Swimmingskibble [???]... hope this makes sense...
In aerospace, very high strength forms of steel [low alloy, tool, etc], CRES and titanium alloys have relatively tiny differences between ultimate and yield strength resulting in low toughness and low strain to failure.
These materials are usually ‘worked’ [rough machined, welded, etc] in low strength states such as annealed or solution heat treated [not quenched]. Thick section parts may be subject to multiple annealing operations for strain/distortion control with aggressive rough machining and/or cold, warm or hot straightening as necessary in-between.
However there is an inevitable point in processing when these parts must be heat treated to the highest mechanical stress state, usually just prior to final machining. At this point, any mechanical operation [machining, drilling, reaming, grinding etc] or chemical operation [etch, cleaning, etc] can induce embedded stresses in the surface… which must be eliminated by stress relieving HT operations to prevent brittle fracture. For each of the alloy families mentioned above, there are specific processes for this purpose.
NOTE. after all Inspections are done and the part has been declared fit for finishing, these same parts are usually shot-peened to further enhance the surface by compressive forces which retard crack/corrosion initiation… then are plated/coated for added environmental resistance. At each of these stages fabrication stages, secondary heat treat operations, annealing, embrittlement relief, stress relief are done routinely… just to get to the next stage/operation. HOWEVER, EVERY operation can be a spoiler if done wrong, not done at all or done out-of-sequence. Gaaaaa!
A clear example of the complexity of processing involved, is work with ultra-high strength steel parts [IE main landing gear parts] typically 4340M and 300M steel heat treated above 270-KSI. Do anyone step wrong in a processing sequences [fail to anneal between aggressive machining operations, miss a hydrogen embrittlement relief, miss a second temper operation, etc]… and the material goes in the dumpster. Reasons are obviously complex; however, when processed correctly these alloys perform well and predictably.
A classic example of this intricate fabrication dance is given in SAE ARP1631 Manufacturing Sequence for Fabrication of High-Strength Steel Parts - 300M or 4340 Modified Low-Alloy Steels - 270,000 psi (1860 MPa) Tensile Strength and Higher. I have referred to this carefully written document many times when dealing with these/similar ferrous alloys at the limits of their heat treatment … and have developed similar/parallel processes for VHS CRES and Ti-parts. So far so good.
Regards, Wil Taylor
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