In situ synthesis, densification and shaping of non-oxide ceramics by vacuum additive manufacturing technologies

1 . A vacuum additive manufacturing process for the production of complex shape non-oxide ceramics and ceramics matrix composites with ceramic reinforcements, the process performing in a single step the in situ synthesis, controlled densification and shaping of non-oxide ceramics as mono-phase like SiC or multi-phase like complex ceramic composite materials, said process consisting in one-step reaction of powdered, electrically conductive, metallic particles with powdered non-metallic particles in a production chamber, wherein the thermal energy is supplied by one or more energy sources, a powder bed is progressively deposited and the energy source is focused on said powder bed, generating heat and selectively melting said powdered metallic and non-metallic particles following 3D model data to simultaneously shaping and consolidating the desired component. 2 . The vacuum additive manufacturing process according to claim 1 applied to the production of high performance non-oxide ceramic parts, and to the generation of in situ non-oxide ceramics reinforcement dispersed in oxide matrices. 3 . The vacuum additive manufacturing process according to claim 1 , wherein the single step process comprises the following procedure within the production chamber for simultaneously shaping and consolidating: 1) spreading a thin layer of metallic and non metallic mixed powders on a building platform by a coater blade; 2) preheating the layer of powder by one or more energy sources; 3) selective melting of the powder by one or more energy source at high energy; 4) turning (of the metallic particles) to the molten phase and reacting with non metallic particles powder; 5) repeating the sequence of steps 1-4 until the complete realization in height of the component according to the CAD design of the ceramic component to be realized. 6) post-processing. 4 . The vacuum additive manufacturing process according to claim 1 , wherein the powder metallic particles are made of Si and the powder non metallic ones are made of graphite, oxide and non-oxide ceramic particles. 5 . The vacuum additive manufacturing process according to claim 4 wherein the particles have mean particle size in the range of 5-300 micrometer. 6 . The vacuum additive manufacturing process according to claim 1 , wherein the metallic and non metallic mixed powders are spread on a building platform by a coater blade forming a layer having thickness higher than the biggest powder particle size and inferior of 200 micrometer. 7 . The vacuum additive manufacturing process according to claim 1 , wherein the vacuum level is guaranteed by a 10 −4 -10 −5 mbar. 8 . The vacuum additive manufacturing process according to claim 1 wherein the homogenization of feedstock materials are achieved through an highly efficient method like gas atomization, wherein graphite or other oxide or non-oxide ceramic particles are mixed as filler with the metallic particles during the solidification phase. 9 . The vacuum additive manufacturing process according to claim 8 wherein the metallic particles having spherical shape and non-metallic particles powders are uniformly mixed together through an highly efficient mixing method, like spray drying technique wherein graphite or other oxide or non-oxide ceramic particles are spheroidized together with the metallic particles. 10 . The vacuum additive manufacturing process according to claim 1 wherein the metallic particles having spherical shape and the non-metallic powders are uniformly mixed through an highly efficient mixing method, as dry mixing in ceramic jars or by a wet-based technique wherein at first non-metallic particles sheets are added into a liquid dispersant and dispersed using mechanical stirring or ultrasonication, thereby obtaining a suspension, thereafter, the metallic particles powder is inserted into the suspension and stirred by either mechanical stirring or ultrasonication and in the end, said suspension is placed into a drying oven to vaporize said liquid dispersant and obtain the mixture of metal and non-metallic powder ready for additive manufacturing processing. 11 . The vacuum additive manufacturing process according to claim 3 wherein the post-processing step is performed by thermal treatment. 12 . A porous or fully dense non-oxide ceramics component with an high level of geometrical complexity obtainable by the single step vacuum additive manufacturing process of claim 1 , the porous or fully dense non-oxide ceramics component having strictly controlled nano-micro-macrostructure features in terms of grain size, ranging from 50 nm to 5000 micron, grain shape, from equiaxed to columnar, phase distribution, grain boundary purity, full density or porosities lies in the range of 10-90%. 13 . The vacuum additive manufacturing process for the production of the complex shape non-oxide ceramics according to claim 3 wherein the ceramic components with microstructure and texture differentiated and optimized for different zones of the part can be obtained modulating the high energy source. 14 . The vacuum additive manufacturing process of claim 1 , wherein the one or more energy sources is laser or electron beam. 15 . The vacuum additive manufacturing process of claim 2 , wherein the high performance non-oxide ceramic parts are selected from a group including components in pure silicon carbide, silicon nitride, boron carbide and silicides like MoSi 2 and NbSi 2 and related composites. 16 . The vacuum additive manufacturing process of claim 8 , wherein the particles mixed as filler with the metallic particles comprises Si powder. 17 . The vacuum additive manufacturing process of claim 9 , wherein the particles spheroidized together with the metallic particles comprises Si powder. 18 . The vacuum additive manufacturing process according to claim 2 , wherein the single step process comprises the following procedure within the production chamber for simultaneously shaping and consolidating: 1) spreading a thin layer of metallic and non metallic mixed powders on a building platform by a coater blade; 2) preheating the layer of powder by one or more energy sources; 3) selective melting of the powder by one or more energy source at high energy; 4) turning (of the metallic particles) to the molten phase and reacting with non metallic particles powder; 5) repeating the sequence of steps 1-4 until the complete realization in height of the component according to the CAD design of the ceramic component to be realized. 6) post-processing. 19 . The vacuum additive manufacturing process according to claim 2 , wherein the powder metallic particles are made of Si and the powder non metallic ones are made of graphite, oxide and non-oxide ceramic particles. 20 . The vacuum additive manufacturing process according to claim 2 , wherein the metallic and non metallic mixed powders are spread on a building platform by a coater blade forming a layer having thickness higher than the biggest powder particle size and inferior of 200 micrometer.