Using result from  calculus:(1) $ log(xlogx)>log\vartheta \cdot log(2xlog2x)$ for  $2\leq \vartheta<e$ ($e$-Euler number) and  $ x>x(\vartheta )>2$, I am able to prove $ p_{2n}<\frac{2n}{log(\vartheta )}\cdot log(p_{n})$ for $n>n(\vartheta)$, where $p_{n}$ is the n-th prime number. The proof does not work for $\vartheta=e$, since inequality (1) is obviously not valid in this case. But  data suggests  also stronger result:       
$ p_{2n}<2n\cdot log(p_{n})$  for $n>52$. How can it be proved?