Electrathon America Forum

As of this year i have acquired a former students car, mike mcmurry (Centennial High School, car #50).  He had a strange steering set up when i got it.  It was designed to tilt the car in the direction of the turn.
it didnt work out and tended to break alot.  So this year i tore the steering off of the car after designing a new steering system. i did not get the car to lean like i had wanted to, but in turn i came up with a sysem that i am very satisfied with. while sitting in calculus one day with Nick Morrell, a fellow driver of from Centennial High School, and started doodling some designs.  I came up with something a little to complicated to work, but after showing on one my peers, he helped me refine it to something that worked. right now i am in the process of cutting, milling, lathing, bending, and grinding for countless hours to get it ready to weld.
after i had the drawings and was ready to start building the first of two prototypes (the first is on the left and the second on the right).
the first model i built so that i could test different angles of "king pin" inclination, i put the quotes because with the steering system i designed i eliminated the king ping and now have two stationary pivotal points. after i found the best angle for tire lean, 25 degrees, i then started to tilt the entire system various degrees in the vice to figure out the best angle for more tire lean after adding positive castor (positive castor is when the upper pivot point is behind the lower pivot point), it came out to 15 degrees to the positive.
after finding the 25 degree angle i built the second model to that measure, this time using ball joints instead on pins. this way when i put it back it the vice i could measure more presicely(?) the angle of tire lean i got. i measure the tire lean my putting a angle gauge on the spindle and recording the change in degree when turning left and right. i did this at 5, 10, 15, and 20 degrees. at 5 and 10 degrees the angle of tire lean was almost too small to notice but not non-existant. when i got to twenty degrees i ran into a problem that a few of the cars out there on the tracks today have, and that would be tire flop.
tire flop is when the wheels lean into the corner, but lean too much and at low speeds the weight of the car will force the wheels to fall over jerking the steering wheel (or lever steering) violently. on the track this can be very dangerous because if out are not anticipating it you can become a hazard to other drivers coming towards you.
at 15 degrees of caster i got 5 degrees of tire lean to the forward when on the outside of a corner, and 7 degrees to the rear when on the inside of the corner. this also causes the the inside tire to turn a few degrees sharper than the inside. i dont know how to explain this but i know that you want the inside tire to turn a little bit sharper because when turning a corner the tires travel on different paths. the inside tire on a sharper radius than the outside.
after building the prototypes i started on the actual steering system.
i started with the parts the pivot points are mounted too. i took a solit 1 1/2" solid aluminum. i turned the center down to 3/4" to save a bit of weight. then milled a block of aluminum into the "L" brackets you see in the close-up. the angles on the round stock are at 25 degrees to compensate for the 25 degrees of "king ping" inclination to creak clearence for the ball joints.
then i made a wood stand to mount the assemble to the position they will be mounted on the car. then i proceeded to bend and grind aluminum tubing fitted to mount the assembly to the car... 
at this point i am currently still in the process of bending my last piece of tubing and weld it to the frame..


if anyone would like to make a few suggestions please feel free. be considerate as i am also learning as i go.