Let $V$ be a vector space of finite dimentional $d$ over a field of prime order $p$.
For what values of $d$ and $p$, one can find $d+1$ (pairwise distinct) hyperplanes (subspaces of dimension $d-1$) $W_1,\dots,W_{d+1}$ such that 
(1) $W_i+(W_{i+1}\cap\cdots \cap W_{d+1})=V$ for all $i\in\{1,\dots,d\}$
(2) $V\not=W_1 \cup \cdots \cup W_{d+1}$?

I somehow believe  the answer (for all values of $d$ and $p$) is negative!!

I would like to know if the question has any corresponding in the language of finite geometry?

The question comes from a problem about certain automorphisms of finite $p$-groups.
Let $G$ be a finite non-abelian $p$-group and let $M_1,\dots,M_s$ be maximal subgroups of $G$ whose set-theoretic union is NOT the whole of $G$.
Take any element $g\not\in M_1 \cup \cdots \cup M_{s}$ and any central element $z$ of order $p$. Then the maps $\theta_i:g\mapsto gz$ and $\theta: m_i \mapsto m_i$ for all $m_i\in M_i$ can be extended to automorphisms of $G$ of order $p$ for each $i\in\{1,\dots,s\}$. If we may further assume that $Z(G)\leq \Phi(G)$, then the subgroup $\Theta:=\langle \theta_1,\dots,\theta_s\rangle$ is elementary abelian.
The question is now as follows: What is the maximal rank (or dimension) of $\Theta$?
The rank, of course, will depend on the choice of $M_i$. The ineteger $d$ in the former question corresponds to the minimal number of generators of $G$. We know that the rank is at least $d$.