Systems and methods for joining polymeric composites using conductive ink and a conductive rivet

What is claimed: 1. A process, for joining workpieces using hybrid mechanical connector-resistance welding, comprising: introducing a conductive fluid to an interface between the workpieces; inserting at least one mechanical conductive connector into at least one of the workpieces so that the connector reaches the interface having the conductive fluid therein; and applying energy for welding to the at least one mechanical conductive connector so that the energy passes, through the connector, to the conductive fluid and heat is generated in the workpieces at the interface, thereby melting the workpieces and forming a weld joint connecting the workpieces. 2. The process of claim 1 , wherein: the mechanical conductive connector is a rivet; and the rivet is shaped to form a generally annular top plan profile. 3. The process of claim 1 , wherein: the mechanical conductive connector is a rivet; and the rivet includes an insulating spacer separating two poles, each of which is inserted to reach the conductive fluid. 4. The process of claim 1 , wherein the inserting and the applying are performed using a combined punch-electrode tool. 5. The process of claim 4 , wherein the tool includes an electrode sub-tool surrounding a central punch sub-tool. 6. The process of claim 5 , wherein the electrode sub-tool includes at least one insulator separating a first electrode of the electrode sub-tool and a second electrode of the electrode sub-tool. 7. The process of claim 1 , wherein: inserting the connector into at least one of the workpieces includes piercing the first workpiece with the connector; and the piercing is performed while welding energy, and force, are being applied, by a welding tool, to the connector, causing the first workpiece to melt adjacent tips of the connector, facilitating the piercing. 8. The process of claim 7 , wherein: the piercing is performed using a punch device; and the punch device also functions as the weld-energy applicator. 9. The process of claim 1 , wherein: positioning the connector in the first workpiece of the multiple workpieces to be joined includes positioning the connector partially within the first workpiece during a molding process for the first workpiece; and positioning the connector partially within the first workpiece includes implanting or embedding the connector into the first workpiece during compression molding. 10. The process of claim 1 , wherein positioning the conductive mechanical connector in the first workpiece of the multiple workpieces to be joined includes positioning the connector partially within the first workpiece prior to a molding process for the first workpiece. 11. The process of claim 1 , wherein positioning the conductive mechanical connector in the first workpiece of the multiple workpieces to be joined includes positioning the connector to at least a depth of the first workpiece adjacent an interface between the first workpiece and the second workpiece. 12. The process of claim 1 , wherein: the contact portion of the connector includes a generally flat head; and the connector is positioned with respect to the first workpiece so that the head does not reach to or below the application surface of the first workpiece. 13. The process of claim 1 , wherein the contact portion of the connector includes a generally flat head; and the connector remains with a product formed by the welding to perform at least a function of post-welding peel stopping. 14. The process of claim 1 , wherein the mechanical conductive component is configured and provided in the first workpiece so that, following welding, the component acts as a heat sink, drawing heat from the weld formed, promoting quick hardening of the joint newly formed. 15. The process of claim 1 , wherein: the process further comprises contacting the mechanical conductive component with a weld-energy applicator prior to the welding; and the workpiece material is not deposited on the applicator during the welding; and the process further comprises withdrawing the applicator from the mechanical conductive component very soon post welding, without workpiece material being affixed to the applicator. 16. The process of claim 1 , wherein applying the energy for welding to the at least one mechanical conductive connector includes applying an electrical current by a first electrode to the connector adjacent an outer surface of the first workpiece and positioning a second electrode in contact with the connector adjacent an outer surface of the second workpiece, allowing the input current to exit the workpieces via the connector and second electrode. 17. The process of claim 1 , wherein applying the energy for welding to the at least one mechanical conductive connector includes applying an electrical current by a first electrode to the connector adjacent an outer surface of the second workpiece and positioning a second electrode in contact with the connector adjacent an outer surface of the first workpiece, allowing the input current to exit the workpieces via the connector and second electrode. 18. The process of claim 1 , further comprising piercing the connector into the second workpiece while welding energy, and force, are being applied, by a welding tool, to the connector, causing the second workpiece to melt adjacent tips of the connector, facilitating the piercing into the second workpiece. 19. A process, for joining workpieces using hybrid mechanical connector-resistance welding, comprising: inserting at least one mechanical conductive connector into at least one of the workpieces so that the connector reaches an interface between the workpieces having a conductive fluid at the interface; and applying energy for welding to the at least one mechanical conductive connector so that the energy passes, through the connector, to the conductive fluid and heat is generated in the workpieces at the interface, thereby melting the workpieces and forming a weld joint connecting the workpieces; wherein inserting the connector into at least one of the workpieces includes piercing the first workpiece with the connector; and wherein the piercing is performed while welding energy, and force, are being applied, by a welding tool, to the connector, causing the first workpiece to melt adjacent tips of the connector, facilitating the piercing. 20. A process, for joining workpieces using hybrid mechanical connector-resistance welding, comprising: inserting at least one mechanical conductive connector into at least one of the workpieces so that the connector reaches an interface between the workpieces having a conductive fluid at the interface; and applying energy for welding to the at least one mechanical conductive connector so that the energy passes, through the connector, to the conductive fluid and heat is generated in the workpieces at the interface, thereby melting the workpieces and forming a weld joint connecting the workpieces.