Reactors and methods for processes involving partial oxidation reactions

We claim: 1 . A reactor suitable for conducting a partial oxidative reaction, wherein the reactor comprises a vessel comprising a process channel and a composite catalyst structure, wherein the composite catalyst structure comprises a catalyst layer, comprising a substrate and a catalyst, and wherein at least a portion of the composite catalyst structure has a porous heat transfer structure configured to quench free radicals and prevent explosions or propagation of a fire during the partial oxidative reaction. 2 . The reactor of claim 1 , further comprising a flow distribution layer on top of the composite catalyst structure, wherein the vessel further comprises an inlet, and wherein the inlet is located above the flow distribution layer. 3 . The reactor of claim 1 , wherein the composite catalyst structure further comprises a barrier layer configured to prevent the catalyst from migrating out of the catalyst bed, a heat spreader layer configured to dissipate heat, or both. 4 . The reactor of claim 3 , wherein the heat spreader layer has a thermal conductivity of at least 10 W/m-K, optionally greater than 45 W/m-K, 65 W/m-K, or 100 W/m-K. 5 . The reactor of claim 4 , wherein the heat spreader layer comprises a metal or a metal alloy, optionally wherein the heat spreader layer contains two layers, where the first layer is a flame blocking layer that contains a higher metal fraction than the metal fraction of the second layer, wherein the second layer is a quenching layer. 6 . The reactor of claim 4 , wherein the flame blocking layer and quenching layer contain the same metal or metal alloy, and wherein the flame blocking layer and quenching layer are sintered to each other. 7 . The reactor of claim 4 , wherein the composite catalyst structure comprises a heat spreader layer, and wherein the heat spreader layer comprises a material selected from the group consisting of a metal screen, metal mesh, metal foam, perforated plate, and microfibrous media. 8 . The reactor of claim 1 , wherein the substrate in the catalyst layer is a sintered metal mesh, a metal honeycomb, or a metal monolith, optionally with a thermal conductivity of 10 W/m-k or greater. 9 . The reactor of claim 1 , wherein the amount of catalyst in the catalyst layer ranges from about 1 to about 25 vol %, optionally from about 5-15 vol %. 10 . The reactor of claim 1 , wherein the catalyst is in the form of catalyst particles and the catalyst particles are dispersed in the substrate. 11 . The reactor of claim 10 , wherein the composite catalyst structure further comprises a barrier layer, wherein the barrier layer is located beneath the catalyst layer, and wherein the barrier layer has a pore size that is smaller than the size of catalyst particles. 12 . The reactor of claim 11 , wherein the barrier layer comprises a mesh structure, metal microfibrous media, or ceramic microfibrous media, optionally wherein the mesh structure is in the form of a screen. 13 . The reactor of claim 11 , wherein the composite catalyst structure further comprises a heat spreader layer, and wherein each of the barrier layer and heat spreader layer is formed from a metal or metal alloy, and wherein the heat spreader layer and barrier layer are sintered to each other. 14 . The reactor of claim 1 , wherein the vessel comprises two or more composite catalyst structures in the form of a stack, and wherein the composite catalyst structures are the same or different. 15 . The reactor of claim 14 , wherein the vessel further comprises a mechanical supportive structure, and wherein each of the composite catalyst structures is on or surrounds the mechanical supportive structure. 16 . The reactor of claim 15 , wherein the vessel further comprises a reactant fluid inlet and a product fluid outlet. 17 . The reactor of claim 16 , further comprising an oxygen inlet, optionally at least one inlet combines with the reactant fluid inlet. 18 . A reactor suitable for conducting a partial oxidative reaction, wherein the reactor comprises a vessel comprising a composite catalyst structure, comprising a catalyst layer, and optionally a barrier layer configured to prevent the catalyst from migrating out of the catalyst bed, a heat spreader layer configured to dissipate heat, or both. 19 . A method for conducting a partial oxidative reaction, comprising flowing a reactant fluid through the reactor of claim 1 . 20 . The method of claim 19 , wherein the reactant fluid comprises organic compounds and oxygen. 21 . The method of claim 19 , wherein the reactor operates at a temperature ranging from 200° C. to 950° C. 22 . The method of claim 19 , wherein the amount of oxygen that can safely be fed to the reactor without causing a fire or explosion is greater than the lower explosion limit (LEL) for the partial oxidative reaction.