Mid-Term Presentation

Come stop by Temple University on Tuesday, October 19th. We'll be presenting for our mid-term review at 12:50PM in room 217A of the Howdard Gittis Student Center (SAC). Everyone is welcome, and the presentation is a short ten minutes. We'd love to see you there!

HEATT

Senior Design 2010 - 2011

Welcome Back!

The Fall 2010 semester at Temple University has begun bringing a new senior design team to work on the Audi TT. We'd like to introduce ourselves briefly:

Stephen Barrett - TU Senior - Mechanical Engineer

Jonathan Childs - TU Senior - Mechanical Engineer

Dean Cun - TU Senior - Mechanical Engineer

Emmy Messina - TU Senior - Electrical Engineer

We will be updating this blog regularly with our challenges, successes, troubles and overall progress on the Audi TT. We feel privileged to be a continuing part of this project and we are excited to get our hands dirty.

Stay tuned!

First road test

It is a success!

The weather was horrible. It rained and poured on the first day of testing, but by the second day, it cleared up and was beautiful.

On the first day, we took it for a spin and got it up to 25 mph. We didn't want to push it too far too soon especially with the way the weather was behaving.

On the second day, we took it up to about 40mph in a parking lot and it behaved exactly like a normal car except there were no engine noises and turning on the vehicle was eerily quiet.

Here is more of a press shot showing off Temple. The car looks so sexy and beautiful that it is hard not to see this as the future of passenger vehicles especially when the performance and handling is on par with a normal vehicle.

Here is a short video of the initial testing. We took it out for about 5 hours of testing and probably drove about 20 miles at varying speeds.

Prepping the vehicle for the first road test

We are getting close to testing the vehicle and this means we have to start putting it back together, stop debugging it for a couple of days, and finalize what we have at this point.

This is what the car looked like two days before it got moved out of our lab and into road testing.

We had to put the lights back on the vehicle and wire them up in addition to writing controls to engage the back reverse and brake lights when they would engage on a normal vehicle.

This is what it looked like the morning of the road test.

We tried to pick a good day weather wise for the test, but the weather took a turn for the worst as we began to take the vehicle out of our lab and onto the road.

Soundproofing the vehicle

One of the biggest advantages with electric vehicles and hybrids, is the lack of engine noise when the vehicle is not moving or moving at low speeds. Soundproofing was added to the rear of the passenger cabin to help reduce the noise created through road noise and the IC generator. This was achieved by building a sound wall, adding a sound box around the IC engine, and through modifying the muffler of the IC engine.

This is a view of the Geo Metro muffler that was adapted to fit the IC engine we have.

This shows the sound wall and a view of the rear of the vehicle.

Testing the Motor

After wiring the batteries, we connected the 3 phase AC motor cable to the motor controller connection and the power and ground of the batteries to the controller cables. Below is a picture of the 3 phase cable connected to the controller.


The controller also requires 12V DC to operate, so for our first test we simply just hooked up a lead acid battery from our lab. The tricky part at this point was connecting all the pins, or leads from the throttle (potential meter), motor controller, and starter switch (having options of reverse, start/neutral, and drive). This took some time to figure out, but after using the manual and connecting our laptop to the controller to troubleshoot, we managed to figure out the problem.

After working together, we finally had all systems go. We are ready to push the throttle and see our motor move. Mind you we were all very excited and extremely nervous because this is the first time we will see our design in action after working on the project since June 2009. Take a look below!

Wiring the Batteries

There are 90 lithium iron phosphate batteries wired in series. Each battery is roughly 3.2V which gives a total of 300 Volts. This took about a day and a half. With all the wiring preparation for the BMS, probably about a week. We covered each terminal with duct tape so we wouldn't accidentally short a battery or shock ourselves. Yea, we played it safe.

A close up shot of a terminal. The wire is connecting the bottom layer to the top. The large red wire is high gauge rated for the large amount of current and voltage, while the skinny orange wires are connected to each battery node to read voltage for the BMS, which is not yet connected to the white inserts.

Jordan admiring the awesome power and thankful he wasn't shocked.

Another shot of the wired batteries. Two layers, 90 batteries, 300V, ready to light the tires!