Thanks for all the answers and sorry about a silly question. I have also figured out that it can be proved using the usual complete metric on the usual (countable product) Hilbert cube and finite $\epsilon$-nets.

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**Update.** Here is a "meta-proof" (i do not construct $\epsilon$-nets in details).

Let $X = [0,1]\times[0,\frac{1}{2}]\times[0,\frac{1}{3}]\times\dotsb$ be a Hilbert cube endowed with its $\ell_2$ metric.
For every $k$, let $N_k$ be a "well chosen" $\frac{1}{2^k}$-net for $X$.

Let $\mathcal U$ be a given family of open sets such that no finite subfamily of $\mathcal U$ covers $X$.
Then let $S_k$ be the set of those elements of $N_k$ which are within the distance of $\frac{1}{2^k}$ from the compliment of any finite union of elements of $\mathcal U$.
Each $S_k$ is nonempty.
For all $m$ and $n$, the distance from any point of $S_m$ to the set $S_n$ is at most $\frac{1}{2^m}+\frac{1}{2^n}$.

Take "the first" $x_1\in S_1$, then "the first" $x_2\in S_2$ that is within the distance of $\frac{3}{4}$ from $x_1$, then "the first" $x_3\in S_3$ that is within the distance of $\frac{3}{8}$ from $x_2$, and so forth.
The obtained sequence $\lbrace x_k \rbrace$ is Cauchy.
Its limit is not in any element of $\mathcal U$.