The main reason is the same reason we often prefer to use integer fractions instead of fixed-precision decimals. With rational fractions, (1/3) times 3 is always 1. (1/3) plus (2/3) is always 1. (1/3) times 2 is (2/3).
Why? Because integer fractions are exact, just like integers are exact.
But with fixed-precision real numbers -- it's not so pretty. If (1/3) is
.33333, then 3 times (1/3) will not be 1. And if (2/3) is
.66666, then (1/3)+(2/3) will not be one. But if (2/3) is
.66667, then (1/3) times 2 will not be (2/3) and 1 minus (1/3) will not be (2/3).
And, of course, you can't fix this by using more places. No number of decimal digits will allow you to represent (1/3) exactly.
Floating point is a fixed-precision real format, much like my fixed-precision decimals above. It doesn't always follow the naive rules you might expect. See the classic paper What Every Computer Scientist Should Know About Floating-Point Arithmetic.
To answer your question, to a first approximation, you should use integers whenever you possibly can and use floating point numbers only when you have to. And you should always remember that floating point numbers have limited precision and comparing two floating point numbers to see if they are equal can give results you might not expect.