Induction heating systems and techniques for fused filament metal fabrication

1 . A method of heating a fused filament fabrication extrusion nozzle that is constructed from a nozzle material, and has a length L and an effective radius r, the method comprising operating an induction coil at an induction frequency f chosen such that the nozzle has an induction skin depth s at the induction frequency f such that: a. the nozzle induction skin depth s is less than the effective radius r; and b. the nozzle induction skin depth s is larger than 1/15 of the effective radius r. 2 . The method of claim 1 , wherein the nozzle induction skin depth is less than the nozzle length L. 3 . The method of claim 1 , the nozzle comprising: a. an annular outer body having an outer body outer effective radius equal to the effective radius r; and b. an inner tube. 4 . The method of claim 1 , the nozzle comprising a nozzle material comprising graphite. 5 . The method of claim 4 , further comprising providing a metal containing multi-phase build material into the nozzle. 6 . The method of claim 1 , further comprising providing the induction coil substantially surrounding the nozzle, the coil having an axial extent that is less than the nozzle length L. 7 . The method of claim 1 , further comprising providing a metal containing multi phase (MCMP) build material into the nozzle, the nozzle comprising a nozzle material that has a higher performance index than that of the build material. 8 . A fused filament fabrication extrusion nozzle for use with an induction heating coil, which nozzle has a length L and an effective radius r, the nozzle comprising a material, such that, when the induction coil is driven at an induction frequency f, the nozzle has an induction skin depth s that: a. is less than the effective radius r; and b. is larger than 1/15 of the effective radius r. 9 . The nozzle of claim 8 , wherein the nozzle induction skin depth is less than the nozzle length L. 10 . The nozzle of claim 8 , wherein the nozzle material comprises graphite. 11 . The nozzle of claim 8 , further comprising an induction heating coil. 12 . The nozzle of claim 8 , further comprising an induction coil having an inner radius, the inner radius of the induction coil being no greater than 1.4 times the nozzle body effective radius. 13 . The nozzle of claim 12 , wherein the induction coil has an axial extent that is less than the nozzle length L. 14 . A printing assembly comprising: a. a nozzle, having a length L and an effective radius r, the nozzle comprising a material; and b. an induction heating coil, the coil being operable at an induction frequency f, such that, due to the nozzle material, at the induction frequency f, the nozzle has an induction skin depth s such that: i. the nozzle induction skin depth s is less than the effective radius r; and ii. the nozzle induction skin depth s is larger than 1/15 of the effective radius r. 15 . The printing assembly of claim 14 , wherein the nozzle induction skin depth is less than the nozzle length L. 16 . The printing assembly of claim 14 , the nozzle further comprising: a. an annular outer body having an inner radius and a thickness, and an outer body outer effective radius equal to the effective radius r; and b. an inner tube. 17 . The printing assembly of claim 16 , wherein the inner tube comprises a component that is separable from the annular outer body. 18 . The printing assembly of claim 14 , the nozzle comprising: a. a body, comprising a plurality of annular portions; b. at least one of the annular portions comprising a bore, and being a first grade of graphite; and c. at least one of the annular portions comprising a second, different grade of graphite. 19 . The printing assembly of claim 14 , wherein the induction coil has an inner radius that is no greater than 1.4 times the effective radius of the nozzle body. 20 . The printing assembly of claim 14 , wherein the induction coil has an axial extent that is less than L. 21 - 31 . (canceled)