|
1. 2000 Civic Si
Comptech Ice Box vs. Stock
Dyno Result
http://www.comptechusa.com/images/dy...ic_si_plot.pdf
2. 2000 Si
Comptech I/H/E vs Stock
Dyno Results
http://www.comptechusa.com/images/dy...icsi-build.pdf
3. 2002 Si
AEM CAI vs Stock
Dyno Result
http://www.aempower.com/pdf/results/21-5082002CivicSI_CAS.pdf
AEM Short Ram vs Stock
Dyno Result
http://www.aempower.com/pdf/results/22-508_2002CivicSISRS.pdf
4. 2003 Si
Comptech H/E vs Stock
Dyno Results
http://www.comptechusa.com/images/dyno/03si-h-e.pdf
5. 2002 Si
Injen CAI vs. Stock
-----------
Dc-Sports 4-2-1 vs 4-1 vs Stock
Mods: Stock
Peak HP: 139.2
Peak TQ: 100.0
Mods: DC Sports 4-2-1 header
Peak HP: 142.9
Peak TQ: 103.5
Mods: DC Sports 4-1 header
Peak HP: 140.9
Peak TQ: 104.0
1. What's the difference between an Si and a SiR?
The SiR is the Canadian version of the US Si.
Canadian SiR=Us Si
Canadian Si=Us Ex
The only differences that there are between the US Si and the Canadian
SiR are:
1. The SiR is also available in VSM (Silver)
2. The SiR has heated mirrors.
3. The SiR has anti lock breaks (ABS)
4. The SiR has a slightly larger washer fluid Reservoir.
What is VTEC and how does it work?
*Lets see how DOHC VTEC works. The figure to the right shows a
simplified representation of a intake-valve VTEC mechanism (the exhaust
mechanisms work similarly). So for each pair of valves, there are three
cam lobes. The two on the outside are low RPM lobes and the one in the
middle is the high RPM lobe. The two low RPM lobes actuate the two valve
rockers, which in turn pushes the valves open. The high RPM lobe
actuates a follower, which is shaped like a valve rocker, but doesn't
actuate any valves. The figures show the circular section of the cam
lobes touching the valve rockers, and the elliptical section pointing
away. Thus the valves are closed in this stage.
During low RPM operations, the two outer cam lobes directly actuates the
two valve rockers. These low PRM lobes are optimized for smooth
operation and low fuel consumption. The high RPM lobe actuates the
follower. But since the follower isn't connected to anything, it doesn't
cause anything to happen. This process is illustrated by the figure to
the right.
At high RPMs, oil pressure pushes a metal pin through the valve rockers
and the follower, effectively binding the three pieces into one. And
since the high RPM lobe pushes out further than the low RPM lobes, the
two valve rockers now follow the the profile of the high RPM lobe. The
high RPM lobe's profile is designed to open the valves open wider, and
for a longer duration of time, thus allowing more fuel/air mixture to
enter the cylinder. The improved breathing allows the engine to sustain
its torque output as RPM rises, thus resulting in higher power output
That is basically how VTEC works. The picture to the right is a picture
of an actual DOHC VTEC engine. Note that there are two cam shafts, one
for the intake valves and one for the exhaust valves. For each pair of
valves, notice that there are three cam lobes: two cam lobes on the
outside, and one cam lobe in the middle.
*The information provided came from
http://www.leecao.com/honda/vtec/dohcvtec.html
To sum it all up...
VTEC: Variable Valve Timing and Lift Electronic Control.
“VTEC is an electronic and mechanical system in some Honda engines that
allows the engine to effectively have multiple camshafts. As the engine
moves into different RPM ranges, the engine's computer can activate
alternate lobes on the camshaft and change the cam's timing. In this way
the engine gets the best features of low-speed and high-speed camshafts
in the same engine.”
Basically VTEC is a system that allows the engine to act as two totally
different engines all in one. When in the lower RPM range the engine
operates smoothly, quietly, and fuel efficiently. However, once you
reach the higher RPM range (*5500+) the engine turns into a completely
different machine. It turns into a power hungry, gas guzzling race
engine.
*VTEC will engage in the 99-00 Si/SiR at ~5500 RPM
-you know about the valves that let air into the engine and let exhaust
out of the engine. You also know about the cam shaft that controls the
valves. The camshaft uses rotating lobes that push against the valves to
open and close them. This is an animation from How Car Engines Work to
help understand how the cam shaft opens and closes the valves:
It turns out that there is big relationship between the way the lobes
are ground on the camshaft and the way the engine performs in different
RPM ranges. To understand why this is the case, imagine that we were
running an engine extremely slowly - at just 10 or 20 RPMs, so it took
the piston seconds to complete a cycle. It would be impossible to
actually run a normal engine this slowly, but imagine that we could. We
would want to grind the cam shaft so that, just as the piston starts
moving downward in the intake stroke, the intake valve would open. The
intake valve would close right as the piston bottoms out. Then the
exhaust valve would open right as the piston bottoms out at the end of
the combustion stroke and would close as the piston completes the
exhaust stroke. That would work great for the engine as long as it ran
at this very slow speed.
When you increase the RPMs, however, this configuration for the camshaft
does not work well. If the engine is running at 4,000 RPM, the valves
are opening and closing 2,000 times every minute, or 3 to 4 times every
second. When the intake valve opens right at the top of the intake
stroke, it turns out that the piston has a lot of trouble getting the
air moving into the cylinder in the short time available (a fraction of
a second). Therefore, at higher RPMs you want the intake valve to open
prior to the intake stroke - actually back in the exhaust stroke - so
that by the time the piston starts moving downward in the intake stroke
the valve is open and air moves freely into the cylinder during the
entire intake stroke. This is something of a simplification, but you get
the idea. For maximum engine performance at low engine speeds the valves
need to open and close differently than they do at higher engine speeds.
If you put in a good low-speed camshaft it hurts the engine's
performance at high speeds, and if you put in a good high-speed camshaft
it hurts the engine's performance at low speeds (and in extreme cases
can make it very hard to start the engine!).
It turns out that there is big relationship between the way the lobes
are ground on the camshaft and the way the engine performs in different
RPM ranges. To understand why this is the case, imagine that we were
running an engine extremely slowly - at just 10 or 20 RPMs, so it took
the piston seconds to complete a cycle. It would be impossible to
actually run a normal engine this slowly, but imagine that we could. We
would want to grind the cam shaft so that, just as the piston starts
moving downward in the intake stroke, the intake valve would open. The
intake valve would close right as the piston bottoms out. Then the
exhaust valve would open right as the piston bottoms out at the end of
the combustion stroke and would close as the piston completes the
exhaust stroke. That would work great for the engine as long as it ran
at this very slow speed.
When you increase the RPMs, however, this configuration for the camshaft
does not work well. If the engine is running at 4,000 RPM, the valves
are opening and closing 2,000 times every minute, or 3 to 4 times every
second. When the intake valve opens right at the top of the intake
stroke, it turns out that the piston has a lot of trouble getting the
air moving into the cylinder in the short time available (a fraction of
a second). Therefore, at higher RPMs you want the intake valve to open
prior to the intake stroke - actually back in the exhaust stroke - so
that by the time the piston starts moving downward in the intake stroke
the valve is open and air moves freely into the cylinder during the
entire intake stroke. This is something of a simplification, but you get
the idea. For maximum engine performance at low engine speeds the valves
need to open and close differently than they do at higher engine speeds.
If you put in a good low-speed camshaft it hurts the engine's
performance at high speeds, and if you put in a good high-speed camshaft
it hurts the engine's performance at low speeds (and in extreme cases
can make it very hard to start the engine!).
VTEC (which stands for Variable Valve Timing and Lift Electronic
Control) is an electronic and mechanical system in some Honda engines
that allows the engine to effectively have multiple camshafts. As the
engine moves into different RPM ranges, the engine's computer can
activate alternate lobes on the camshaft and change the cam's timing. In
this way the engine gets the best features of low-speed and high-speed
camshafts in the same engine.
Variable Valve Timing and Electronic Control. It works by adding an
additional cam lobe that alters valve timing duration and lift to
improve engine breathing and boost output for a smoother more powerful
response. Both Honda and Acura use the VTEC system in various
performance-oriented vehicles, such as the Honda Civic Si, the Honda
Civic EX, the Honda Civic delSol Si and delSol VTEC, and the Honda
Prelude Si and Prelude VTEC. There are variations on this sytem that
include different lobe profiles on the exhaust valves as well.
Just an example of SOHC VTEC vs. SOHC Non-VTEC
Civic: DX
Type: Aluminum-Alloy In-Line 4
Displacement (cc0 1590
Horsepower @ rpm 106 @ 6200
Torque (lb.-ft. @ rpm 103 @ 4600
Compression Ratio 9.4:1
Valve Train: SOHC 16-V
Fuel System: Multi-Point Fuel Injection
Ignition System: Electronic
Final Drive Ratio (MT/AT) 4.06/4.36
Civic: EX
Type: Aluminum-Alloy In-Line 4
Displacement (cc) 1590
Horsepower @ rpm 127 @ 6600
Torque (lb.-ft. @ rpm)107 @ 5500
Compression Ratio 9.6:1
Valve Train: VTEC
Fuel System: Multi-Point Fuel Injection
Ignition System: Electronic
Final Drive Ratio (MT/AT) 4.25/4.36
|
Menu
Site Search
Recent Forum Posts
Most popular downloads