"page that is mapped in the virtual address space, but not loaded in physical memory" does not imply that it previously was in physical memory. Suppose you map a file? It's still on disk, not in memory yet.
Suppose you map a log file and keep appending to it. Every time you exceed the end of committed memory, a page fault occurs, the OS will provide you with a new empty page and adjust the file length.
It could also be access violations which are caught and handled by the program.
It could also be that the program uses more memory segments than fit in the TLB (which is a cache for the page tables). When pages are contiguous, they can all be handled by a single page table entry. But if memory is fragmented in physical address space, many page table entries are needed, and they may not fit in the TLB. When a TLB miss occurs, the OS page fault handler is invoked and looks up the mapping in the process's page table.
In some ways, this is a variation on Dean's answer: the pages are already in physical RAM, and the OS does need to load those mappings into the TLB, but not because of IPC.
Brian pointed out that x86 (and therefore all Win32 systems) handles this without a page fault.
Yet another cause of page faults is triggering guard pages used for stack growth and copy-on-write, but usually those would not occur without bound. I'm not 100% sure if those would show up as access violations or not, because they will be marked as an access violation on entry to the MMU trap, but are probably handled by the OS page fault handler and not transformed into the user mode (SEH) access violation.