System and method for three-dimensional printing of fiber reinforced thermoplastics with multi-axial reinforcement

What is claimed is: 1. A device for three-dimensional (3D) printing of a fiber reinforced thermoplastic (FRTP) material with multi-axial reinforcements, the device comprising: an extrusion nozzle system for 3D printing a braided FRTP structure within an object assembly area of a three-dimensional printer, the extrusion nozzle system including: an extrusion nozzle comprising a first sub-extruder and a second sub-extruder each having a respective channel and being configured to receive a filament material and discharge a respective FRTP strand from an outlet of the extrusion nozzle, and one or more rotation mechanisms configured to rotate the extrusion nozzle about a rotational axis and configured to rotate each of the first and second sub-extruders individually about a respective rotational axis and thereby 3D printing the braided FRTP structure; and an extrusion needle system for reinforcing the braided FRTP structure in a z-axis direction, the extrusion needle system including: an extrusion needle having a needle point, a hollow interior channel and an opening provided along a length of the needle, wherein the needle is configured to receive a filament material within the needle channel and discharge the filament material therethrough, and a needle position control mechanism for adjusting a height of the needle in the z-axis direction to penetrate the needle into the braided FRTP structure such that the filament material is discharged from the opening at a prescribed depth within the braided structure. 2. The device of claim 1 , wherein the one or more rotation mechanisms include a first rotational mechanism comprising a major rotating gear for rotating the nozzle and a second rotational mechanism comprising two minor rotating gears for rotating the first and second sub-extruders within the nozzle. 3. The device of claim 2 , wherein the second rotational mechanism counter-rotates the first and second sub-extruders. 4. The device of claim 1 , wherein the extrusion needle system further comprises a rotation mechanism configured to rotate the extrusion needle about a rotational axis. 5. The device of claim 1 , wherein the first and second sub-extruders discharge a respective strand of FRTP material through respective outlets and are rotated about a central axis of the respective channels. 6. The device of claim 1 , wherein the channels of the first and second sub-extruders converge at the outlet and wherein the rotational axis of the nozzle is a central axis of the outlet and wherein the first and second sub-extruders rotate about a central axis of the respective channels. 7. The device of claim 1 , wherein the first sub-extruder is configured to receive a first filament material, the second sub-extruder is configured to receive a second filament material and the extrusion needle is configured to receive a third filament material, and wherein one or more of the first, second and third filament materials comprise continuous filaments of pre-impregnated FRTP material. 8. A system for additive manufacturing of an object from fiber reinforced thermoplastic (FRTP) material having multi-axial reinforcements, the system comprising: a platform defining an object assembly area; a print head comprising: an extrusion nozzle system for 3D printing a braided FRTP material structure within the object assembly area, the extrusion nozzle system including: an extrusion nozzle comprising a first sub-extruder and a second sub-extruder each having a respective channel and being configured to receive a filament material and discharge a respective FRTP strand from an outlet of the extrusion nozzle, and one or more rotation mechanisms configured to rotate the extrusion nozzle about a rotational axis and configured to rotate each of the first and second sub-extruders individually about a respective rotational axis; and an extrusion needle system for reinforcing the braided FRTP structure in a z-axis direction, the extrusion needle system including: an extrusion needle having a needle point, a hollow interior channel and an opening provided along a length of the needle, wherein the needle is configured to receive a filament material within the needle channel and discharge the filament material therethrough, and a needle position control mechanism for adjusting a height of the needle in the z-axis direction to penetrate the needle into the braided FRTP structure such that the filament material is discharged from the opening at a prescribed depth within the braided structure; a position control mechanism configured to controllably position the print head within the object assembly area in an x-y direction; and a control computer including a processor and a memory, wherein the control computer is configured to control operation of the print-head and the position control mechanism according to an instruction set stored in the memory and executable by the processor. 9. The system of claim 8 , wherein the instruction set includes a design file for the object and configures the control computer to produce the object in accordance with the design file by: controllably moving the print head within the object assembly area, causing the extrusion nozzle system to controllably extrude respective FRTP material strands from the first and second sub-extruders while controllably rotating the extrusion nozzle and each of the first and second sub-extruders using the one or more rotation mechanisms, and selectively providing z-axis reinforcements at prescribed locations within a volume of the braided FRTP material using the extrusion needle system. 10. The system of claim 9 , wherein the control computer is configured to selectively control a rate at which the first and second sub-extruders extrude the respective FRTP material strands. 11. The system of claim 9 , wherein the control computer is configured to selectively control a rate at which the first and second sub-extruders rotate during extrusion of the respective FRTP material strands. 12. The system of claim 8 , wherein the control computer is configured to selectively provide the z-axis reinforcements by, at prescribed locations in the x-y direction, penetrating the needle into the braided FRTP structure to a prescribed depth and discharging filament material from the opening of the needle. 13. The system of claim 8 , wherein the one or more rotation mechanisms include a first rotational mechanism comprising a major rotating gear for rotating the nozzle and a second rotational mechanism comprising two minor rotating gears for rotating the first and second sub-extruders within the nozzle. 14. The system of claim 13 , wherein the second rotational mechanism counter-rotates the first and second sub-extruders. 15. The system of claim 8 , wherein the extrusion needle system further comprises a rotation mechanism configured to rotate the extrusion needle about a rotational axis. 16. The system of claim 8 , wherein the first and second sub-extruders discharge a respective strand of FRTP material through respective outlets and are rotated about a central axis of the respective channels. 17. The system of claim 8 , wherein the channels of the first and second sub-extruders converge at the outlet and wherein the rotational axis of the nozzle is a central axis of the outlet and wherein the first and second sub-extruders rotate about a central axis of the respective channels. 18. The system of claim 8 , wherein the first sub-extruder is configured to receive a first filament material, the second sub-extruder is configured to receive a seco