The quantity $\lambda(P)|P|$ is scale invariant since $\lambda(tP)=\frac{1}{t^2}\lambda(P)$. Therefore, its derivative with perturbations preserving the regularity of the polygon equals zero. The derivative of the eigenvalue can be found using the shape derivative formula: $$\lambda'(P)(\theta) = -\int_{\partial P} (\partial_n u)^2 (\theta \cdot n)$$ It is immediate to notice that a vector field which corresponds to dilations verifies $\theta \cdot n = 1$. In the same case the shape derivative of the area gives $$ |P|'(\theta) = \int_{\partial P} \theta \cdot n.$$ This gives $\lambda(P)|P|'=-|P|\lambda'(P)(\theta) = |P|\int_{\partial P}(\partial_n u)^2$. In the end: $\lambda(P)=|P| \frac{1}{|\partial P|}\int_{\partial P}(\partial_n u)^2$. If my reasoning is correct, this is an **equality** (always better than an inequality :) ) Therefore the inequality the OP wants goes in the other sense (the average is smaller than the $L^\infty$ norm).