Apparatus and methods for joining polymeric composites using a hybrid friction/ultrasound technique for achieving desired weld characteristics

What is claimed: 1. A hybrid shaping-and-energizing system, having a pre-shaping state, a shaping state, a pre-ultrasonic-energy-application state, and an ultrasonic-energy-application state, for use in efficiently joining together multiple workpieces, of a workpiece arrangement, while inhibiting incursion of weld material into one or more unwanted areas of the arrangement, comprising: a shaping tool extending from a shaping-tool proximate end to a shaping-tool distal end, wherein the shaping tool is configured to form at least one recess in a proximate workpiece of the workpieces to be joined; and an ultrasonic horn extending from an ultrasonic-horn proximate end to an ultrasonic-horn distal end; wherein: the ultrasonic horn is generally cylindrical in shape; the shaping tool has a generally annular profile; the shaping tool is in a pre-shaping position and the ultrasonic-horn is in a pre-ultrasonic-energy-application position, with the shaping-tool distal end being generally flush with the ultrasonic-horn distal end, when the system is in the pre-shaping state; the shaping tool is movably connected to the ultrasonic horn and, when the system is in the shaping state, the shaping tool is in a shaping position distal from the pre-shaping position, with the shaping-tool distal end being distal to the ultrasonic-horn distal end; when the system is in the pre-ultrasonic-energy-application state, the ultrasonic horn is in the pre-ultrasonic-energy-application position, with the ultrasonic-horn distal end being generally flush with the shaping-tool distal end; and the ultrasonic horn, being movably connected to the shaping tool is, when the system is in the ultra-sonic-energy-application state, distal to the pre-ultrasonic-energy-application position, with the ultrasonic-horn distal end being distal to the shaping-tool distal end and contacting only a proximate surface of the proximate workpiece, to apply ultrasonic energy to the proximate workpiece by way of the proximate surface. 2. The system of claim 1 , wherein: the shaping tool is configured to form the recess by friction; and the shaping tool is configured and arranged to melt proximate workpiece material when rotated. 3. The system of claim 2 , wherein the shaping tool is configured to rotate while in contact with the proximate workpiece to generate the friction to create the recess, being an annular recess. 4. The system of claim 1 , wherein the shaping tool is positioned around the ultrasonic horn. 5. The system of claim 1 , wherein the shaping tool and the ultrasonic horn have a relative movement relationship selected from a group consisting of: the shaping tool being extendable and retractable with respect to the ultrasonic horn; and the ultrasonic horn being extendable and retractable with respect to the shaping tool. 6. The system of claim 1 , further including automated machinery controlling one or more functions of the system. 7. The system of claim 1 , wherein: the first workpiece and the second workpiece have dissimilar material; and at least one of the workpieces includes a polymer. 8. The system of claim 1 , wherein the shaping tool is spaced from the ultrasonic horn, defining an intervening gap, when the ultrasonic horn is positioned for applying ultrasonic vibrations, to inhibit transmission of vibrations from the ultrasonic horn to the shaping tool. 9. The system of claim 1 , wherein the system has an insulating characteristic selected from a group consisting of: the shaping tool comprising an insulating layer to inhibit transmission of vibrations from the ultrasonic horn to the shaping tool; and the ultrasonic horn comprising an insulating layer to inhibit transmission of vibrations from the ultrasonic horn to the shaping tool; and the system comprising an intervening material, positioned between the shaping tool and the ultrasonic horn when the ultrasonic horn is positioned for applying ultrasonic vibrations, and configured to inhibit transmission of vibrations from the ultrasonic horn to the shaping tool. 10. A hybrid shaping-and-energizing system, having a pre-shaping state, a shaping state, a pre-ultrasonic-energy-application state, and an ultrasonic-energy-application state, for use in efficiently joining together multiple workpieces, of a workpiece arrangement, while inhibiting incursion of weld material into one or more unwanted areas of the arrangement, comprising: a shaping tool extending from a shaping-tool proximate end to a shaping-tool distal end, wherein the shaping tool is configured to form at least one recess in a proximate workpiece of the workpieces to be joined; and an ultrasonic horn extending from an ultrasonic-horn proximate end to an ultrasonic-horn distal end; wherein: the shaping tool is in a pre-shaping position and the ultrasonic-horn is in a pre-ultrasonic-energy-application position, with the shaping-tool distal end being generally flush with the ultrasonic-horn distal end, when the system is in the pre-shaping state; the shaping tool is movably connected to the ultrasonic horn and, when the system is in the shaping state, the shaping tool is in a shaping position distal from the pre-shaping position, with the shaping-tool distal end being distal to the ultrasonic-horn distal end; when the system is in the pre-ultrasonic-energy-application state, the ultrasonic horn is in the pre-ultrasonic-energy-application position, with the ultrasonic-horn distal end being generally flush with the shaping-tool distal end; and the ultrasonic horn, being movably connected to the shaping tool is, when the system is in the ultra-sonic-energy-application state, distal to the pre-ultrasonic-energy-application position, with the ultrasonic-horn distal end being distal to the shaping-tool distal end and contacting only a proximate surface of the proximate workpiece, to apply ultrasonic energy to the proximate workpiece by way of the proximate surface. 11. The system of claim 10 , wherein: the shaping tool is configured to form the recess by friction; and the shaping tool is configured and arranged to melt proximate workpiece material when rotated. 12. The system of claim 10 , wherein the ultrasonic horn is generally cylindrical in shape. 13. The system of claim 10 , wherein the shaping tool has a generally annular profile. 14. The system of claim 10 , wherein the shaping tool is positioned around the ultrasonic horn. 15. The system of claim 10 , wherein the shaping tool and the ultrasonic horn have a relative movement relationship selected from a group consisting of: the shaping tool being extendable and retractable with respect to the ultrasonic horn; and the ultrasonic horn being extendable and retractable with respect to the shaping tool. 16. The system of claim 10 , wherein the shaping tool is spaced from the ultrasonic horn, defining an intervening gap, when the ultrasonic horn is positioned for applying ultrasonic vibrations, to inhibit transmission of vibrations from the ultrasonic horn to the shaping tool. 17. The system of claim 10 , wherein the system has an insulating characteristic selected from a group consisting of: the shaping tool comprising an insulating layer to inhibit transmission of vibrations from the ultrasonic horn to the shaping tool; and the ultrasonic horn comprising an insulating layer to inhibit transmission of vibrations from the ultrasonic horn to the shaping tool. 18. A hybrid shaping-and-energizing system, having a pre-shaping state and a shaping state, for use in efficiently joining together multiple work