At the end of the day, a single alphanumeric character has at least 36 possible values. If you include punctuation, lower case, etc then you can easily pass 72 possible values.
A non-colliding number that allows you to quickly compare strings would necessarily grow exponentially with the length of the string.
So you first must decide on the longest string you are expecting to compare. Assuming it's N characters in length, and assuming you ONLY need uppercase letters and the numerals 0-9 then you need to have an integer representation that can be as high as
For a string of length 25 (common name field) then you end up needing a binary number with 130 bits.
If you compose that into 32 bit numbers, you'll need 4. Then you can compare each number (four integer compares should take no time, compared to walking the string). I would recommend a big number library, but for this specialized case I'm pretty sure you can write your own and get better performance.
If you want to handle 72 possible values per character (uppercase, lowercase, numerals, punctuation...) and you need 10 characters, then you'll need 62 bits - two 32 bit integers (or one 64 bit if you're on a system that supports 64 bit computing)
If, however, you are not able to restrict the numbers in the string (ie, could be any of the 256 letters/numbers/characters/etc) and you can't define the size of the string, then comparing the strings directly is the only way to go, but there's a shortcut.
Cast the pointer of the string to a 32 bit unsigned integer array, and compare the string 4 bytes at a time (or 64 bits/8bytes at a time on a 64 bit processor). This means that a 100 character string only requires 25 compares maximum to find which is greater.
You may need to re-define the character set (and convert the strings) so that the characters with higher precedence are assigned values closer to 0, and lower precedence values closer to 255 (or vice versa, depending on how you are comparing them).