Tuesday, 15 December 2015

SOHC LK0/L24


The SOHC (LK0/L24) cylinder head had 8 valves and was made of lost foam cast aluminum. The camshaft was located in the center of the cylinder head and driven by a chain off the front crankshaft sprocket. Motion from the camshaft was transmitted to the eight valves by the hydraulic lifters and rocker arms.
The LK0 engine first used TBI (Throttle Body Injection) for fuel delivery and was rated at 85 hp (63 kW) at 5000 RPM and 107 lb·ft (145 N·m) at 2400 RPM from 1991 to 1994.
The L24 engine received MPFI (Multi-Port Fuel Injection) in 1995 which increased power output to 100 hp (75 kW) at 5000 RPM and 115 lb·ft (156 N·m) at 2400 RPM. In 1999, these engines switched from the recessed top pistons of the previous models to all new flat top pistons that were also used in the twin cam models. The cylinder head was also redesigned to keep the compression ratio at 8.8:1 even with the flat top pistons and now featured provisions for an air injection reaction system. This engine was used from 1995 to 2002.
The SOHC engine was available on the base model S-series vehicles (SC1, SL, SL1, SW, SW1)
1992 through 1998 L24 Cylinder heads developed issues with cracks developing in the fifth camshaft journal, located closest to #4 cylinder. The hairline crack would develop between the oil feed port of that journal and the coolant passages in the cylinder head. Symptoms would range from overheating to low coolant, however, most cars affected by this issue exhibited oil migration into the cooling system. The resulting mixture of the two fluids would result in a thick brown "milkshake"-like mixture, visible in the coolant overflow tank.
Saturn released unadvertised policy which would cover this issue, extending the warranty on the cylinder head to 6 years or 100,000 miles (160,000 km).
Repair required the replacement of the cylinder head. and flushing of the coolant system. Badly affected cars would see coolant in the oil, as well as oil in the coolant, and would require the replacement of the complete engine assembly.
Until the cylinder head casting was redesigned some time in 1998, some vehicles would require this repair more than once, and replacement cylinder heads could develop the same crack.
It was estimated that between 2% and 5% of SOHC Saturn S-Series vehicles were affected by this defect. DOHC engines had a different cylinder head, and did not suffer the same issue.

DOHC LL0

The DOHC cylinder head had 16 valves and was made of lost foam cast aluminium. The camshafts were held in the cylinder head with bearing caps and driven by a chain off the front crankshaft sprocket. Motion from the camshafts was transmitted to the 16 valves by direct-acting hydraulic lifters.
LL0 cylinder heads were changed slightly in 1995, when Saturn adopted electronic, linear EGR mechanisms, over the previous vacuum actuated design. The head casting was changed to accommodate different mounting surface of the new valve.
All LL0 engines used MPFI and were rated at 124 hp (92 kW) at 5600 RPM and 122 lb·ft (165 N·m) at 4800 RPM. The DOHC engine was available on the upper-level model S-series vehicles (SC, SC2, SL2, SW2). A revision of the LL0 appeared in 1999 and used a roller camshaft with hydraulic lifters and rocker arms, but power was unchanged. Also for 1999 provisions for a new air injection reaction system was introduced aimed at improving engine emissions.
TOYOTA NEW TECHNOLOGY
INTRODUCTION
VVT-i, or Variable Valve Timing with intelligence, is an automobile variable valve timing technology developed by Toyota. The Toyota VVT-i system replaces the Toyota VVT offered starting in 1991 on the 5-valve per cylinder 4A-GE engine. The VVT system is a 2-stage hydraulically controlled cam phasing system.
TYPE OF ENGINE USED IN TOYOTA CARS

      I.            VVT-i


Cutaway view of Variable ValveTiming with ignition engine

VVT-i, or Variable Valve Timing with intelligence, is an automobile variable valve timing technology developed by Toyota. The Toyota VVT-i system replaces the Toyota VVT offered starting in 1991 on the 5-valve per cylinder 4A-GE engine. The VVT system is a 2-stage hydraulically controlled cam phasing system.
VVT-i, introduced in 1996, varies the timing of the intake valves by adjusting the relationship between the camshaft drive (belt, scissor-gear or chain) and intake camshaft. Engine oil pressure is applied to an actuator to adjust the camshaft position. Adjustments in the overlap time between the exhaust valve closing and intake valve opening result in improved engine efficiency.[1] Variants of the system, including VVTL-i, Dual VVT-i, VVT-iE, and Valvematic, have followed.

II.            VVTL-i


The cutaway of  VVTL-i engine

VVTL-i (Variable Valve Timing and Lift intelligent system) (also sometimes denoted as VVT-iL or Variable Valve Timing and Intelligence with Lift) is an enhanced version of VVT-i that can alter valve lift (and duration) as well as valve timing. In the case of the 16 valve 2ZZ-GE, the engine head resembles a typical DOHC design, featuring separate cams for intake and exhaust and featuring two intake and two exhaust valves (four total) per cylinder. Unlike a conventional design, each camshaft has two lobes per cylinder, one optimized for lower rpm operation and one optimized for high rpm operation, with higher lift and longer duration. Each valve pair is controlled by one rocker arm, which is operated by the camshaft. Each rocker arm has a slipper follower mounted to the rocker arm with a spring, allowing the slipper follower to freely move up and down with the high lobe without affecting the rocker arm. When the engine is operating below 6000-7000 rpm (dependent on year, car, and ECU installed), the lower lobe is operating the rocker arm and thus the valves, and the slipper-follower is freewheeling next to the rocker arm. When the engine is operating above the lift engagement point, the ECU activates an oil pressure switch which pushes a sliding pin under the slipper follower on each rocker arm. The rocker arm is now locked into slipper-follower's movements and thus follows the movement of the high rpm cam lobe, and will operate with the high rpm cam profile until the pin is disengaged by the ECU. The lift system is similar in principle to Honda VTEC operation.
The system was first used in 2000 Toyota Celica with 2ZZ-GE. Toyota has now ceased production of its VVTL-i engines for most markets, because the engine does not meet Euro IV specifications for emissions. As a result, this engine has been discontinued on some Toyota models, including that of the Corolla T-Sport (Europe), Corolla Sportivo (Australia), Celica, Corolla XRS, Toyota Matrix XRS, and the Pontiac Vibe GT, all of which had the 2ZZ-GE engine fitted. The Lotus Elise continues to offer the 2ZZ-GE and the 1ZZ-FE engine, while the Exige offers the engine with a supercharger. The Toyota Yaris uses VVT-i on its gasoline engines.


III.            Dual VVT-i


The cutaway of Dual VVT-i engine

The Dual VVT-i system adjusts timing on both intake and exhaust camshafts. It was first introduced in 1998 on the RS200 Altezza's 3S-GE engine.
Dual VVT-i is also found in Toyota's new generation V6 engine, the 3.5-liter 2GR-FE first appearing on the 2005 Avalon. This engine can now be found on numerous Toyota and Lexus models. By adjusting the valve timing, engine start and stop occurs almost unnoticeably at minimum compression. Fast heating of the catalytic converter to its light-off temperature is possible, thereby reducing hydrocarbon emissions considerably.
Most Toyota engines including the LR engines (V10, used in the Lexus LFA), UR engines (V8), GR engines (V6), AR engines (Large I4), and ZR engines (Small I4) now use this technology.



TOYOTA VVTI  SYSTEM EXPLAINATION

Any mechanic or automotive enthusiast can tell you that an engine is essentially a large air pump. The more an engine can suck in air to mix with fuel, the more it can create power through combustion. Thus, the more efficiently an engine removes exhaust gases from the cylinders, the better it can manage that power. The key to a strong, healthy engine is adequate air from one end to another.

Air flow is affected by many different components in the motor, but the valves in the cylinder head are what directly control the amount of air entering a cylinder, and the volume of exhaust gases leaving it. The intake valves open up just prior to combustion in order to allow air to flow in and mix with fuel, and the exhaust valves open after the ignition of this mixture in order to suck out the resulting gases. The timing of the valves is controlled by a rotating shaft called the camshaft. The camshaft has lobes which push up on the valves in order to open them and drop them back closed again.

How long these valves remain open, and at what point in the combustion cycle, can have a big impact on the drivability and power generated by an engine. For instance, if you want to have a really fast car, like a race car, you'll want the engine to produce a lot of power at high RPMs. You can adjust the camshaft to perform well at higher RPMs. This will result in poor performance at low RPMs, but that's OK with a race car. Conversely, if you want a lot of low-end torque - which is great for towing - you need to adjust the camshaft to perform well at low RPMs. This, of course, will hurt high RPM performance.

Unfortunately, street vehicles are a compromise between reliability, fuel efficiency and power. While race vehicles have engines with camshaft designs that generate large amounts of power while being used only at specific, high revolutions, your daily driver sees a wide range of RPMs that make a broader power band necessary. While it is ok for a race car to have a lumpy idle that barely runs below 1000 rpm, it would do you no good if your street car stalled out at every stoplight. Regular vehicles usually have to make do with a camshaft that provides a good amount of power in the most often used range of engine RPMs, but runs out of steam at high speeds.
The problem with compromise camshafts is that they're not all that efficient. Since everyday vehicles operate at a variety of different RPMs, the engine needs to be just as capable of accelerating from a dead stop as it is of zooming along at highway speeds, and everything in between. The result is that your engine often ends up burning too much fuel while underperforming.

Automakers have addressed this concern with something called "variable valve timing" (VVT). The Toyota Tundra's i-Force 5.7L V8, Toyota's newest VVT-i engine, has the ability to vary the timing of the valves in relation to engine speed. It does this by using engine oil pressure to move the camshaft slightly, so that more aggressive lobe designs are used when the engine is running at a higher rpm. By doing this, the i-Force V8 is able to run a camshaft profile that provides good fuel efficiency in every day driving, but is still able to churn out gobs of power when the pedal is pressed to the floor.


 Conclusion:

There is no overlooking the TOYOTA VVTI hefty price. However, most VVTI owners are extremely satisfied with their purchase. The car’s high-tech features and stunning design make it a dream vehicle. Every driver will get addicted to the VVTIhigh-revving engine.


BMW NEW TECHNOLOGY
INTRODUCTION
     The engine is by far the most important component in BMW. And every BMW enthusiast knows that a well maintained engine is good engine. BMW's famous S63TU engine, the 4.4 liter twin-turbo V8 that BMW has used in nearly all of its big performance cars for years now, is a serious contender. The S63 also has top-mounted twin-scroll turbocharger mounted in the vee of the engine and also features variable valve timing and direct injection.

TYPE OF ENGINE USED:
·        BMW S63TU Twin-Turbo V8



·        BMW M6 Gran Coupe (F06) 4.4l V8 (560 HP) - technical specs

Engine specification
Cylinders
V8
Displacement
4395 cm3
Power
412 KW @ 6000 RPM
560 HP @ 6000RPM
553 BHP @ 6000 RPM
Torque
502 Lb-ft @ 1500–5750 RPM
681 Nm @ 1500–5750 RPM
Fuel system
M Twin Power Turbo technology with cross-bank exhaust manifold, Twin Scroll Twin Turbo technology, High Precision Direct Petrol Injection, VALVETRONIC and Double-VANOS
Fuel
Petrol
CO Emission
232 g/km
Performance specification
Top speed
190 mph OR 306 km/h
Acceleration 0-62 Mph (0-100 Km/h)  
4.2 s
Fuel consumption specification  
City
17 mpg US OR 13.8 L/100Km
Highway
31 mpg US OR 7.6 L/100Km
Combined
24 mpg US OR 9.8 L/100Km

ENGINE OPERATION BMW(VANOS)
Performance, torque, idle characteristics and exhaust emissions reduction are improved by Variable Camshaft Timing. The VANOS system is currently used in all BMW engines.BMW’s Variable Valve Timing system is called VANOS (Variable Nockenwellen Steuerung), and here’s how it works.

The VANOS units are mounted directly on the front of the camshafts and adjusts the timing of the Intake and Exhaust camshafts throughout the entire spread range from retarded to advanced. The ECM controls the operation of the VANOS solenoids which regulates the oil pressure required to move the VANOS units. Engine rpm, load and temperature are used to determine VANOS activation.






The VANOS mechanical operation is dependent on engine oil pressure applied to position the VANOS units. When oil pressure is applied to the units (via ports in the camshafts regulated by the solenoids), the camshaft hubs are rotated in the drive sprockets changing the position which advances/retards the intake/exhaust camshafts timing. The VANOS system is “fully variable”. When the ECM detects that the camshafts are in the optimum positions, the solenoids maintain oil pressure on the units to hold the camshaft timing. The operation of the VANOS solenoids are monitored in accordance with the OBD II requirements for emission control. The ECM monitors the final stage output control and the signals from the Camshaft Position Sensors for VANOS operation.
  



The VANOS unit lifted off, notice how the cam and the cam gear are independent of each other without the VANOS gear in place.  Image courtesy of Beisan Systems.
This is the single VANOS engine (found in M50 engines). It controls the intake cam gear, which is mechanically linked to the exhaust gear with a chain. The key of the VANOS design is that the cam gear and the cam itself are independent, and both have splines.  The gear/cup in the VANOS system inserts in between these two parts, mechanically linking them.  The VANOS gear has two sets of splines, the outer for the cam gear and the inner for the cam itself.  The splines have a twist to them, also known as a helical gear, so as the gear inserts itself further between the cam and cam gear, the relative position changes, if by only a few degrees.


At idle, the gear is retracted.  As the RPM bumps off idle, the cup inserts further into the gear and advances intake valve timing.  This creates intake and exhaust valve overlap, allowing for exhaust gas recirculation (an operation designed to improve emissions while cruising).  When accelerating into the higher RPM ranges, the solenoid closes and the cup retracts once again, reducing overlap and going for max power.  It should be noted that this solenoid gets a real workout, and is a common failure in these engines as they age.



The VANOS solenoid opens, allowing the helical gear cup to push forward and change the orientation of the cam in relation to the gear a number of degrees.
Double VANOS has a hydraulic pod (found in later cars) extending into both cam gears, and has control over both intake and exhaust cam timing independently.  This system is much more advanced than single VANOS, allowing for constantly variable timing.  The ECU can change the intake and exhaust cam timing, and however it so pleases.  Using different maps for different situations ( warm up, cruising, thrashing).

In all practical senses, the system is quite simple and ingenious.  Many of the best car makers do it. All it takes is putting a few different shaped gears together to pull off something amazing.  Now in 2014, you will see that nearly all automakers have some form of variable valve timing, but BMW was one of the few early companies to take full advantage of such a system early on.

VANOS Units

The infinitely variable double VANOS system uses a hydraulic oscillating motor type
VANOS units for the intake and the exhaust cams. Although they have identical function,
the oscillating motor VANOS units are a further development of the variable vane type
motor VANOS units used on previous systems. They are designed as an integrated
component in the chain drive and are mounted with a central bolt on the respective
camshaft. When de-pressurized, a coil spring holds the VANOS unit in the base position.
The VANOS units are controlled by oil pressure from the 4/3 proportional solenoid
valves. The valves are located in the front of the cylinder head and are controlled by the
ECM. The ECM regulates the VANOS based on factors such as engine RPM, load and
coolant temperature.


N52 Hydraulic oscillating motor/VANOS unit




     
Index
Explanation
1
Front plate
2
Locking pin
3
Oil channel
4
Casing with oil ring
5
Pressure chamber for advancing
6
Oscillating rotor
7
Pressure chamber for retarding
8
Oil channel



The VANOS units are controlled by oil pressure from the 4/3 proportional solenoid
valves. The valves are located in the front of the cylinder head and are controlled by the
ECM. The ECM regulates the VANOS based on factors such as engine RPM, load and
coolant temperature.

N52 VANOS system





Index
Explanation
1
VANOS unit, Exhaust
2
VANOS unit, Intake
3
Intake camshaft sensor
4
Exhaust camshaft sensor
5
VANOS solenoid valve
6
VANOS solenoid valve

Here are just some of the benefits of the VANOS.
  • It increases torque at lower to mid range engine speeds with no loss of power in the upper range engine speeds.
  • It allows for increased fuel economy due to optimized valve timing angles, and reduced emissions.
  • You enjoy a smoother idle quality due to optimized valve overlap



Conclusion:

There is no overlooking the BMW M6’s hefty price. However, most M6 owners are extremely satisfied with their purchase. The car’s high-tech features and stunning design make it a dream vehicle. Every driver will get addicted to the M6’s high-revving engine.


Benefits of VANOS



Benefits of VANOS

  •          Overall increase in torque and power.
  •          Particularly in the lower RPM range, lower than 3000 RPM.
  •          Resolution of bogging then surging at 3000 RPM.
  •          Smooth even distribution of power and RPM transition.
  •          Resolution of engine hesitations in the lower RPM range, lower than 3000 RPM.
  •          Quiet stable at idle state.
  •          Smooth easy take offs.
  •          Improved performance when AC is on.
  •          Reduced fuel consumption by 10%.