Process to make a ceramic filter for metal casting

What is claimed is: 1 . A ceramic foam filter, comprising: a filter body having portions forming multiple tortuous path channels through the filter body to filter a molten liquid, the molten liquid having multiple inclusions; an upstream end of the filter body configured to receive the molten liquid; and the multiple tortuous path channels being sized to trap a predominant portion of multiple oxides within the molten liquid as trapped oxides within the filter body. 2 . The ceramic foam filter of claim 1 , further including a melt treatment material incorporated within the multiple tortuous path channels. 3 . The ceramic foam filter of claim 2 , having the melt treatment material coated onto walls of the tortuous path channels. 4 . The ceramic foam filter of claim 3 , further including a melt treatment portion of the melt treatment material, wherein as the molten material traverses the multiple tortuous path channels the melt treatment portion is captured by and incorporated into the molten material. 5 . The ceramic foam filter of claim 3 , wherein the melt treatment material includes at least one of a grain refiner, a eutectic modifier and a chemical fluxing. 6 . The ceramic foam filter of claim 5 , wherein the grain refiner includes at least one of a titanium-boride material, a boride material, a lanthanum-boride material, a niobium material, a niobium-boride material, a titanium-magnesium-cerium material, a lanthanum-cerium material. 7 . The ceramic foam filter of claim 5 , wherein the eutectic modifier includes a silicone modifier including one or more of a strontium (Sr) material, a sodium (Na) material, an antimony (Sb) material, a phosphorus (P) material, a calcium (Ca) material, a barium (Ba) material, an yttrium (Y) material, a europium (Eu) material, an ytterbium (Yb) material, a lanthanum (La) material, a cerium (Ce) material, a praseodymium (Pr) material, and a neodymium (Nd) material. 8 . The ceramic foam filter of claim 5 , wherein the chemical fluxing includes at least one of an oxide film remover including one of a fluorine containing material and a fluorine-free material. 9 . The ceramic foam filter of claim 1 , wherein sequential ones of the multiple tortuous path channels are oppositely facing, individual ones of the multiple tortuous path channels include multiple rounded slots. 10 . The ceramic foam filter of claim 1 , wherein sequential ones of the multiple tortuous path channels are oppositely facing, individual ones of the multiple tortuous path channels include multiple rectangular-shaped slots. 11 . A ceramic foam filter system, comprising: a filter body having multiple tortuous path channels through the filter body to filter a molten liquid; a filter holder configuration defining a canister in a runner passage receiving the filter body; an upstream end of the filter body receiving the molten liquid, the molten liquid having multiple inclusions, a predominant portion of the inclusions being larger than the multiple tortuous path channels and being trapped against the upstream end of the filter body; the multiple tortuous path channels sized to trap a predominant portion of multiple oxides within the molten liquid as trapped oxides within the filter body; and a filtered molten material having the multiple inclusions and the multiple oxides removed is directed from the multiple tortuous path channels as a discharge flow to exit at a downstream end of the filter body. 12 . The ceramic foam filter system of claim 11 , further including a mold creating a casting defining an aluminum cylinder head of an automobile vehicle. 13 . The ceramic foam filter system of claim 12 , further including a feed portion having a gating system connected to the mold. 14 . The ceramic foam filter system of claim 13 , including a pour basin into which the molten liquid is poured, the molten liquid flowing downward under gravity out of the pour basin through a sprue in a downward direction and pass through the filter holder configuration defining a canister in a runner passage including the filter body. 15 . The ceramic foam filter system of claim 14 , wherein the molten liquid exits the filter body as the filtered molten material and is directed into a horizontally oriented runner, and from the runner the filtered molten material is split and flows through multiple gates into the mold. 16 . The ceramic foam filter system of claim 11 , including a melt treatment material incorporated within the multiple tortuous path channels by an additive manufacturing process, wherein as the filtered molten material traverses the multiple tortuous path channels a portion of the melt treatment material is captured by and incorporated into the filtered molten material as a melt treatment portion. 17 . The ceramic foam filter system of claim 16 , wherein the melt treatment material includes at least one of a grain refiner, a eutectic modifier and a chemical fluxing. 18 . A method for making a ceramic foam filter, comprising: combining ceramic powders and at least one binder in a combining operation; designing a ceramic foam filter cell geometry of a filter body; printing the filter body using the ceramic powders and the binder from the combining operation using an additive manufacturing operation; and sintering the filter body at a sintering temperature above an anticipated temperature of a molten material to be filtered by the filter body. 19 . The method of claim 18 , further including applying a cell surface treatment to the filter body. 20 . The method of claim 19 , further including assembling the filter body into a filter holder configuration defining a canister in a runner passage.