Let $\pi$ be the prime counting function. Then $\pi(x)\geqslant\log x/(2\log2)$ for all $x\geqslant2.$ Maybe I am missing something pretty evident, but, so far, I have proved that $\pi(x)\geqslant\log{\lfloor x\rfloor}/(2\log2)$ using a method Paul Erdős used to prove that there are infinit...

Take the first $j$ primes $2,3,\dots,p_{j}$ and define $N\left(x\right)=\left|\left\{ n\leq x:\, p\nmid n\,\forall p>p_{j}\right\} \right|$. If we write an $n$ in the form $$n=n_{1}^{2}m$$ with $m$ a squarefree number, we have $$m=2^{a_{1}}3^{a_{2}}\cdots p_{j}^{a_{j}}$$ where $a_{i}\in\left\{ 0,...

Well, here's a way to get a cheap lower bound. Note that any $n≤x$ can be written uniquely as $m\times k^2$ where $m$ is square free. It follows that $$x≤ 2^{\pi(x)}\sqrt x\implies \sqrt x ≤ 2^{\pi(x)}\implies \frac {\log_2(x)}2≤\pi(x)$$ This seems better than your desired bound.

In "A Classical Introduction to Modern Number Theory" by Ireland and Rosen, a very close bound is obtained by completely elementary means. Assum $p_n \le x < p_{n+1}$, where $p_i$ denotes the $i$'th prime. By definition, $\pi(x) = n$. Considers the numbers up to $x$: $\{1,2,\cdots, x \}$. They ...