Energy director joint design for ultrasonic welding of thermoplastics

What is claimed is: 1. An ultrasonic welding method for joining first and second thermoplastic parts, said method comprising forming at least one energy director as an integral part of at least one surface of said first thermoplastic part, said energy director projecting from said surface of said first thermoplastic part toward an opposed surface of said second thermoplastic part, the end portion of said energy director having a convex curved surface so that the central portion of said convex curved surface initially engages said opposed surface when said first and second thermoplastic parts are brought into engagement with each other, and ultrasonically welding said first and second thermoplastic parts by pressing said first and second thermoplastic parts together using a servo-driven ultrasonic press while vibrating at least said first part in a direction parallel to the direction of projection of said energy director to melt said energy director and the adjacent surface of said first thermoplastic part on which said energy director is formed, wherein a longitudinal section taken through said energy director, in a direction normal to the surface to be engaged by said director, has a curved profile at the distal end of said director, said curved profile having a radius of curvature of at least 0.20 mm at the distal end of said energy director, and advancing said parts toward each other after an initial programmed delay interval following the start of said vibrating using the servo-driven ultrasonic press to change forces or speed rapidly during the ultrasonically welding after the programmed delay interval to promote initial melting of the energy director and thereafter a uniform and consistent welt joint with an optimum weld strength. 2. The ultrasonic welding method of claim 1 in which a longitudinal section taken through said energy director, in a direction normal to the surface to be engaged by said director, has a curved profile at the distal end of said director. 3. The ultrasonic welding method of claim 2 in which said curved profile is a section of a circle. 4. The ultrasonic welding method of claim 3 in which the center of said circle is substantially coincident with the surface of said first thermoplastic part from which said energy director protrudes. 5. The ultrasonic welding method of claim 3 in which the center of said circle is spaced away from the surface of said first thermoplastic part from which said energy director protrudes, in a direction opposite the direction of projection of said energy director. 6. The ultrasonic welding method of claim 3 in which the center of said circle is spaced away from the surface of said first thermoplastic part from which said energy director protrudes, in the same direction as the direction of projection of said energy director, and which includes a pair of substantially flat side walls joined to opposite ends of said curved profile, said substantially flat side walls diverging from each other as they extend away from said curved profile toward the surface of said first thermoplastic part to be joined to said second thermoplastic part. 7. The ultrasonic welding method of claim 2 in which the maximum width of said curved profile is at least half of the maximum width of said longitudinal section taken through said energy director. 8. The ultrasonic welding method of claim 2 in which said curved profile has the radius of curvature of at least 0.20 mm at the distal end of said energy director. 9. The ultrasonic welding method of claim 1 in which said energy director is formed in a mold in which the cavity that forms said energy director is formed by ball end milling. 10. An ultrasonic welding method for joining a film or fabric to a rigid thermoplastic part, said method comprising forming at least one energy director as an integral part of at least one surface of said rigid thermoplastic part, said energy director projecting from said surface of said rigid thermoplastic part toward an opposed surface of said film or fabric, the end portion of said energy director having a convex curved surface so that the central portion of said convex curved surface initially engages said film or fabric when said film or fabric is brought into engagement with said rigid thermoplastic part, wherein a longitudinal section taken through said energy director, in a direction normal to the surface to be engaged by said director, has a curved profile at the distal end of said director, said curved profile having a radius of curvature of at least 0.20 mm at the distal end of said energy director, and ultrasonically welding said film or fabric to said rigid thermoplastic part by pressing said film or fabric and said rigid thermoplastic part together using a servo-driven ultrasonic press while vibrating at least said rigid thermoplastic part or said film or fabric in a direction parallel to the direction of projection of said energy director to melt said energy director and the adjacent surface of said rigid thermoplastic part on which said energy director is formed, and advancing said parts toward each other after an initial programmed delay interval following the start of said vibrating using the servo-driven ultrasonic press to change forces or speed rapidly during the ultrasonically welding after the programmed delay interval to promote initial melting of said energy director and thereafter a uniform and consistent welt joint with an optimum weld strength. 11. The method of claim 10 in which said film or fabric is supported on a rigid surface made of a material that will not adhere to said rigid thermoplastic part. 12. An ultrasonic welding method for joining first and second thermoplastic parts, said method comprising forming at least one energy director as an integral part of at least one surface of said first thermoplastic part, said energy director projecting from said surface of said first thermoplastic part toward an opposed surface of said second thermoplastic part, the end portion of said energy director having a trapezoidal surface so that the central portion of said trapezoidal surface initially engages said opposed surface when said first and second thermoplastic parts are brought into engagement with each other, and ultrasonically welding said first and second thermoplastic parts by pressing said first and second thermoplastic parts together using a servo-driven ultrasonic press while vibrating at least said first part in a direction parallel to the direction of projection of said energy director to melt said energy director and the adjacent surface of said first thermoplastic part on which said energy director is formed, wherein said energy director has a non-pointed profile at a distal end of said energy director, and advancing said parts toward each other after an initial programmed delay interval following the start of said vibrating using the servo-driven ultrasonic press to change forces or speed rapidly during the ultrasonically welding after the programmed delay interval to promote initial melting of the energy director and thereafter a uniform and consistent welt joint with an optimum weld strength. 13. The ultrasonic welding method of claim 1 in which said trapezoidal energy director has truncated corners separated by a flat central end surface on said energy director.