Convection Effects and Optimal Insulation: Modelling and Analysis
Abstract
In this paper, we study an insulation problem that seeks to determine the optimal distribution of a given amount m>0 of insulating material coating an insulated boundary part I⊂eq ∂ of a thermally conducting body ⊂eq Rd, d∈ N, subject to convective heat transfer. The `thickness' of the insulating layer I⊂eq Rd is given locally via d, where >0 denotes the (arbitrarily small) conductivity and d I [0,+∞) the (to be determined) distribution of the insulating material. Then, the physical process is modelled by the stationary heat equation in the insulated thermally conducting body I:= I with Robin-type boundary conditions on the interacting insulation boundary I⊂eq ∂I (reflecting convective heat transfer between the thermally conducting body and its surrounding medium) as well as Dirichlet and Neumann boundary conditions at the remaining boundary parts, i.e., ∂I I. More precisely, we establish (L2(Rd))-convergence of the heat loss formulation (as 0+), in the case that the thermally conducting body is a bounded Lipschitz domain having a C1,1-regular or piece-wise flat insulated boundary I.
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