I think the issue here is that your analysis of quicksort and heapsort is not precise enough to show why the constant factors would be different.

You can indeed show that on average, quicksort will do more comparisons than heapsort (roughly 1.44 n log_{2} n for quicksort versus n log_{2} n versus heapsort). However, comparisons are not the only determining factor in the runtime of heapsort and quicksort.

The main reason quicksort is faster is *locality of reference.* Due to the way that memory caches work, array accesses in locations that are adjacent to one another tend to be much, much faster than array accesses scattered throughout an array. In quicksort, the partitioning step typically does all its reads and writes at the ends of the arrays, so the array accesses are closely packed toward one another. Heapsort, on the other hand, jumps around the array as it moves up and down the heap. Therefore, the array accesses in quicksort, on average, take much less time than the array accesses in heapsort. The difference is large enough that the constant factor in front of the n log n term in quicksort is lower than the constant factor in front of the n log n term in heapsort, which is one reason why quicksort is much faster than heapsort.

In short - if all we care about are comparisons, heapsort is a better choice than quicksort. But since memory systems use caches and cache misses are expensive, quicksort is usually a much better option.

Also, note that log(n^{n}) = n log n and log (n!) = n log n - n + O(log n) via Stirling's approximation. This means that log (n!) is not much smaller than n log n, even as n gets very large. There definitely is a difference, but it's not large enough to make a huge dent on its own.

Hope this helps!

Introduction to Algorithmsfor why heapsort is O(n log n). – Oliver Charlesworth Aug 26 '13 at 18:51