Let $U_1$ and $U_2$ be two bounded domains in $\mathbb{R}^n$ such that $U_1 \Subset U_2$. Note that we don't assume $\partial U_i$ to be smooth
or Lipschitz, they may be very bad.

Denote $U=U_2 \backslash \bar{U_1}$, consider the Dirichlet problem
\begin{equation}
\Delta u=0 \text{ on }U,
\end{equation}
\begin{equation}
u=1 \text{ on } \partial U_1, \quad u=0 \text{ on } \partial U_2.
\end{equation}
Let
$$
U^r_1=\{x \in \mathbb{R}^n: d(x,U_1)\leqslant r\},
$$
$$
g_r=\max\{ 1-\frac{d(x,U_1)}{r}, 0\},
$$
an extension from $1,0$ function to a Lipschitz function defined on $\bar{U}$. By the standard argument, we can prove that there exists a
function $u \in W^{1,2}(U)$ satisfying the above boundary value problem and $u-g_r \in W^{1,2}_0(U)$. For different $r$ and different extensions, the solutions remain
unchanged, i.e. the solution is unique.

Now suppose $U_2 \Subset U_3$, consider the Dirichlet problem
\begin{equation}
\Delta v=0 \text{ on } U_3 \backslash \bar{U}_1,
\end{equation}
\begin{equation}
v=1 \text{ on } \partial U_1, \quad v=0 \text{ on } \partial U_3.
\end{equation}
**Do we have $v\geqslant u$ on $U$?**

If $\partial U_i$ are smooth for $i=1,2,3$, then $u\in C(\bar{U})$, $v\in C(\bar{U_3} \backslash U_1)$. $u, v|_{\partial U_1}=1$, $u|_{\partial U_2}=0$ and
$v|_{\partial U_3}=0$. Then $v-u \geqslant 0$ on $\partial U_1$ and $\partial U_2$, by the maximum principle, we have $v\geqslant u$. However, the boundaries we considered here are not smooth.