Multilayer fiber reinforcement design for 3D printing

What is claimed is: 1. A machine implemented method for generating three-dimensional toolpath signals for controlling a three dimensional printer, the method comprising: receiving a three-dimensional geometry sliced into shells or layers; generating, for each shell or layer of a set of the shells or layers defining a portion of a 3D printed part, first isotropic fill toolpath signals defining motion of an isotropic solidifying head to solidify a substantially isotropic fill material along a first isotropic fill toolpath; generating, for each shell or layer of an anisotropic fill subset of the set of shells or layers defining the portion of the 3D printed part, first anisotropic fill toolpath signals defining motion of an anisotropic solidifying head to orient an anisotropic characteristic of a substantially anisotropic fill material along a first anisotropic fill toolpath; receiving a selection, from among the set of shells or layers defining the portion of the 3D printed part, of an editing subset of shells or layers, the editing subset including at least part of the anisotropic fill subset; generating, for each shell or layer of the editing subset, at least one of second isotropic fill toolpath signals and second anisotropic fill toolpath signals, the second isotropic fill toolpath signals defining motion of the isotropic solidifying head to solidify the substantially isotropic fill material along a second isotropic fill toolpath different from the first isotropic fill toolpath, and the second anisotropic fill toolpath signals defining motion of the anisotropic solidifying head to orient the anisotropic characteristic of the substantially anisotropic fill material along a second anisotropic fill toolpath different from the first anisotropic fill toolpath; and transmitting motion command signals corresponding to at least one of the first and second isotropic fill toolpath signals and at least one of the first and second anisotropic fill toolpath signals to the three dimensional printer, the motion command signals configured to control the three dimensional printer to print the 3D printed part by: solidifying, for each shell or layer of the set of shells or layers defining the portion of the 3D printed part, the substantially isotropic fill material along at least one of the first isotropic fill toolpath and the second isotropic fill toolpath; and orienting, for each shell or layer of the anisotropic fill subset, the anisotropic characteristic of the substantially anisotropic fill material along at least one of the first anisotropic fill toolpath and the second anisotropic fill toolpath such that each shell or layer of the anisotropic fill subset exhibits the anisotropic characteristic in at least one specific direction corresponding to a trajectory of the at least one of the first and second anisotropic fill toolpaths. 2. The machine implemented method of claim 1 , further comprising: generating, for each shell or layer of the editing subset, both the second isotropic fill toolpath signals and the second anisotropic fill toolpath signals. 3. The machine implemented method of claim 1 , wherein generating the first isotropic tool path signals comprises applying a first generation rule defining the first isotropic fill toolpath signals for controlling the isotropic solidifying head to solidify the substantially isotropic fill material along the first isotropic fill toolpath; and wherein generating the first anisotropic tool path signals comprises applying a second generation rule defining the first anisotropic fill toolpath signals for controlling the anisotropic solidifying head to orient the substantially anisotropic fill material along the first anisotropic tool path, wherein the first and second generation rules govern mutually exclusive regions within each shell or layer of the set of shells or layers defining a portion of the 3D printed part. 4. The machine implemented method of claim 1 , wherein generating the first isotropic tool path signals comprises applying a first generation rule defining the first isotropic fill toolpath signals for controlling the isotropic solidifying head to solidify the substantially isotropic fill material along the first isotropic fill toolpath; and wherein generating the first anisotropic tool path signals comprises applying a second generation rule defining the first anisotropic fill toolpath signals for controlling the anisotropic solidifying head to orient the substantially anisotropic fill material along the first anisotropic tool path, wherein a priority is defined between the first and second generation rules to determine, when the first and second generation rules govern conflicting regions within a shell or layer of the set of shells or layers defining a portion of the 3D printed part, which of the first or second generation rule shall apply. 5. The machine implemented method of claim 1 , wherein, within a sequential set of three or more parallel shells or layers, generating the first isotropic fill tool path signals comprises applying a wall generation rule defining the first isotropic fill toolpath signals for controlling the isotropic solidifying head to solidify the substantially isotropic fill material as a contour wall of the part; and wherein, within the sequential set of three or more parallel shells or layers, generating the first or second anisotropic fill toolpath signals comprises applying a quasi-isotropic generation rule defining the first or second anisotropic fill toolpath signals for controlling the anisotropic solidifying head to orient the substantially anisotropic fill material as a quasi-isotropic set of the first or second anisotropic fill toolpaths forming a laminate among the three or more shells or layers and having a partially isotropic in-shell behavior among the three or more shells or layers. 6. The machine implemented method of claim 5 , wherein, within the sequential set of three or more parallel shells or layers, generating the second isotropic fill tool path signals comprises applying a volume infill generation rule defining the second isotropic fill toolpath signals for controlling the isotropic solidifying head to solidify the substantially isotropic fill material as a volume infill of the part, and wherein, within the sequential set of three or more parallel shells or layers, generating the first or second anisotropic fill toolpath signals comprises applying an outer concentric generation rule defining the first or second anisotropic fill toolpath signals for controlling the anisotropic solidifying head to orient the substantially anisotropic fill material as outer concentric fill toolpaths located adjacent and parallel to an outer contour and/or an outer perimeter of the 3D printed part and at least partially radially outward from a centroid of the 3D printed part. 7. The machine implemented method of claim 5 , wherein, within the sequential set of three or more parallel shells or layers, generating the first or second anisotropic fill toolpath signals comprises applying an inner concentric generation rule defining the first or second anisotropic fill toolpath signals for controlling the anisotropic solidifying head to orient the substantially anisotropic fill material as inner concentric fill tool paths located adjacent and parallel to an inner contour and/or through-hole perimeters of the part. 8. A machine implemented method for generating three-dimensional toolpath signals for controlling a three dimensional printer, the method comprising: receiving a three-dimensional geometry sliced into shells or layers; generating, for each shell or layer of a set of the shells or layers defining a portion of a 3D printed part, isotropic fill toolpath signals defining motio