You use comparison-based sorting when you're too lazy to write up a non-comparison based sort.
Comparison-based sorts are inherently slower; they need to call a comparator on input elements a whole bunch of times and each call gives the comparison-based sort exactly one bit of information. A correct comparison-based sort must accumulate log_2(n!) ~= n log(n) bits of information about its input on average.
Now, all data has a representation in the machine. You can tailor a sorting algorithm to your particular kind of data, the representation it has, and the machine you're using to sort, and, if you know what you're doing, you will often beat the pants off any comparison-based sorting algorithm.
However, performance isn't everything, and there are cases (most cases I've seen, in fact) where the most performant solution isn't the right solution. Good comparison-based sorts can take a black-box comparator and they will sort the input in a small constant times n log(n) comparisons. And that's good enough for almost all applications.
EDIT: The above only really applies for internal sorting, where you have more than enough RAM to store the whole input. External sorting (overflowing to a disk, say) should usually be done by reading about half a RAMful of data at a time, using a non-comparison-based sort, and writing the sorted result out. All the while being careful to overlap sorting with input and output. At the end, you do a (comparison-based) n-way merge.