Direct write dispensing apparatus and method

Having thus described various embodiments of the invention, what is claimed as new and desired to be protected by Letters Patent includes the following: 1. A method of direct write dispensing an electronic twisted pair on a substrate, the method comprising the steps of: opening a first inner nozzle; dispensing conductive material via the first inner nozzle so as to form a first conductive core; opening a second inner nozzle independently from the first inner nozzle, the second inner nozzle being spaced from the first inner nozzle; dispensing conductive material via the second inner nozzle independently from dispensing the conductive material via the first inner nozzle so as to form a second conductive core spaced from the first conductive core independently from the first conductive core; opening a first peripheral nozzle independently from the first inner nozzle and second inner nozzle; dispensing non-conductive material via the first peripheral nozzle independently from dispensing the conductive material via the first inner nozzle and second inner nozzle so as to form a first non-conductive casing surrounding at least the first conductive core independently from the first conductive core and second conductive core; and rotating the first inner nozzle, the second inner nozzle, and the first peripheral nozzle near the substrate about a longitudinal axis independently from dispensing the conductive material and non-conductive material so that the first conductive core and the second conductive core cooperatively form double helix traces on the substrate. 2. The method of claim 1 , wherein the first peripheral nozzle extends around the first inner nozzle and the second inner nozzle such that the first non-conductive casing surrounds the first conductive core and the second conductive core. 3. The method of claim 2 , wherein the first inner nozzle and the second inner nozzle are circular. 4. The method of claim 3 , wherein a portion of the peripheral nozzle is concentric around the first inner nozzle and another portion of the peripheral nozzle is concentric around the second inner nozzle. 5. The method of claim 1 , further comprising the step of dispensing non-conductive material via a second peripheral nozzle so as to form a second non-conductive casing surrounding the second conductive core such that the first non-conductive casing contacts the second non-conductive casing, the step of rotating the first inner nozzle, the second inner nozzle, and the first peripheral nozzle includes rotating the second peripheral nozzle about the longitudinal axis. 6. The method of claim 5 , wherein the first inner nozzle, the second inner nozzle, the first peripheral nozzle, and the second peripheral nozzle are circular, the first peripheral nozzle being concentric around the first inner nozzle and the second peripheral nozzle being concentric around the second peripheral nozzle. 7. The method of claim 1 , wherein the longitudinal axis is halfway between the first inner nozzle and the second inner nozzle. 8. The method of claim 1 , wherein the first inner nozzle, second inner nozzle, and first peripheral nozzle dispense material along axes extending parallel to the longitudinal axis of rotation. 9. A method of direct write dispensing an electronic twisted pair on a substrate, the method comprising the steps of: opening a first inner nozzle; dispensing conductive material via the first inner nozzle so as to form a first conductive core; opening a second inner nozzle independently from the first inner nozzle, the second inner nozzle being spaced from the first inner nozzle; dispensing conductive material via the second inner nozzle independently from dispensing the conductive material via the first inner nozzle so as to form a second conductive core spaced from the first conductive core independently from the first conductive core; opening a peripheral nozzle independently from the first inner nozzle and second inner nozzle; dispensing non-conductive material via the peripheral nozzle independently from dispensing the conductive material via the first inner nozzle and second inner nozzle so as to form a non-conductive casing surrounding the first conductive core and the second conductive core independently from the first conductive core and second conductive core, a portion of the peripheral nozzle being concentric with the first inner nozzle and another portion of the peripheral nozzle being concentric with the second inner nozzle; and rotating the first inner nozzle, the second inner nozzle, and the first peripheral nozzle near the substrate about a longitudinal axis independently from dispensing the conductive material and non-conductive material so that the first conductive core and the second conductive core cooperatively form double helix traces on the substrate. 10. The method of claim 9 , wherein the first inner nozzle, second inner nozzle, and peripheral nozzle dispense material along axes extending parallel to the longitudinal axis of rotation.