Additive manufacturing system having feed-tensioner

What is claimed is: 1. A head assembly for an additive manufacturing system, comprising: a mounting bracket having a first end connectable to a moveable support, and a second end; a matrix reservoir connected to the second end of the mounting bracket and configured to wet a continuous reinforcement with a liquid matrix; a nozzle connected to receive the matrix-wetted continuous reinforcement from the matrix reservoir; and a tension mechanism located upstream of the nozzle and movable throughout pulling of the continuous reinforcement out of the additive manufacturing system to maintain a desired level of tension greater than zero in an axial direction of the continuous reinforcement. 2. The head assembly of claim 1 , wherein the tension mechanism is located at least partially inside the matrix reservoir. 3. The head assembly of claim 1 , further including at least one matrix jet located downstream of the tension mechanism and configured to push the continuous reinforcement towards the nozzle with a liquid matrix passing from the matrix reservoir through the matrix jet. 4. The head assembly of claim 1 , wherein the tension mechanism includes: a first guide element; a second guide element spaced apart from the first guide element and configured to receive the continuous reinforcement in a straight-line trajectory from the first guide element; and a dancer located between the first and second guide elements and configured to bias the continuous reinforcement away from the straight-line trajectory a distance related to the tension within the continuous reinforcement. 5. The head assembly of claim 4 , wherein at least one of the first and second guide elements is a roller having a concave outer profile configured to axially spread out the continuous reinforcement. 6. The head assembly of claim 4 , wherein the dancer is biased by gravity. 7. The head assembly of claim 4 , wherein the dancer is movable based on an amount of available continuous reinforcement. 8. The head assembly of claim 4 , wherein the dancer maintains a generally constant tension level within the continuous reinforcement. 9. The head assembly of claim 4 , further including at least one sensor associated with the dancer and configured to generate a signal indicative of a required adjustment in feed rate of the continuous reinforcement. 10. The head assembly of claim 1 , further including a cure enhancer located adjacent the nozzle and configured to cure the matrix wetting the continuous reinforcement during discharge from the nozzle. 11. The head assembly of claim 9 , further including a reinforcement feeder connected to the mounting bracket at a location upstream of the tension mechanism, the reinforcement feeder being configured to feed the continuous reinforcement through the tension mechanism to the nozzle. 12. The head assembly of claim 11 , further including a controller in communication with the at least one sensor and the reinforcement feeder, the controller being configured to selectively activate the reinforcement feeder based on the signal. 13. The head assembly of claim 11 , further including a second reinforcement feeder connected to the mounting bracket, the second reinforcement feeder being configured to feed a second continuous reinforcement through the tension mechanism to the nozzle. 14. The head assembly of claim 9 , wherein: the at least one sensor includes: a first limit sensor associated with a maximum allowable tension; and a second limit sensor associated with a minimum allowable tension; and the dancer is moveable between the first and second limit sensors. 15. The head assembly of claim 10 , wherein the cure enhancer includes a UV light source. 16. The head assembly of claim 3 , further including: at least one sensor configured to generate a signal indicative of a required adjustment in feed rate of the continuous reinforcement; and a valve associated with the matrix jet and adjustable to maintain a desired ratio of matrix-to-reinforcement based on the signal. 17. The head assembly of claim 1 , wherein the tension mechanism is connected to the mounting bracket between the first end and the matrix reservoir. 18. A head assembly for an additive manufacturing system, comprising: a mounting bracket having a first end connectable to a moveable support, and a second end; a matrix reservoir connected to the second end of the mounting bracket and configured to wet a continuous reinforcement with a liquid matrix; a nozzle connected to receive the matrix-wetted continuous reinforcement from the matrix reservoir; a first guide element; a second guide element spaced apart from the first guide element and configured to receive the continuous reinforcement in a straight-line trajectory from the first guide element; a dancer located between the first and second guide elements and configured to bias the continuous reinforcement away from the straight-line trajectory based on a level of tension in the continuous reinforcement that is greater than zero in an axial direction; at least one sensor associated with the dancer and configured to generate a signal indicative of movement of the dancer; and a controller in communication with the at least one sensor and configured to selectively adjust a feed rate of the continuous reinforcement based on the signal to raise or lower the level of tension. 19. The head assembly of claim 18 , further including a reinforcement feeder connected to the mounting bracket at a location upstream of the dancer, the reinforcement feeder being configured to feed the continuous reinforcement through the dancer to the nozzle. 20. The head assembly of claim 18 , further including a light source mounted adjacent the nozzle and configured to expose the liquid matrix wetting the continuous reinforcement to light at discharge from the nozzle.