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In this paper, we rewrite the minimal-connected-component (MCC) model in 2-D meshes in a fully-distributed manner without using global information so that not only can the existence of a Manhattan-distance-path be ensured at the source, but also such a path can be formed by routing-decisions made at intermediate nodes along the path. We propose the MCC model in 3-D meshes, and extend the corresponding routing in 2-D meshes to 3-D meshes. We consider the positions of source & destination when the new faulty components are constructed. Specifically, all faulty nodes will be contained in some disjoint fault-components, and a healthy node will be included in a faulty component only if using it in the routing will definitely cause a non-minimal routing-path. A distributed process is provided to collect & distribute MCC information to a limited number of nodes along so-called boundaries. Moreover, a sufficient & necessary condition is provided for the existence of a Manhattan-distance-path in the presence of our faulty components. As a result, only the routing having a Manhattan-distance-path will be activated at the source, and its success can be guaranteed by using the information of boundary in routing-decisions at the intermediate nodes. The results of our Monte-Carlo-estimate show substantial improvement of the new fault-information model in the percentage of successful Manhattan-routing conducted in 3-D meshes.