TorqByte Tuning

Slowly I’ve been trying to get up to speed on the TorqByte water-methanol injection controller and the TorqTune software application that gives access to the functionality of the controller.  The software has a good deal of capability, more than I am accustomed to from a WMI system, and thus is taking some time to get familiar with.

Up to now I have just been injecting a small amount of liquid and not given much concern to how it is being injected since my goal has been to keep IAT’s in check during dyno pulls.  Looking at some of the recent data (below) I decided to start tweaking the software settings, primarily the pump duty cycle table that drives the injection rate.

torqbyte_wmi_results_f21_rev2

I’ve chosen to try and up the WMI flow rate slightly around the point where peak boost pressure is being reached and also to slightly pull back on the injection rate beyond 5000 rpm.

The pump duty cycle table is straight forward to modify (below).

torqbyte_f21_rev2

The engine speed range is adjustable on the main page and the setting updates on the table, shown above the maximum engine speed on the table is 7500 rpm.  I dropped this down to 7000 rpm since I rarely get much past 6500 rpm.  This changed the engine speed increments from 500 rpm intervals to 400 rpm intervals.

I then went into the table and updated the duty cycle at the engine speeds of interest, around 3400 rpm and past 5000.

This configuration is saved to a unique file and then can be loaded into the TorqByte controller via a USB cable.

Path Temperatures Along Intake Tract

Currently I have air temperature sensors located at various points along my S4’s intake path to monitor the air temperature under various driving conditions.

There is one sensor located in the intake pipe leading into the turbocharger compressor, approximately 10 inches before the inlet.

Another sensor is located in the hard pipe at the turbocharger compressor outlet but before the air to air intercooler.

I have access to temperature data from the vehicle intake air temperature sensor which is located at the entrance to the intake manifold.

A fourth air temperature sensor is the vehicle outside air temperature sensor located in front of the radiator.

Driving while logging these locations provides some idea of how the different components affects the temperature of the intake air as it travels along it’s path to the engine.

Shown below is a chart of these temperatures over several minutes of driving under changing conditions.

Chart of intake air path temperatures

As documented on the chart, the orange line was the atmospheric temperature at the time of this drive, a cold 28 degrees Fahrenheit.

The blue line shows the temperature of that air after passing through the intake snorkel, airbox/filter, MAF housing, accordion, Y-pipe, and upper turbo inlet piping.

Note: This log was made after driving for a short while, prior to which the vehicle was parked inside a garage where the air temperature was around 50 degF.

The red line shows the next stop on the air’s journey to the engine, after it has passed through the turbocharger compressor.  The large upward spikes indicate when the turbochargers were producing boost, around 22 psi in the case of the larger spikes.

Last, the green line shows the temperature after the air has passed through the intercooler and is entering the intake manifold.

Observations:

One of the most obvious take-aways from this chart is how substantially the turbochargers heat the intake air when producing boost, even at relatively modest levels for a stage 3 setup.

Another significant point is how well the intercoolers work at bringing that temperature back down so what is fed to the engine is relatively cool.  During this drive I was using the Silly Rabbit Motorsport B5 S4 SMIC’s.

Something this chart does not answer, but may provide some perspective about, is the significance of additional methods at heat management.  For example, thermal wraps, reflective barriers, cold air intakes, etc.  If the turbocharger is raising the temperature of the air up to 200 degF above the temperature it enters the compressor at, and then the intercooler pulls that air temperature back down by about 190 degF, is wrapping the entire intake path going to make much difference in the outcome?

Fluidampr crankshaft pulley

Soon to be installed on my S4 is one of the Fluidampr engine dampers.

Fluidampr 2.7T engine dmapener

I’m not expecting to be able to detect any difference from the driver’s seat, but hopefully it will help with engine longevity, especially at higher than stock horsepower levels which I expect my car to be operating at.

Here’s it is on a bathroom scale, weighing in at 7.2 lbs.

fluidampr_weight

And a couple more angles of the product.

fluidampr_bottom

fluidampr_side

Today I removed the stock crankshaft pulley and weighed it on the same scale to compare with the Fluidampr weight.

stock_damper_weight

  • Stock: 4.6 lbs
  • Fluidampr: 7.2 lbs

Here’s the two parts side-by-side:

fluidampr_stock_damper
(L-R) Stock, Fluidampr

Installed on the S4.

fluidampr_installed_27t

Finally, some additional information about what these viscous dampers do to help mitigate the affects of torsional vibration.