE engines, the hardware is actually different with each variant. On the ION, the ECM is chassis-mounted under the hood to the right of the engine, rather than engine-mounted on the intake manifold.

Finally, the VUE and ION 2.2-liter engines have a close-coupled catalytic converter. The converter is mounted closer to the exhaust manifold than it is in other Ecotec 2.2-liter (L61) equipped vehicles. It heats more quickly because of its proximity to the exhaust manifold, and achieves light off--the temperature at which exhaust emissions are most efficiently oxidized--more quickly.

NEW ASSEMBLY PLANT IN SPRING HILL, TENN.
The Ecotec 2.2-liter (L61) is currently built in two assembly plants (Tonawanda, N.Y. and Kaiserlautern, Germany). A third facility in Spring Hill, Tenn., is scheduled to open in 2002.

BI-FUEL FOR CHEVROLET CAVALIER
The new bi-fuel Ecotec 2.2-liter (L42) operates on either gasoline or compressed natural gas (CNG). The bi-fuel 2.2-liter is an option in the Chevrolet Cavalier for Federal Clean Fuel Fleet service. It is expected to be used primarily in fleet service and replaces the CNG variant of the 2.2-liter (LN2) four-cylinder.

Compressed natural gas is the 2.2-liter (L42) engine's primary fuel. It uses CNG as long as there is sufficient pressure in the storage tank. If pressure drops below a prescribed level, the engine automatically switches to gasoline operation. The change occurs without driver intervention and is indicated only by a ``gasoline operation’’ light in the instrument panel. The driver cannot manually override CNG operation.

Hardware differences between the 2.2-liter (L61) and 2.2-liter (L42) are entirely in the cylinder head and fuel delivery system. CNG does not have the lubricating properties of liquid gasoline, and it tends to produce more surface erosion than gasoline as it flows into the combustion chambers. To ensure maximum durability with CNG operation, the engine has unique valve seats and intake valves that are more resistant to erosion. The seats are manufactured from an alloy called Brico 3010, a sintered powder metal with higher chromium, tungsten and copper content than the alloy used for the regular gas version's valve seats. The engine's intake valves are forged from a premium alloy that includes tungsten, vanadium, manganese, and silicone, and has more chromium than conventional iron-alloy valve material. These alloys virtually eliminate the possibility of valve face and seat erosion with CNG operation.

Fuel-delivery systems on the 2.2-liter (L61) and 2.2-liter-CNG (L42) are substantially different. The CNG engine actually has two fuel systems in one, with sequential port injection for CNG running parallel with the multipoint gasoline injection.

The CNG injection has its own stainless steel fuel rail and uses an adaptor plate, molded from the same nylon composite as the intake manifold, installed between the manifold and the cylinder head. The plate is 8 millimeter thick, with a boss and narrow passage molded at each intake port. The CNG injectors mount on the bosses, roughly one inch to the left of the standard Multec II gasoline injectors, and deliver CNG through the passage in the adaptor plate to the port. The natural gas injectors are fired sequentially. The engine adds a second injector driver module (IDM) to manage the injectors. This solid-state device controls the CNG injector pulses electronically.

To manage the second IDM, the engine has a unique powertrain control module (PCM). The PCM uses software developed specifically for bi-fuel operation.

Maximum fuel delivery pressure in both of the fuel systems is the same: about 65 psi, with a normal operating range of 40-45 psi. Nonetheless, the CNG is stored at tremendous pressure up to 3600 psi. The CNG tank is installed in the Cavalier’s trunk, over a high-pressure regulator that reduces gas pressure to 170 PSI and sends the fuel through a line under the car. A second intermediate pressure regulator mounted on the transmission further reduces fuel pressure to about 45 psi for delivery to the injectors. Two electrically operated shut-off valves--one on the tank, the other under the hood--can shut down the CNG fuel system if the on-board diagnostics detect the slightest malfunction. In such circumstances, the PCM switches the 2.2-liter to gasoline operation and advises the driver of the problem with a ``service engine’’ warning light in the dash.

The Cavalier’s CNG tank has a capacity of 6.2 GGE (gasoline gallon equivalent). At full capacity, the tank stores the same amount of energy, measured by BTUs, as 6.2 gallons of gasoline. The bi-fuel engine is expected to extend the Cavalier’s range 150-200 miles over the dedicated gasoline vehicle. CNG operation reduces the engine's maximum horsepower and torque approximately 10 percent (see product specifications).

AIR INJECTION REACTION (AIR) DELETED FROM SATURN LS AUTOMATIC.
The AIR system has been removed from Saturn L-Series sedans equipped with the 2.2-liter (L61) and an automatic transmission. AIR was used to lower exhaust emissions by injecting warm, fresh air into the combustion process to create an exothermic reaction. The reaction creates heat and warms the catalytic converters more quickly, speeding catalyst light off and reducing emissions during cold starts--a critical phase in certification tests. The automatic-equipped L-Series now meets all government emissions standards without AIR. Removing AIR reduces cost and mass.

Saturn L-Series sedans equipped with a manual transmission continue with AIR.






>>>For Sale? Clicky!<<<
-----The orginal Mr.Goodwrench on the JBO since 11/99-----

I forgot about this thread.
And the last updates of the 2.2L Ecotec.

2010 Ecotec 2.2L I-4 VVT ( LE8 )
ECOTEC 2.2L I-4 (LE8) TRUCK ENGINE
2010 Model Year Features and Benefits Summary

•Gen II Engine Block ( E85 Variant for Chevrolet HHR )
•Cylinder Head Improvements
•E37 Engine Control Module
•Piston features
•Oil Pump NVH improvement
•Front Cover enhancement
•Intake manifold
•E85 Flex Fuel
•Variable Valve Timing
•Split Catalytic Converter

Full Description of Features and Benefits for 2010 model year.

E85 Flex Fuel engine for 2010 Chevrolet HHR
The Ecotec 2.2L I-4 VVT (LE8) powers the Chevrolet HHR Panel and Passenger Van for 2010 model year. This Ecotec engine is installed transversely, and equipped with either a Hydra-Matic 4T45 (MN5) FWD automatic or a Getrag F23/5 (M86) manual transmission. Horsepower improvements of up to seven horsepower gain will be realized in these applications and consistent with all new GM engine rpo’s, the (LE8) will be SAE Certified for 2010 model year.

Gen II Engine Block
The Ecotec 2.2L starts with a refined engine block, introduced for 2006 with the Ecotec 2.4L I-4 VVT (RPO LE5). The Gen II block was developed with data acquired in racing programs and the latest math-based tools. Both the bore walls and bulkheads, or the structural elements that support the crank bearings, have been strengthened, with only a minimal weight increase (approximately 2.5 pounds). The coolant jackets have been expanded, allowing more precise bore roundness and improving the block’s ability to dissipate heat. Coolant capacity increases approximately .5 liter.
The cylinder block is the engine’s foundation, and crucial to its durability, output and smooth operation. For GM, the common Gen II Ecotec block increases assembly efficiency. For the customer, the result is more efficient cooling, more strength to accommodate additional power, and better noise, vibration and harshness control.

Cylinder Head Improvements
The Ecotec 2.2L VVT I-4 also benefits from cylinder head refinements introduced on the 2.4L VVT. The exhaust ports have been enlarged slightly to expel exhaust gas more efficiently. The improvements to the cylinder head increase Ecotec 2.2L horsepower slightly in most applications (see specs). A semi –permanent mold (SPM), casting process with improved material properties was selected for these new heads. Upgraded valve seats on both the intake and exhaust ports improve durability and enable the engine to run on E85 fuel. The LE8 has High Silicon Molybdenum cast nodular iron exhaust manifold, chosen for its durability and sound-deadening properties.



E37 Engine Control Module
An advanced controller manages the multitude of operations that occur within the Ecotec 2.2L every split second. The E37 is the S-3 Controller within GM’s new family of three engine control modules (ECM) that will direct nearly all the engines in GM’s line-up. The E37 is the high-value variant, yet it’s anything but basic. It features 32-bit processing, compared to the conventional 16-bit processing in previous Ecotec 2.2Ls. It operates at 59 MHz, with 32 megabytes of flash memory, 128 kilobytes of RAM and a high-speed CAN bus, and it synchronizes several dozen functions, from spark timing to cruise control operation to traction control calculations. The E37 works roughly 50 times faster than the first computers used on internal combustion engines in the late 1970s, which managed five or six functions.

The family strategy behind GM’s new ECMs allows engineers to apply standard manufacturing, software and service procedures to all powertrains, and quickly upgrade certain engine technologies and calibration capabilities while leaving others alone. It creates both assembly and procurement efficiencies, as well as volume sourcing. In short, it creates a solid, flexible, efficient foundation, allowing engineers to focus on innovations and get them to market more quickly. The family of controllers means the ECM and corresponding connectors can be packaged and mounted identically in virtually every GM vehicle. GM creates all the software for the three ECMs, which share a common language and hardware interface that’s tailored to each vehicle.

The E37 also applies a new, rate-based monitoring protocol sometimes known as run-at-rate diagnostics. Rate-based diagnostics improve the robustness of the Onboard Diagnostics System (OBD II) and ensure optimal performance of emissions control systems. The new software increases the frequency at which the ECM checks various Ecotec 2.2L systems, and particularly emissions-control systems such as the catalytic converter and oxygen sensors. Rate-based diagnostics more reliably monitor real-world operation of these systems, and allow regulatory agencies to more easily measure and certify emissions compliance.

New Piston Features
The 2010 LE8 pistons have valve pockets to allow full use of the variable cam phaser and an anodized upper ring groove for improved durability. The oil control ring has lower tension for reduced friction and the upper compression ring is made of a new, more durable material, compatible with E85 fuel.

Front Cover Enhancements
For 2010, all Ecotec engine front covers incorporate a more efficient “Goosehead" port oil pump design, reducing cavitation at higher engine speeds and results in a measurable reduction in noise at the customer's ear, especially in cold-start and drive-away operation. The oil pump also includes a pressure-balanced oil relief valve, further improving the durability and reliability of the lubrication system, as well as a lower friction crank seal.

Intake manifold
The (LE8) intake manifold features a LE5 style welded seam composite manifold which contributes to engine mass reduction and NVH improvements while maintaining the
improved flow characteristics for improved engine performance numbers.


E85 Flexible-Fuel Capability (LE8)
GM has led the industry in introducing flex-fuel capability to its cars and trucks, and the new flex-fuel 2.2L I-4 VVT ( LE8 ) extends availability to an even broader range of customers. E85 is a clean-burning alternative fuel made in the United States from corn and other crops, composed of 85 percent ethanol alcohol and 15 percent gasoline. The 2.2L’s flex-fuel technology is both sophisticated and durable.

Flex fuel engines require special valves and valve seats to withstand the wear and corrosive effects of ethanol. The nitrided Silcrome 1 intake valves and 21-43 exhaust valves used in the 2.2L I-4 are up to the challenge. Compared to conventional iron-alloy valve material, nitrided Silcrome 1 includes tungsten, vanadium, manganese, silicone and higher chromium content. It is harder, and it improves durability, even under the rigors of ethanol operation. The 21-43 exhaust valves work equally well. Valve seat inserts have been upgraded to premium materials with a high percent of tool steel and solid lubricants resulting in excellent durability whether E85 or gasoline is run in the engine.

Hardware changes for flex-fuel operation are limited to the injectors. Because ethanol has fewer BTUs (less energy) than the same volume of gasoline, more fuel is required to produce the same horsepower at wide-open throttle. Flex fuel engines use unique stainless injectors with a greater cone angle and higher maximum fuel-flow rate. The fuel rail matches the injectors, but it’s manufactured of the same stainless steel used for all 2.2L I-4 fuel rails.

The flex-fuel 2.2L doesn’t require a special fuel sensor. The first flex-fuel engines used a light-reactive sensor to measure fuel composition from 100 percent gasoline to 85 percent ethanol. The 2.2L has a virtual sensor—software programmed in the E37 ECM with no separate physical sensor whatsoever. Based on readings from the oxygen (O2) sensors, fuel level sensor and vehicle speed sensors, the ECM adjusts the length of time the fuel injectors open for the type of fuel used. Within a few miles after filling up, the E37 controller determines what fuel is powering the 2.2L I-4 and manages the engine accordingly.

E85 fuel provides an environmentally friendly companion or alternative to gasoline. It is biodegradable and doesn’t contaminate the water supply. Ethanol can be produced from various feed stocks, including corn and wheat stalks, forestry and agricultural waste, and even municipal waste.

Variable Valve Timing
Variable Valve Timing (VVT) is included in these applications, and allows the powertrain system to take advantage of dual independent continuously variable valve timing for greater efficiency. Dual Independent VVT eliminates the compromise inherent in conventional fixed valve timing and allows a previously unattainable mix of low-rpm torque, even torque delivery over a broad range of engines speeds, and free-breathing high-rev horsepower.

The dual-independent cam phasers adjust intake and exhaust camshaft timing independent from one another for both intake and exhaust valves. A vane-type phaser is installed on the cam sprocket of both the intake and exhaust camshafts to turn these camshafts relative to the sprockets, thereby adjusting the timing of the valve operation. The vane phaser is actuated by hydraulic pressure from engine oil, and managed by a solenoid that controls oil pressure on the phaser. The phaser uses a wheel or rotor with five vanes (like a propeller) to turn the camshaft relative to the cam sprocket, which turns at a fixed rate via chain from the crankshaft. The solenoid directs oil to pressure ports on either side of the five phaser vanes; the vanes, and camshaft, turn as directed by this pressure. The more pressure, the more the phaser and camshaft turn. The engine control module directs the phaser to advance or retard cam timing, depending on driving demands. The dual-independent phasers can turn their respective camshafts over a range of 25 degrees relative to the cam sprocket, or 50 cam degrees from their parked positions.

The benefits are considerable. The cam phasers change valve timing on the fly, maximizing engine performance for given demands and conditions. At idle, for example, the intake cam is retarded and the exhaust cam is advanced which minimizes valve overlap, and allows for exceptionally smooth idling. Under other operating demands, the phasers adjust to deliver optimal valve timing for performance, drivability and fuel economy. At high rpm, the intake phaser might retard intake timing to maximize airflow through the engine and increase horsepower. At low rpm, the intake phaser advances to increase torque. Under a light load (say, casual everyday driving), the phasers are calibrated to select the optimum valve centerlines to maximize fuel economy. Without cam phasing, a cam design and valve timing must be biased toward one strength or another—high-end horsepower or low-end torque, for example—or profiled at some median level that maximizes neither.

The cam phaser is timed to hold the intake valve open a short time longer than a normal engine, allowing a reverse flow into the intake manifold. This reduces the effective compression ratio, allowing the expansion ratio to increase while retaining normal combustion pressures. Efficiency is gained because the high expansion ratio delivers a longer power stroke and reduces the heat wasted in the exhaust. This increase in efficiency comes at the expense of some power from the lower effective compression ratio, but that can be compensated for by the overall higher mechanical compression ratio.

Variable valve timing allows linear delivery of torque, with near-peak levels over a broad rpm range, and high specific output (horsepower per liter of displacement) without sacrificing overall engine response, or drivability. It also provides another effective tool for controlling exhaust emissions because it manages valve overlap at optimum levels.


Split Catalytic Converter (Improved Emissions Performance)
The Ecotec 2.2L I-4 VVT (LE8) engine mates up with a split converter architecture system in order to meet emission / diagnostic requirements. Ecotec engines meet BIN5 tailpipe emissions mandates in all applications. Bin 4 emissions levels in E85 equipped packages, To achieve this standard, the mix of precious metals in the catalytic converter has been reformulated. Metals such as platinum, palladium and rhodium in the converter’s catalytic substrate create the chemical reaction that turns the majority of exhaust emissions into harmless gases and water vapor.

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2011 ECOTEC 2.2L I-4 VVT (LE8)
Vehicle Applications
•Chevrolet HHR

Product Highlights
•Precision sand-cast engine block
•Enhanced piston design
•Optimized cylinder head
•DOHC with continuously variable valve timing
•Electronic throttle control
•E85 flex-fuel capability
•Revised oil pump/front cover
•155 horsepower (116 kW) at 6,100 rpm – gas / 161 horsepower (120 kW) at 6,000 rpm – E85
•150 lb.-ft. of torque (203 Nm) at 4,800 rpm – gas / 158 lb.-ft. of torque (214 Nm) at 4,600 rpm – E85

Overview
Introduced in 2000, the Ecotec 2.2L engine has proved to be a versatile, powerful and efficient engine. In 2011, the LE8-code version is standard in the efficient Chevrolet HHR. Like other engines in the Ecotec family, it uses continuously variable valve timing to optimize performance, efficiency and emissions. It is rated at 155 horsepower (116 kW) and 150 lb.-ft. of torque (203 Nm) on gas. With the standard five-speed manual transmission, it delivers an EPA-estimated 32 mpg on the highway. With the optional Hydra-Matic 4T45 four-speed automatic transmission, the EPA-estimated highway fuel economy is 30 mpg.

The Ecotec 2.2L (LE8) is based on the same Ecotec 2.4L family found in other GM vehicles, including the Buick LaCrosse and GMC Terrain. As with them, it offers durability and technology features familiar in premium V-type engines, including low-friction hydraulic roller-finger valve operation and an electronic throttle. A hydraulic tensioner keeps the timing chain adjusted for life, and extended-life spark plugs deliver 100,000 miles (160,000 km) of service. Additional Ecotec family traits include:
• Dual overhead camshafts (DOHC) with four valves per cylinder
• Twin counter-rotating balance shafts to cancel the second-order vibration typical in four-cylinder inline engines
• Full-circle transmission attachment and a structural oil pan that bolts to both the engine block and transmission bell housing.

Engine Block
The Ecotec 2.2L's sand-cast cylinder block is a superior refinement of previous Ecotec engine block castings. It is dimensionally similar with previous variants, while providing excellent structural support, as well as enabling greater control of noise, vibration and harshness.

The main bearing bulkheads, which support the crank bearing, as well as the cylinder bore walls, have been significantly strengthened to support increased engine loads. Also, refinements to the oil distribution system enable improved oil flow throughout the engine; and an expansion of the coolant jacket, along with the use of cast-in-place bore liners, allows more precise bore roundness and improves the block’s ability to dissipate heat.

Enhanced Piston Design
The Ecotec 2.2L’s pistons have valve pockets to accommodate variable valve timing and an anodized upper ring groove for improved durability. The oil control ring has lower tension for reduced friction and the upper compression ring is made of a new, more durable material that is compatible with E85, a fuel comprising 85 percent ethanol and 15 percent gasoline.

The pistons are used with strong connecting rods that are linked to a nodular iron crankshaft. It is a durable and proven rotating assembly.

Optimized Cylinder Head
The Ecotec 2.2L VVT benefits from cylinder head refinements introduced on the Ecotec 2.4L, including slightly enlarged exhaust ports that expel exhaust gas more efficiently. A semi-permanent mold (SPM) casting process is used to create the head and it features upgraded valve seats on both the intake and exhaust ports to improve durability and enable flex-fuel capability. The Ecotec 2.2L also has a High Silicon Molybdenum cast nodular iron exhaust manifold that was selected for its durability and sound-deadening properties.

DOHC with Continuously Variable Valve Timing
Overhead cams are the most direct, efficient means of operating the valves, while four valves per cylinder increase airflow in and out of the engine. This arrangement is integrated on the Ecotec 2.2L’s lightweight aluminum cylinder head.

Continuously variable valve timing optimizes the engine's performance, efficiency and emissions. Both the intake and exhaust cams have hydraulically operated vane-type phasers that are managed by a solenoid and directed by the engine control module (ECM). The phasers turn the camshaft relative to the drive sprocket, allowing intake and exhaust valve timing to be adjusted independently.

Cam phasing changes the timing of valve operation as conditions such as rpm and engine load vary. It allows an outstanding balance of smooth torque delivery over a broad rpm range, high specific output and good specific fuel consumption. Cam phasing also provides another effective tool for controlling exhaust emissions. Because it manages valve overlap at optimum levels, it eliminates the need for a separate exhaust gas recirculation (EGR) system.

The Ecotec 2.2L camshafts feature 4X timing reluctors with digital sensors. This state-of-the-art control system allows the ECM to accurately measure and adjust valve timing, with consistent performance over the engine’s anticipated useful life. The cam reluctors work in conjunction with a 58X crankshaft position encoder to ensure the precisely accurate spark timing required of a direct-injection engine. This dual timing system also provides a reliable back up in the event either a camshaft or crankshaft sensor fails.

Electronic Throttle Control
GM has led the industry in applying electronic throttle control (ETC). With ETC, there is no mechanical link between the accelerator pedal and the throttle body. A sensor at the pedal measures pedal angle and sends a signal to the engine control module (ECM), which in turn directs an electric motor to open the throttle at the appropriate rate and angle. ETC delivers a number of benefits to the customer.

With the ECM measuring throttle pedal angle and monitoring other data including the transmission’s shift status and traction at the drive wheels, the ETC system can deliver outstanding throttle response and greater reliability than a mechanical connection, which typically uses a cable that requires adjustment – and sometimes breaks. Cruise control electronics are integrated into the system, further improving reliability and simplifying engine assembly.

E85 Flex-Fuel Capability
E85 is a cleaner-burning, domestically produced alternative fuel composed of 85 percent ethanol alcohol and 15 percent gasoline. Ethanol is renewable, biodegradable and can be produced from various feed stocks, including corn and wheat stalks, forestry and agricultural waste and even municipal waste.

The Ecotec 2.2L’s flex-fuel technology is both sophisticated and durable. Hardware changes are limited to the injectors with a higher maximum flow rating. Because ethanol has fewer BTUs (less energy) than the same volume of gasoline, more fuel is required to produce the same horsepower at wide-open throttle.

A special fuel sensor is not required for the engine; it uses a “virtual sensor” within the Engine Control Module that takes readings from the oxygen sensors, fuel level sensor and vehicle speed sensors to adjust the length of time the fuel injectors open for the type of fuel used.

Revised Oil Pump/Front Cover
For 2011 all Ecotec engine front covers incorporate a more efficient “goosehead”-port oil pump design, which reduces cavitation at higher engine speeds and results in a measurable reduction in noise, especially in cold-start and drive-away operation. The oil pump also includes a pressure-balanced oil relief valve, further improving the durability and reliability of the lubrication system, as well as a lower friction crank seal.

Oil and Filter Changes
Routine maintenance with the Ecotec 2.2L is limited to oil and filter changes; and with a paper filter replacement cartridge those are made as easy as possible. GM’s industry-leading Oil Life System determines oil-change intervals according to real-world operation rather than a predetermined mileage interval.




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-----The orginal Mr.Goodwrench on the JBO since 11/99-----

Has drive by wire ever got stuck open? My old boss had a drive by wire toyota pickup truck. He stopped at a red light one day and couldn't move again, truck was stuck at an idle.


- Your not-so-local, untrained, uncertified, backyard mechanic. But my @!#$ runs