Apparatus and method for air particle capture in a gas turbine engine

What is claimed is: 1 . A combustor for a gas turbine engine, comprising: a heat shield panel attached to a combustor liner, the combustor liner having a plurality of primary apertures extending through the combustor liner and the heat shield panel having a plurality of heat shield apertures extending therethrough; an intermediary layer located between the combustor liner and the heat shield panel, the intermediary layer being spaced from the combustor liner and the intermediary layer being spaced from the heat shield panel, the intermediary layer including a plurality of secondary apertures extending through the intermediary layer, the plurality of heat shield apertures, the plurality of primary apertures and the plurality of secondary apertures each being in fluid communication with each other; and a plurality of solid pins extending upwardly and away from a surface of the intermediary layer towards a surface of the combustor liner, wherein particulate deposition occurs adjacent to the plurality of solid pins as airflow is redirected around the plurality of solid pins to flow through the plurality of secondary apertures in the intermediary layer. 2 . The combustor as in claim 1 , wherein the heat shield panel and the intermediary layer are removably mounted to the combustor liner by one or more attachment mechanisms. 3 . The combustor as in claim 2 , wherein the one or more attachment mechanisms are integrally formed with the heat shield panel. 4 . The combustor as in claim 3 , wherein the one or more attachment mechanisms are a bolt that extends from the heat shield panel through the intermediary layer and into a receiving portion or aperture of the combustor liner. 5 . The combustor as in claim 1 , wherein the combustor defines a combustion chamber, the combustion chamber including a combustion area within the combustion chamber and the heat shield panel partially encloses the combustion area within the combustion chamber of the combustor. 6 . The combustor as in claim 1 , wherein the combustor includes an inlet and an outlet through which air may pass. 7 . The combustor as in claim 1 , wherein the plurality of solid pins are arranged in an array on the surface of the intermediary layer. 8 . The combustor as in claim 1 , wherein a gap is located between a top of the plurality of solid pins and the surface of the combustor liner. 9 . The combustor as in claim 8 , wherein the plurality of solid pins are arranged in an array on the surface of the intermediary layer. 10 . A gas turbine engine, comprising: a compressor section; a combustor fluidly connected to the compressor section; a turbine section fluidly connected to the combustor, the combustor comprising: a heat shield panel attached to a combustor liner, the combustor liner having a plurality of primary apertures extending through the combustor liner and the heat shield panel has a plurality of heat shield apertures extending therethrough; an intermediary layer located between the combustor liner and the heat shield panel, the intermediary layer being spaced from the combustor liner and the intermediary layer being spaced from the heat shield panel, the intermediary layer including a plurality of secondary apertures extending through the intermediary layer, the plurality of heat shield apertures, the plurality of primary apertures and the plurality of secondary apertures each being in fluid communication with each other; and a plurality of solid pins extending upwardly and away from a surface of the intermediary layer towards a surface of the combustor liner, wherein particulate deposition occurs adjacent to the plurality of solid pins as airflow is redirected around the plurality of solid pins to flow through the plurality of secondary apertures in the intermediary layer. 11 . The gas turbine engine as in claim 10 , wherein the heat shield panel and the intermediary layer are removably mounted to the combustor liner by one or more attachment mechanisms. 12 . The gas turbine engine as in claim 11 , wherein the one or more attachment mechanisms are integrally formed with the heat shield panel. 13 . The gas turbine engine as in claim 12 , wherein the one or more attachment mechanisms are a bolt that extends from the heat shield panel through the intermediary layer and into a receiving portion or aperture of the combustor liner. 14 . The gas turbine engine as in claim 10 , wherein the combustor defines a combustion chamber, the combustion chamber including a combustion area within the combustion chamber and the heat shield panel partially encloses the combustion area within the combustion chamber of the combustor. 15 . The gas turbine engine as in claim 10 , wherein the combustor includes an inlet and an outlet through which air may pass. 16 . The gas turbine engine as in claim 10 , wherein the plurality of solid pins are arranged in an array on the surface of the intermediary layer. 17 . The gas turbine engine as in claim 10 , wherein a gap is located between a top of the plurality of solid pins and the surface of the combustor liner. 18 . The gas turbine engine as in claim 17 , wherein the plurality of solid pins are arranged in an array on the surface of the intermediary layer. 19 . A method for capturing dirt particles in a combustor of a gas turbine engine, comprising: securing a heat shield panel of the combustor to a combustor liner of the combustor, the combustor liner having a plurality of primary apertures extending through the combustor liner and the heat shield panel having a plurality of heat shield apertures extending therethrough; securing an intermediary layer between the combustor liner and the heat shield panel, the intermediary layer being spaced from the combustor liner and the intermediary layer being spaced from the heat shield panel, the intermediary layer including a plurality of secondary apertures extending through the intermediary layer, the plurality of heat shield apertures, the plurality of primary apertures and the plurality of secondary apertures each being in fluid communication with each other; and capturing dirt particles with a plurality of solid pins extending upwardly and away from a surface of the intermediary layer towards a surface of the combustor liner, wherein particulate deposition occurs adjacent to the plurality of solid pins as airflow is redirected around the plurality of solid pins to flow through the plurality of secondary apertures in the intermediary layer. 20 . The method as in claim 19 , wherein the plurality of solid pins are arranged in an array on the surface of the intermediary layer.