This is an attempt to prove the following:

**Theorem.** Let $X$ be a noetherian scheme, $r\in\mathbb N$, $Z\subseteq X$ a subscheme such that ${\rm codim}_XZ\geq r$, and $\mathcal F$ a coherent $\mathcal O_X$-module such that ${\rm supp}\\,\mathcal F=X$ and  $\mathcal F_x$ is $S_r$ for every $x\in Z$. Then
$$
\mathcal H^i_Z(X,\mathcal F)=0\quad\text{for $i=0,\ldots,r-1$}.
$$

**Proof.** Let $x\in Z$ and notice that we have the following equality of functors:
$$
H^0_x = H^0_x\circ \mathcal H^0_Z
$$
which induces a Grothendieck spectral sequence
$$
E^{p,q}_2= H^p_x \circ \mathcal H^q_Z \Rightarrow H^{p+q}_x.
$$
Now prove the statement using induction on $i$. 

Suppose $\exists\\,\sigma\in\mathcal H^0_Z(X,\mathcal F)$, $\sigma\neq 0$. Let $x\in Z$ be the general point of an irreducible component of ${\rm supp}\\,\sigma$. Then $H^0_x(X, \mathcal H^0_Z(X,\mathcal F))\neq 0$ and hence $H^0_x(X,\mathcal F)\neq 0$. But this contradicts the assumption that $\mathcal F_x$ is $S_r$. 

Now suppose that we already know that 
$$
\mathcal H^i_Z(X,\mathcal F)=0\quad\text{for $i=0,\ldots,k-1$}
$$
for some $k<r$ and assume that $\mathcal H^k_Z(X,\mathcal F)\neq 0$. By the same argument as above we find a point such that $E^{0,k}_2=H^0_x(X,\mathcal H^k_Z(X,\mathcal F))\neq 0$. Since it is an $E^{0,k}$ term there are no differentials (including later pages of the spectral sequence) mapping to this term and all subsequent differentials mapping from this term map to something of the form $E^{p,q}$ with $0\leq q\leq k-1$. However those latter kind are zero by the inductive hypothesis. Therefore this implies that then $H^k_x(X,\mathcal F)=0$ which is again a contradiction to the assumption that $\mathcal F_x$ is $S_r$. **Q.E.D.**