But this is (1) unlikely to amount to much --YMMV per line
and pulley diameter–, AND (2) it’s only relevant were you
testing to determine line strength (which, though, is a good
thing to do, vs. using rated strength, if you’re concerned about
making some assertions per the line rather than per knots
relative to each other). At the point of information we now
have before us, much can be done in just getting good data
on the breakage, leaving the basis for “%” figures able to be
adjusted upon better info as to the accuracy of tensile-strength
rating.

I recall one fellow testing angling knots who found, in testing
himself for line tensile strength, that rated strengths could
be as much as HALF the actual strength (!!) --which, you see,
would give knotted strengths a high value compared to the
rating (50% of line rated 50% of its actual strength yields
a “100%” knot).

–dl*

That way you will have a survivor knot to examine;
it should’ve seen upwards of 90% of the force that
–knotted-- it can bear, which should be informative.

But the flaw as I see it is in the stroke-length of the
jack vs. the elasticity of the material : I surmise that
you will run out of push before the knots are anywhere
near rupture. Perhaps there could be some other means
to applying early tension, and then the power of the
jack brought to bear at that point, where there is no
longer so much elasticity remaining!?

(One will want to guard against significant whiplash
effects of ruptured line. Could it be done simply by
tying, in finer line hitched to either side of both knots
and that line secured to small weights? --the flying-apart
line shouldn’t have much mass in its force. In some
laid rope, the break will come --under slow loading–
in steps, a strand or two first, with resulting drop in
tension; the pulling can be arrested at this point, even.)

–dl*

ps : This topic should go under Knotting Explorations, IMO;
anyone is welcome to capture this (my) post and begin it
there. Topic : “Break Testing” might be best; I can see it
being worthwhile to pursue other sorts of testing, such as
non-break force testing (since, in general, we do hope that
our knots don’t break, though they might receive considerable
force; knots for abseiling, e.g., should never get close to rupture),
and security testing (some means of continuous shaking!?).

The problem is that the pulley should have a deep groove, of the diameter of the rope, so the flattening of the material would be minimized. On the other hand, some will argue that this flattening might be beneficial, after all - because the relative differences between the inner and the outer track fibers, as they rurn around the curve, would be smaller…

Right - if one uses common car jacks. Moreover, if one would like to test nylon-made ropes, as I do , where the elongation is excessive, he will have to solve this problem. I plan to use two-, or even three-stage hydraulic bottles, and small diameter slings, so that even a 30% elongation of the rope+knot(s) sling would be within the limits, I guess. Another solution is the use of “High-Lift” jacks - a solution that I think is easy, cheap and reliable, for every knot tyer to test his knots - at least for destractive tests of small diameter ropes.

I believe one should place a protective tube around the pair of the tensioned lines.
The problem is it should be transparent - because it will be nice to be able to take pictures of the deforming and rupturing knot…