Chebyshev used the divisibility of the middle binomial coefficient ${{2n}\choose{n}}$ to set upper and lower bounds on the number of primes in the form
$\frac{an}{log(n)} > \pi(n) > \frac{bn}{log(n)}$
for some constants $a$ and $b$. If $a$ is not too small and $b$ is not too large then the proofs can be elementary and quite short. See e.g. http://www.fen.bilkent.edu.tr/~franz/nt/cheb.pdf for proofs with $a = 6log(2)$ and $b= log(2)/2$
There must then be a prime between $x$ and $nx$ if
$ \frac{ax}{log(x)} < \frac{bnx}{log(nx)} $
which is equivalent to
$a log(nx) < bn log(x)$
so for the $a/b = 12$ as above you get
$12 log(n) < (n-12) log(x) $
$ x > exp({\frac{12 log(n)}{n-12}})$
so for any value of $n > 12$ this gives a lower bound for $x$ above which there is always a prime between $x$ and $xn$ then for smaller $x$ it can be checked by hand.