Flexible circuit to terminal connector with wiping electrical contacts

What is claimed is: 1. An electrical connector system, comprising: a first electrical connector comprising a connector housing and a set of exposed terminals disposed at least partially within the connector housing and having a tin-coating applied at respective terminal ends; and a second electrical connector comprising: a flexible circuit (FC) comprising a set of conductive traces disposed in an insulation material and defining a set of exposed portions each where (i) the insulation material has been removed thereby exposing portions of the set of conductive traces and (ii) a tin-coating has been applied, a rigid stiffener device configured to receive and secure a portion of the FC corresponding to the set of tin-coated exposed portions, and a spring-loaded cover assembly configured to cover the portion of the FC and selectively engage with or connect to the rigid stiffener device, the spring cover assembly comprising a spring device and a spring retainer cover arranged on an opposing side of the FC that, when engaged with/connected to the rigid stiffener device, provides securing and downward force on the FC, wherein the connector housing and the spring-loaded cover assembly define a set of connection features that cause a lateral wiping action between the tin-coated terminal ends of the set of exposed terminals and the tin-coated exposed portions of the FC to improve an electrical connection therebetween during connection of the first and second electrical connectors. 2. The electrical connector system of claim 1 , wherein the spring device is a stainless steel spring. 3. The electrical connector system of claim 1 , wherein the spring device is an elastomer-type spring. 4. The electrical connector system of claim 1 , wherein the set of connection features comprises an L-shaped guide feature for an initial vertical connection movement followed by the lateral wiping action. 5. The electrical connector system of claim 1 , wherein: the first electrical connector further comprises an interface seal at an end of the connector housing proximate the terminal ends of the set of exposed terminals; and the second electrical connector further comprises an adhesive sealant disposed between the portion of the FC and the rigid stiffener device. 6. The electrical connector system of claim 5 , wherein the interface seal is an asymmetrical interface seal that, after the lateral wiping action during connection of the first and second electrical connectors, becomes a symmetrical interface seal. 7. The electrical connector system of claim 6 , wherein the set of connection features comprises an L-shaped guide feature for an initial vertical connection movement followed by the lateral wiping action. 8. The electrical connector system of claim 1 , wherein the electrical connector system is part of an automotive electrical system, and wherein the first electrical connector is further configured to electrically connect to another automotive electrical device or system. 9. A method of forming an electrical connector system, the method comprising: providing a first electrical connector comprising a connector housing and a set of exposed terminals disposed at least partially within the connector housing and having a tin-coating applied at respective terminal ends; providing a second electrical connector comprising: a flexible circuit (FC) comprising a set of conductive traces disposed in an insulation material and defining a set of exposed portions each where (i) the insulation material has been removed thereby exposing portions of the set of conductive traces and (ii) a tin-coating has been applied, a rigid stiffener device configured to receive and secure a portion of the FC corresponding to the set of tin-coated exposed portions, and a spring-loaded cover assembly configured to cover the portion of the FC and selectively engage with or connect to the rigid stiffener device, the spring cover assembly comprising a spring device and a spring retainer cover arranged on an opposing side of the FC that, when engaged with/connected to the rigid stiffener device, provides securing and downward force on the FC; and electrically connecting the first and second electrical connectors, wherein the connector housing and the spring-loaded cover assembly define a set of connection features that cause a lateral wiping action between the tin-coated terminal ends of the set of exposed terminals and the tin-coated exposed portions of the FC to improve an electrical connection therebetween during the connection of the first and second electrical connectors. 10. The method of claim 9 , wherein the spring device is a stainless steel spring. 11. The method of claim 9 , wherein the spring device is an elastomer-type spring. 12. The method of claim 9 , wherein the set of connection features comprises an L-shaped guide feature for an initial vertical connection movement followed by the lateral wiping action. 13. The method of claim 9 , wherein: the first electrical connector further comprises an interface seal at an end of the connector housing proximate the terminal ends of the set of exposed terminals; and the second electrical connector further comprises an adhesive sealant disposed between the portion of the FC and the rigid stiffener device. 14. The method of claim 13 , wherein the interface seal is an asymmetrical interface seal that, after the lateral wiping action during connection of the first and second electrical connectors, becomes a symmetrical interface seal. 15. The method of claim 14 , wherein the set of connection features comprises an L-shaped guide feature for an initial vertical connection movement followed by the lateral wiping action. 16. The method of claim 9 , wherein the electrical connector system is part of an automotive electrical system, and wherein the first electrical connector is further configured to electrically connect to another automotive electrical device or system. 17. An electrical connector system, comprising: a first electrical connector means providing a connector housing means and a set of exposed terminals disposed at least partially within the connector housing means and having a tin-coating applied at respective terminal ends; and a second electrical connector means comprising: a flexible circuit (FC) means comprising a set of conductive traces disposed in an insulation material and defining a set of exposed portions each where (i) the insulation material has been removed thereby exposing portions of the set of conductive traces and (ii) a tin-coating has been applied, a rigid stiffener device means for receiving and securing a portion of the FC corresponding to the set of tin-coated exposed portions, and a spring-loaded cover assembly means for covering the portion of the FC and for selectively engaging with or connecting to the rigid stiffener device means, the spring cover assembly means providing a spring device means and a spring retainer cover means arranged on an opposing side of the FC for, when engaged with/connected to the rigid stiffener device, securing and providing downward force on the FC means, wherein the connector housing means and the spring-loaded cover assembly means define a set of connection features that cause a lateral wiping action between the tin-coated terminal ends of the set of exposed terminals and the tin-coated exposed portions of the FC means to improve an electrical connection therebetween during connection of the first and second electrical connector means. 18. The electrical connector system of claim 1