Hi Lin, I love to share stuff I know about and soak up other people experience as well. I was chatting with Barry the owner of South Auckland Forgings this morning and discussing with him what I had said on the forum just to be sure I was sending you in the right direction. He has been in the heat treatment industry all his life and what he doesn't know isn't worth worrying about. I asked him again about springs and what tempreature would start to have and impact. He is adamant that until you get steel to at least 400 your not touching any of its performance characteristics. He was saying that the material the spring is made from is by far the most determanant factor of how the spring will perform. I am going to run with his recomendation and get the springs powdercoated.
I was talking to him this morning as I am just about to cut down my steering column in order to fit power steering to the car. I dropped off a column to him previously for one of my other cars and asked him to cut and weld it. Without even discussing he did all this deep analysis on the shaft to determine the best and safest way to weld it up. They have a mass spectrometer which can analyse any carbon based steel as well as stainless. Check out his OTT fix. ->
Hi Burnsy. Please see my report below re the modifications to your steering column.
The existing hollow column of 18mm diameter was analysed as 0.07%C, 0.3%Mn. This indicates a soft deep-drawing mild steel. Prelininary hardness tests indicated an approximate Ultimate Tensile Strength (UTS) of 550 MPa. This result (high for this chemistry), together the low ductility exhibited during analysis, indicates extensive cold working during original manufacture.
The column was cut to required length, and an AISI 4140 high tensile Cr-Mo insert pushed into the column to join it together again. The insert had a flange in the middle of 18mm diameter, and it was around each side of this flange that the joining welds were made. The assembly was preheated to 200degC and welded using high tensile low hydrogen electrodes. Porosity was evident in some areas around this weld, and these areas were ground out then preheated and repaired using TIG process. The insert extends 100mm+ into each half of the column, and approx 80mm along each of these inserts legs and longitudinal slot was ground in the column, then welded up per the above procedure. The purpose of these welds was to assist in torque transfer through the insert rather than just the joining weld.
After all welds were finished the welded area was post-weld heat treated at 500degC. This was to relieve welding stresses, lower any hard areas in the weld, and change structure to tempered martensite.
During fairing-out the diameter of the welded joint was reduced from 18mm to a minimum (spot measurement) of 17.25mm. This is deemed not to have any detrimental affect on the strength of the assembly, as it occurs within a region fully supported by the high tensile core. It should be noted that the smallest diameter of the column at the point where the drive spline commences is 16.6mm.
Yours faithfully,
Barry Robinson
S.A.F.E Engineering
Ph ++64 9 2948437
Fax ++64 9 2948431
Cell 027 2864722
