Programming
and integration of the Innovate Motorsports LM-2 Analog input and the SuperFlow
AD30
By: Steve Estrada
WR Racing
I have been working with Superflow products for over 10 years now and
enjoy the superior accuracy and quality of their products.
I recently purchased the Innovate
Motorsports LM2 to replace an LM1 device that was originally integrated with
the AutoDyn 30.
While researching the integration
process, I found the analog connections had changed. Superflow originally sold
and supported Innovate products when this dyno was purchased and the LM-1 came
with the system.
The LM-2 analog cable P/N 3811 is a
cable that comes with a Molex 14 pin connector on one side and raw cable on the
other, giving you choice of connector.
Superflow Customer Service (719-471-1746), provided excellent support regarding
connectors and pins I needed to make a new cable.
I completed the cable and plugged
the LM-2 into the AD 30’s sensor box. I ran a quick test just to see what would
happen and found the scaling between the units was off by quite a bit.
Downloading the Logworks software
from the Innovate web-site was quick and installation was trouble free. After communication was established, I
experienced difficulty in getting the LM-2 to sync up with Logworks on a
consistent basis. This was tested with Windows 7 and XP with all updates. It
seems that plugging and unplugging is part of the normal process, a minor
annoyance. There were no problems like this in either, stand alone or
integrated use with the data acquisition.
Logworks allows you to program the LM2’s
analog inputs and outputs so you can log or integrate other 0-5v signals.
Let’s say you wanted to control a
methanol injection system using the Lambda output. You could use a solenoid to
open a valve at a certain lambda voltage providing control, safety and logging
capability for a boosted power plant. There are many possibilities.
Analog output 1 is what I chose for
this system. I had to calculate scaling so I went into the Superflow WinDyn configuration
editor to look at the way lambda voltage was processed.
The Lambda Voltage channel (104) was
set for Lambda volt * 2 + 9= Air Fuel Ratio. This means the lowest AFR Windyn
could read would be 9 and the highest would be 19 given a scale of 0-5 volts. I
checked the “use air-fuel ratio” button in the Logworks software and programmed
the LM-2 to output 0v at an AFR of 9 and 5v at an AFR of 19. I re-calibrated the
sensor and conducted some tests. I was delighted to see the dyno’s data acquisition
and the LM-2 display were always within .05A/F. The difference in sampling
frequency was the likely reason for this and I did not feel it was worth
changing.
I tested another car and the air-fuel
reading was way off. I started checking out the car’s electrical system with a voltmeter
and quickly found the car’s weak ground loop. After ground was re-established, the
voltage difference was then corrected.
This condition is caused by
differential voltage. In other words, the AC grounded Superflow and the poorly
grounded DC car caused an offset in what the LM-2 and WinDyn saw as the 0v
reference.
This was a nice little refresher
course for future troubleshooting.
Overall, I felt the integration was
easy and basically trouble free. I think it’s great that we can marry high tech
pieces of equipment in such an easy manner. It seems that todays devices are
really only limited by ideas not yet born.
Steve Estrada
WR Racing
* some images
from Innovate LM2 Manual
