OVERVIEW
The 3.5 RL is powered by an all-aluminum, 3.5-liter,
single-overhead-camshaft, 90-degree V-6 engine that produces
225
horsepower at 5200 rpm and 231 lb.-ft. of torque at 4700 rpm.
Four-valves-per-cylinder, a three-stage variable induction
system, a
sophisticated PGM-FI fuel-injection system, a variable silencer
and
an advanced air intake help to provide both high torque at lower
engine speeds and excellent breathing at higher engine speeds.
The
3.5 RL meets LEV (Low Emission Vehicle) standards. It is also
designed to run for 105,000 miles before its first scheduled
tune-up.
The engine is located longitudinally, moving weight to the rear of the car for the 60/40 weight distribution deemed optimum for a front-wheel-drive sedan. The longitudinal mounting also yields reductions in noise, vibration, and harshness (NVH), because it allows the use of softer, optimally positioned engine and transmission mounts.
An electronically controlled, 4-speed automatic transmission, with Grade Logic Control is standard on every 3.5 RL.
ENGINE BLOCK
The block of the RL engine is made of cast aluminum with
cast-in iron
cylinder liners, a design emphasizing light weight, rigidity, and
outstanding long-term durability. Designed with deep skirts and
extensive webbing for added rigidity, the crankcase minimizes
noise
and vibration. The RL engine, a slightly undersquare design with
a
bore of 90.0 mm and a stroke of 91.0 mm, yields a displacement
of
3474 cc.
The generous main bearing journal supports add rigidity and significantly reduce vibration in the 300-to-800 Hz range. By optimizing stiffness, the resonant frequency of the engine block is an impressive 20 Hz -- meaning that this engine transmits very little vibration through the rest of the vehicle.
PRIMARY COUPLE BALANCER
The rotating balance shaft, mounted to the right side of the
engine
block, further reduces vibration transmitted to the passenger
cabin.
The belt-driven balancer counteracts the rocking tendency
inherent in
90-degree V-6 designs.
CRANKSHAFT
To reduce friction and enhance durability, the forged steel
crankshaft is microfinished, an extremely precise finishing
process
developed originally for the Honda Formula One engine
program. The
sophisticated metallurgy of the main bearings is another benefit
gained from the Honda Formula One program. The surface of
the
bearings has a unique, pyramidal structure, allowing space for
enhanced oil retention, reduced friction and improved long-term
durability.
BLOCK-FORGED CONNECTING RODS
The 3.5 RL has connecting rods forged using a unique,
advanced-technology process, called block-forging, that results
in
parts of unprecedented strength and uniformity. The RL engine
is the
first automobile engine in the world to utilize this advanced
technology.
Because of the imprecise nature of the conventional forging process, the connecting rods in other manufacturer engines must be sorted according to weight, with rods of approximately equal mass assigned to each particular engine to achieve proper reciprocating balance. Even in rods that happen to have equal overall mass, the distribution of metal density throughout conventional rods can vary enough to affect strength and engine balance.
In marked contrast, the rods of the RL are forged with a "block-forging" system in which the steel blank is struck, at extremely high pressure, from five directions at once. This process has no allowance for excess metal; giving it nowhere to go in the ultra-precise block-forging dies. Accordingly, the blanks that will be forged into RL rods are machined before the forging process, to exacting mass tolerances. In other words, the material that will become an RL connecting rod has been precisely measured and balanced before it ever enters the forging dies.
As a result of this process, RL connecting rods are among the most precisely balanced of any rods found in a production-automobile engine.
FULL-FLOATING PISTON PINS
To reduce engine noise caused by contact between the pistons
and
piston pins, the RL engine uses a full-floating piston pin design
that reduces the clearance between them. Typically, a piston pin
is a
press fit in the rod, and a larger clearance between the pin and
the
aluminum piston allows the piston to rock freely. In the more
innovative RL design, the pin moves freely in the rod and the
piston
rocks freely on the pin; the piston pin is essentially free to
"float" between the piston and the rod. This advanced design
results
in a significant 5 decibel noise reduction.
CYLINDER HEAD/VALVETRAIN
The RL engine features a four-valve-per-cylinder valvetrain with
pentroof combustion chambers. A flexible, toothed belt drives a
single camshaft for each cast-aluminum cylinder head.
Hydraulic lash
adjusters are used for quieter running and reduced
maintenance.
The combustion chamber is designed with a generous "squish" area formed by the piston and cylinder head - promoting rapid and complete combustion by increasing the turbulence of the fuel air mixture around the centrally located platinum tipped spark plug.
VALVE TIMING
Conventional high-performance engines typically use a
substantial
amount of valve overlap to achieve better breathing at higher
rpm,
with the intake and exhaust valves opening simultaneously at top
dead
center between the exhaust and intake strokes. At low rpm,
however,
this allows blowback of the fuel-air mixture, with exhaust gas
creating a pressure wave that reverses the flow of the fresh
incoming
charge. To prevent the resulting unstable combustion - and
relatively
rough running - at low rpm, the RL camshaft timing has
considerably
reduced valve overlap, resulting in smoother low-speed running
and
improved low-rpm torque. The advanced four-valve-per-cylinder
design,
and the Variable Induction System intake tract, combine to
maintain
excellent high-rpm power output.
TIMING BELT
To further reduce noise, the resonant frequency of the timing belt
has been tuned by altering both its width and its material. The
position of the belt tensioner was also optimized as part of the
intensive effort to reduce overall engine noise.
VARIABLE INDUCTION SYSTEM
To tune the intake system volume and length for optimum torque
at any
rpm, the RL uses a three-stage intake manifold. To enhance
cylinder
charging by making use of resonance effects in the intake tract,
the
engine uses a longer intake tract at low rpm, transitions to a
mid-length tract in the mid-range, and then is opened completely
for
high-rpm running - allowing the inertia effect of the moving
column
of air in the system to enhance cylinder filling at higher engine
speeds. The system has been designed and tuned for the
special
low-rpm/high-torque tuning emphasis of the RL engine.
VARIABLE-SILENCER
The RL features an innovative variable silencer. A special valve
in
the first exhaust chamber within the muffler is able to route the
exhaust as needed for quiet operation and, when applicable,
reduced
back pressure for improved power output. Under normal driving
conditions, the valve is closed - channeling exhaust flow through
the
entire muffler tract for maximum noise reduction. During hard
acceleration, however, at 3500 rpm the valve opens - allowing
exhaust
to flow directly to the muffler's dual exit chambers for improved
flow and enhanced engine output.
AIR INTAKE
In addition to its variable silencer, the RL's V-6 engine benefits
from a unique air intake-joint shape and a large intake-opening
size
for enhanced airflow to the intake manifold. The increase in
intake
airflow allows for a proportionate increase in fuel delivery, with a
corresponding increase in ignition timing for enhanced engine
power
and response.
PROGRAMMED FUEL INJECTION (PGM-FI)
Programmed Fuel Injection (PGM-FI) compensates for varying
driving
and atmospheric conditions, providing enhanced drivability and
engine
efficiency in a wide variety of conditions. Data on coolant
temperature, air temperature and density, manifold vacuum,
engine
rpm, throttle position, crankshaft position, and exhaust oxygen
content is interpreted by the Electronic Control Module (ECM),
which
determines fuel injector duration and timing as well as ignition
timing and transmission operation. To reduce the pulsing noise
emanating from the fuel injectors, a special sound-dampening
unit is
mounted at the junction of the fuel delivery tube and each
individual
injector.
4-SPEED GRADE LOGIC CONTROL AUTOMATIC
TRANSMISSION
The result of an extensive development program, the advanced,
computer-controlled automatic transmission of the RL
underscores
Acura's unwavering commitment to automotive refinement,
efficiency,
and responsiveness.
The 4-speed transmission uses the innovative Grade Logic Control system to enhance uphill and downhill powertrain smoothness. When driving on steep grades, the Electronic Control Module automatically holds the transmission in the proper gear, even if a reduction in throttle position would otherwise dictate an upshift. This all but eliminates unnecessary shifts and "gear hunting." Also, on downgrades, the transmission holds third gear instead of automatically shifting to fourth, letting engine braking help prevent unwanted velocity.
A refined, lock-up torque converter enhances performance and acceleration while optimizing fuel efficiency and engine braking. Developed to reduce the "creeping" effect at idle, the converter makes the vehicle extraordinarily easy to hold with the foot brake at a stop.
HYDRAULIC SUBFRAME MOUNT
To reduce engine noise under acceleration, the subframe
mounts
between the engine/transmission/suspension assembly are
filled with
hydraulic fluid of a specifically tuned viscosity. The resulting
softer damping rate further isolates the passenger compartment
from
engine and road noise.
ELECTRONIC/HYDRAULIC ENGINE MOUNTS
To reduce vibration at idle, the RL uses hydraulic engine mounts
with
two different damping rates: a soft rate that allows the
engine/transmission unit to move more freely at idle and a stiffer
rate that positions the powertrain more firmly during driving.
Between 820 rpm and 850 rpm, the damping characteristics of
the
mounts change automatically; a small solenoid valve closes,
restricting the flow of fluid from chamber to chamber thus
increasing
the damping rate.
In addition, the main engine mounts have been located very close to the center of mass of the engine/transmission unit, more effectively isolating the primary inertial couple effect at idle. This change has resulted in significantly reduced vibration felt at the front seat in the critical 500 to 1200 rpm idle and off-idle range.