There is no problem with the calculation of your expected Zs, this is correct.
For the adiabatic part I think this needs some thought about how you are calculating this value.
You have selected 2.5mm² as a cpc size and put that into the t=k²S²/I² equation and got 0.21s, this is all OK.
However reversing the equation operations to get back the original 2.5mm² is nominally valid but redundant maths.
You have chosen S and then used t=k²S²/I² and then used that t result in the standard form equation S= √(I²t) / k to get back the S you chose in the first place.
I.e. with
S= √(I²t) / k multiply both sides by k
kS = √(I²t) square both sides
k²S² = I²t divide both sides by I²
k²S²/I² = t
this shows both equations are the same so you cannot use the result of one form of the equation, where you have selected one of the values (S), and then use the other form of the equation to get a value for S because it will always be the original value you chose.
Substituting k²S²/I² in place of t in S= √(I²t) / k gives S= √(I²(k²S²/I²)) / k
Multiply by k and square both sides gives k²S² = I²k²S²/I²
The I² cancel each other out to give k²S²=k²S²
divide both sides by k² to get S²=S² and take the square root to get
S=S
which whilst accurate is not worthwhile.
However where you have a value of 0.21s as the maximum time before the cable is damaged from the first part of the calculation you can say that the magnetic trip will operate and will trip in at least 0.01 seconds therefore the cable will not be damaged as 0.01 is less than 0.21s and the cpc will be OK at that csa.
