"Worst case" sometimes depends on "worst case under what constraints".
The case of a hashtable with a valid but stupid hash function mapping all keys to 0 generally isn't a meaningful "worst case", it's not sufficiently interesting. So you can analyse a hashtable's average performance under the minimal assumption that (for practical purposes) the hash function distributes the set of all keys uniformly across the set of all hash values.
If the hash function is reasonably sound but not cryptographically secure there's a separate "worst case" to consider. A malicious or unwitting user could systematically provide data whose hashes collide. You'd come up with a different answer for the "worst case input" vs the "worst case assuming input with well-distributed hashes".
In a given sequence of insertions to a hashtable, one of them might provoke a rehash. Then you would consider that one the "worst case" in that particular. This has very little to do with the input data overall -- if the load factor gets high enough you're going to rehash eventually but rarely. That's why the "amortised" running time is an interesting measure, whenever you can put a tighter upper bound on the total cost of
n operations than just
n times the tightest upper bound on one operation.
Even if the hash function is cryptographically secure, there is a negligible probability that you could get input whose hashes all collide. This is where there's a difference between "averaging over all possible inputs" and "averaging over a sequence of operations with worst-case input". So the word "amortised" also comes with small print. In my experience it normally means the average over a series of operations, and the issue of whether the data is a good or a bad case is not part of the amortisation. nneonneo says that "there's no such thing as amortized worst-case performance", but in my experience there certainly is such a thing as worst-case amortised performance. So it's worth being precise, since this might reflect a difference in what we each expect the term to mean.
When hashtables come up with
O(1) amortized insertion, they mean that
n insertions takes
O(n) time, either (a) assuming that nothing pathologically bad happens with the hash function or (b) expected time for
n insertions assuming random input. Because you get the same answer for hashtables either way, it's tempting to be lazy about saying which one you're talking about.