Method and apparatus for making fiber reinforced composite tubes

What is claimed: 1. A machine configured to make a composite tube, such that the machine comprises: a mandrel that comprises an interior wall and a central axis; and a nozzle that comprises a set of rollers configured to grip a leading edge of a fiber and pull the fiber through the nozzle via the set of rollers being spaced apart from each other, by a distance less than a diameter of the fiber, and a spring configured to apply a force on at least one roller of the set of rollers, such that the nozzle applies individual fibers, while a resin coats the interior wall of the mandrel as the mandrel spins. 2. The machine of claim 1 , further comprising: means for heating the mandrel. 3. The machine of claim 1 , further comprising: a second nozzle configured to deliver the resin onto the interior wall of the mandrel, and means for relatively moving the mandrel and the nozzle along the central axis. 4. The machine of claim 1 , further comprising a fiber delivery system, that comprises a source of individual fibers and means for delivering the individual fibers to the nozzle. 5. The machine of claim 1 , further comprising the nozzle, such that the nozzle comprises a tip oriented at an angle relative to the central axis such that the fibers exit the tip comprising a velocity component, of the fibers, parallel to the central axis. 6. The machine of claim 1 , further comprising a nozzle tip oriented at an angle relative to a tangent of an inner surface of the mandrel such that each fiber of the individual fibers exits the nozzle tip at a velocity equal to a tangential velocity of the inner surface of the mandrel divided by a product of a cosine of the angle and a quotient of a diameter of the fibers divided by a rate of movement of the nozzle relative to a central axis of the mandrel. 7. The machine of claim 1 , further comprising the nozzle configured to move parallel to the central axis such that the fibers exit a tip of the nozzle comprising a velocity component, of the fibers, parallel to the central axis. 8. A machine for making a composite tube, comprising: a mandrel that comprises an interior wall that comprises a central axis; a first drive for spinning the mandrel about the central axis; a system configured to apply layers of fibers and layers of resin to the interior wall of the mandrel as it spins, such that the system comprises, for directing the fibers onto the interior wall, a nozzle that comprises a set of rollers configured to grip a leading edge of a short reinforcing fiber and pull the short reinforcing fiber through the nozzle via the set of rollers being spaced apart from each other, by a distance less than a diameter of the short reinforcing fiber, and a spring configured to apply a force on at least one roller of the set of rollers, such that, in operation, the set of rollers grips the leading edge of the short reinforcing fiber and pulls the short reinforcing fiber through the nozzle via the set of rollers being spaced apart from each other, by the distance less than the diameter of the short reinforcing fiber, and the spring applying the force on the at least one roller of the set of rollers; and a second drive for relatively moving the nozzle and the mandrel along the central axis. 9. The machine of claim 8 , further comprising means for heating the mandrel to a temperature sufficient to melt the layers of resin. 10. The machine of claim 8 , wherein the nozzle is oriented to direct the fibers onto the interior wall in a circumferential direction. 11. The machine of claim 8 , wherein the nozzle includes: a nozzle body having a tip and a passageway through which fibers may pass, guides for guiding the fibers through the passageway, and a drive for pulling the fibers through the passageway and expelling the fibers from the tip. 12. A machine, for making a fiber reinforced composite tube, that comprises: a mandrel that comprises a cylindrical interior wall that comprises a central axis; bearings for mounting the mandrel for rotation about the central axis; a rotary drive for rotating the mandrel; a heating system for heating the mandrel as the mandrel is rotated; a fiber delivery system that comprises a supply of short reinforcing fibers and a nozzle, for directing the short fibers onto the cylindrical interior wall, that comprises a set of rollers configured to grip a leading edge of a short reinforcing fiber and pull the short reinforcing fiber through the nozzle via the set of rollers being spaced apart from each other, by a distance less than a diameter of the short reinforcing fiber, and a spring configured to apply a force on at least one roller of the set of rollers; a resin delivery system including a supply of resin and a nozzle for wetting the short reinforcing fibers with resin; a displacement drive for relatively displacing the mandrel and the nozzles; and a control system for controlling operation of: the rotary drive the heating system, the fiber delivery system, the resin delivery system, and the displacement drive.