Automatic textile winding system with multi-stranded rotatable yarn feed

1 . A system for forming a non-woven, yarn structure for an engineered textile, the system comprising: a jig having a plurality of upstanding pins that collectively circumnavigate a central workspace area; an automatic winding system comprising: a movement mechanism and a winding head coupled with the movement mechanism, the movement mechanism comprising one or more motors that are configured to translate the winding head across the workspace area the winding head comprising: a rotatable base; a plurality of yarn guides arranged in a linear array and extending from the rotatable base; a rotation motor coupled to the rotatable base and configured to selectively rotate the base to alter an orientation of the linear array. 2 . The system of claim 1 , further comprising a winding controller in electrical communication with the one or more motors of the movement mechanism; and wherein the winding controller comprises, or is in digital communication with a digital memory having stored therein instructions that when executed by the winding controller, cause the one or more motors to translate the winding head across the workspace area along a predefined path. 3 . The system of claim 2 , wherein the winding controller is further in electrical communication with the rotation motor, and wherein the instructions, when executed by the winding controller, cause the rotation motor to rotate the rotatable base of the winding head and alter the orientation of the linear array. 4 . The system of claim 3 , wherein the winding controller is configured to cause the rotation motor to rotate the rotatable base of the winding head as a function of the position of the winding head within the workspace. 5 . The system of claim 3 , wherein the winding controller is configured to cause the rotation motor to rotate the rotatable base of the winding head as a function of an arrangement of the plurality of upstanding pins and further as a function of the position of the winding head relative to the arrangement of the plurality of pins. 6 . The system of claim 3 , wherein the movement mechanism is operative to translate the winding head across the workspace and such that: a yarn guide of the plurality of yarn guides exits the workspace area by passing between a first pair of adjacent upstanding pins from the plurality of upstanding pins; and reenters the workspace area by passing between a second pair of adjacent upstanding pins from the plurality of upstanding pins; and further wherein: the linear array of yarn guides defines a thread guide orientation vector that is a best fit line through each of the plurality of yarn guides; the first pair of upstanding pins at least partially define a first pin-alignment vector that is a best fit line through at least the first pair of upstanding pins; and the second pair of upstanding pins at least partially define a second pin-alignment vector that is a best fit line through at least the second pair of upstanding pins; a first exit angle is defined as an angle formed between the yarn guide orientation vector and the first pin-alignment vector at the moment the pin exits the workspace area between the first pair of upstanding pins; and a first reentry angle is defined as an angle formed between the thread guide orientation vector and the second pin-alignment vector at the moment the pin reenters the workspace between the second pair of upstanding pins. 7 . The system of claim 6 wherein: the winding controller is configured to adjust the orientation of the linear array of yarn guides such that first exit angle is identical to the first reentry angle. 8 . The system of claim 6 wherein the movement mechanism is operative to translate the winding head across the workspace and such that: the yarn guide of the plurality of yarn guides exits the workspace area a subsequent time by passing between a third pair of adjacent upstanding pins from the plurality of upstanding pins; and reenters the workspace area a subsequent time by passing between a fourth pair of adjacent upstanding pins from the plurality of upstanding pins; and wherein: the third pair of upstanding pins at least partially define a third pin-alignment vector that is a best fit line through at least the third pair of upstanding pins; and the fourth pair of upstanding pins at least partially define a fourth pin-alignment vector that is a best fit line through at least the fourth pair of upstanding pins; a second exit angle is defined as an angle formed between the thread guide orientation vector and the third pin-alignment vector at the moment the pin exits the workspace area between the third pair of upstanding pins; a second reentry angle is defined as an angle formed between the yarn guide orientation vector and the fourth pin-alignment vector at the moment the pin reenters the workspace between the fourth pair of upstanding pins; and wherein the winding controller is configured to adjust the orientation of the linear array of yarn guides such that first exit angle is identical to the second exit angle and the first reentry angle is identical to the second reentry angle. 9 . The system of claim 1 , wherein each yarn guide of the plurality of yarn guides includes a tube having a proximal end attached to the rotatable base and a distal end that extends into the workspace area. 10 . The system of claim 9 , further comprising a plurality of continuous strands of yarn, each continuous strand of yarn extending through a different respective yarn guide of the plurality of yarn guides, and wherein winding head is operative to draw the plurality of continuous strands of yarn across the workspace area from the distal end of each of the plurality of yarn guides. 11 . The system of claim 10 , further comprising a tensioner in communication with each of the plurality of continuous strands of yarn, the tensioner configured to maintain a predefined amount of tension on the yarn. 12 . The system of claim 1 , wherein the movement mechanism is a gantry system operative to controllably move the winding head in two dimensions. 13 . An automatic winding system for winding a plurality of yarn strands across a jig having a plurality of upstanding peripheral retention pins disposed around a central workspace area, the system comprising: a winding head, the winding head including: a rotatable base; a plurality of yarn guides arranged in a linear array and extending from the rotatable base; a rotation motor coupled to the rotatable base and configured to selectively rotate the base to alter an orientation of the linear array; a movement mechanism coupled with the winding head and including a plurality of motors operative to controllably translate the winding head across the workspace area; a plurality of continuous strands of yarn, each continuous strand of yarn extending through a different respective yarn guide of the plurality of yarn guides; and a winding controller in electrical communication with each of the plurality of motors of the movement mechanism, wherein the winding controller is configured to operate the movement mechanism to draw the plurality of continuous strands of yarn across the workspace area between and around the plurality of upstanding peripheral retention pins. 14 . The automatic winding system of claim 13 , wherein the winding controller is further in communication with the rotation motor and is configured to cause the rotation motor to rotate the rotatable base of the winding head and alter the orientation of the linear array. 15 . The automatic winding system of claim 14 , wherein the windin