Method of manufacturing a shell assembly for an electrical connector

What is claimed is: 1. A method of manufacturing a shell assembly for an electrical connector, the method comprising: forming a plurality of first three-dimensional shells along a length of a first metal strip using a progressive stamping process, each of the first shells having a generally rectangular body attached to the first metal strip by a neck and arranged along the first metal strip such that a front end opening of each first shell is orthogonal to the length of the first metal strip; forming a plurality of second three-dimensional shells along a length of a second metal strip using a progressive stamping process, each of the second shells having a generally rectangular body attached to the second metal strip and arranged along the second metal strip such that front and rear openings of each second shell are parallel to a length of the second metal strip; attaching a second shell of the plurality of second shells to each shell of the plurality of first shells by: (i) severing the second shell from the second metal strip, (ii) sliding the rear opening of the second shell over the front end opening of the first shell so that a portion of the second shell overlaps the first shell and (iii) bonding the first and second shells together in the overlapping region to form a shell assembly; and for each shell assembly, performing additional operations on the shell assembly while the first shell is attached to the first metal strip by the neck. 2. The method of manufacturing a shell for an electrical connector set forth in claim 1 wherein the additional operations performed on each shell assembly while attached to the first metal strip by the neck comprise: a sandblasting operation; and a plating operation. 3. The method of manufacturing a shell assembly for an electrical connector set forth in claim 1 further comprising, for each shell assembly, severing the neck of the first shell to separate the shell assembly from the first metal strip after the additional operations are performed. 4. The method of manufacturing a shell assembly for an electrical connector set forth in claim 1 further comprising, for each first shell in the plurality of first shells, compressing the first shell around each of four sides of the front opening while sliding the rear opening of the second shell over the first shell. 5. The method of manufacturing a shell assembly for an electrical connector set forth in claim 1 wherein the progressive stamping operations for each of the first and second metal strips comprises shearing holes and shapes in the first and second metal strips and bending portions of the first and second metal strips to form the plurality of first and second three dimensional shells. 6. The method of manufacturing a shell assembly for an electrical connector set forth in claim 1 wherein the attaching step comprises feeding the first plurality of shells into a tool along a first feed direction and feeding the second plurality of shells into the tool along a second feed direction, perpendicular to the first feed direction. 7. The method of manufacturing a shell assembly for an electrical connector set forth in claim 1 wherein each of the first and second shells are bonded together in the overlapping region using a laser welding process. 8. The method of manufacturing a shell assembly for an electrical connector set forth in claim 1 wherein: for the first metal strip, after the progressive stamping process, each of the first shells is attached to a single guide rail of the first metal strip by the neck; and for the second metal strip, after the progressive stamping process, each of the second shells is positioned between first and second parallel guide rails of the second metal strip and is attached to the second metal strip by a neck that is attached to a support rail that extends perpendicularly between the first and second parallel guide rails. 9. A method of manufacturing a shell assembly for an electrical connector, the shell assembly including a first and second shell, the method comprising: feeding a length of metal strip in a first direction to a stamping line; stamping, in a second direction, the metal strip, the second direction being orthogonal to the first direction, the stamping comprising: shearing holes and shapes in the metal strip to define a first section of material to act as a carrier strip including one or more sheared holes, a second section of material for forming the first shell, and a neck connecting the first and second sections of material; and forming the first shell with a mechanical press and forming cam, the first shell comprising: a height, a length and a width; and a first opening defining a cavity about the length of the first shell, the first opening being orthogonal to the first direction; assembling the first shell with the second shell, the second shell having an opening defining a cavity that has a width and a thickness that are greater than the width and thickness of the first shell, respectively, the opening of the second shell being assembled over the first shell to form a shell assembly; and performing additional operations on the shell assembly while the shell assembly remains attached to the carrier strip via the neck. 10. The method of claim 9 , wherein the first shell is a rear shell of the shell assembly and the second shell is a front shell of the shell assembly. 11. The method of claim 9 , wherein the first shell is a front shell of the shell assembly and the second shell is the rear shell of the shell assembly. 12. The method of claim 9 , wherein the additional operations include welding, sandblasting and plating the assembled plug connector. 13. The method of claim 12 , wherein the additional operations are performed via the carrier strip being routed via a reel to an operation station for performing the one or more additional operations. 14. The method of claim 9 , further comprising winding the carrier strip around a reel, the carrier strip still having the assembled plug connector attached thereto, for storing or routing one or more assembled plug connectors. 15. The method of claim 9 , wherein the first shell includes one or more locking tabs and the second shell includes corresponding locking gaps, wherein the locking tabs extend into the locking holes when the second shell is assembled over the first shell and the locking tabs are positioned directly below the locking holes thereby holding the first and second shells in their assembled positions with respect to each. 16. The method of claim 9 , further comprising removing the shell assembly from the carrier strip. 17. The method of claim 16 , further comprising assembling a rear boot with the plug connector. 18. The method of claim 17 , further comprising affixing the rear boot assembled with the plug connector to the shell assembly by injection molding material between the rear boot and the shell assembly. 19. The method of claim 18 , wherein the rear boot includes a data and power transmission cable attached to an end thereof. 20. A method of manufacturing a shell assembly for an electrical connector, the method comprising: forming a plurality of first three-dimensional shells along a length of a first metal strip using a progressive stamping process, each of the first shells having a generally rectangular body attached to the first metal strip by a neck and arranged along the first metal strip such that a front end opening of each first shell is orthogonal to the length of the first metal strip; formi