Asymmetrical-force connector system

Having described the invention, we claim: 1. An asymmetrical-force connector system, comprising: a socket, including: a housing shell, having oppositely disposed front and rear housing faces and a longitudinally-oriented shaft bore extending longitudinally through the housing shell and linking the front and rear housing faces, the shaft bore defining a bore axis, a spring-receiving cavity being coaxial with the bore axis and extending laterally around an entirety of the shaft bore, the spring-receiving cavity having an inner circumference that is open to the shaft bore, and a toroidal canted coil spring located at least partially within the spring-receiving cavity, the toroidal canted coil spring having a laterally-oriented inner spring circumference coaxial with the bore axis and extending laterally around an entirety of the shaft bore; and a connector pin, configured for selective sliding insertion into the shaft bore longitudinally from the front housing face, the connector pin including: an elongate shaft having proximal and distal shaft ends and defining a pin axis, the shaft having a laterally-oriented maximum shaft circumference that is larger than the inner spring circumference, and a v-groove extending laterally inward from the maximum shaft circumference toward the pin axis, the v-groove being located longitudinally between the proximal and distal shaft ends and extending circumferentially around the entirety of the shaft to define a minimum shaft circumference as the apex of an included angle, as viewed perpendicular to the pin axis, the v-groove having a proximal groove face extending laterally and proximally outward from the minimum shaft circumference of the shaft at an acute angle with respect to the pin axis and a distal groove face extending laterally and distally outward from the minimum shaft circumference of the shaft at an obtuse angle with respect to the pin axis; wherein the connector pin is located in a maintenance position within the shaft bore when at least a portion of the connector pin is located longitudinally between the front and rear housing faces with at least a portion of the toroidal canted coil spring laterally extending into the v-groove beyond the maximum shaft circumference; wherein the housing shell is a first housing shell having oppositely disposed front and rear first housing faces and a first shaft bore, the system including a second housing shell having oppositely disposed front and second rear housing faces and a longitudinally-oriented second shaft bore extending longitudinally through the second housing shell and linking the front and second rear housing faces, the second shaft bore being located collinearly with the first shaft bore, and the second front housing face is located longitudinally interposed between the rear first housing face and the second rear housing face, a second spring-receiving cavity is coaxial with the bore axis and extending laterally around an entirety of the second shaft bore, the second spring-receiving cavity having a second inner spring circumference that is open to the second shaft bore, and a second toroidal canted coil spring is located at least partially within the second spring-receiving cavity, the second toroidal canted coil spring having a laterally-oriented second inner spring circumference coaxial with the bore axis and extending laterally around an entirety of the second shaft bore; wherein an intermediate member is interposed longitudinally between the second front housing face and the rear first housing face, the intermediate member and first and second housings cooperatively defining the shaft bore therethrough, the intermediate member having a laterally-oriented inner intermediate circumference that is longitudinally coaxial with both of the first and second inner spring circumferences; wherein the inner intermediate circumference is laterally smaller than both of the first and second inner spring circumferences, the intermediate member is at least partially made of a resilient material, and the intermediate member provides a sealing function longitudinally between the first and second toroidal canted coil springs and laterally against the shaft when the connector pin is located in the maintenance position. 2. The asymmetrical-force connector system of claim 1 , wherein the v-groove is a first v-groove and the connector pin includes a second v-groove extending laterally inward from the maximum shaft circumference toward the pin axis, the second v-groove being located longitudinally between the first v-groove and the distal shaft end and extending circumferentially around the entirety of the shaft to define a second minimum shaft circumference as the apex of an included angle, as viewed perpendicular to the pin axis, the second v-groove having a proximal second groove face extending laterally and proximally outward from the second minimum shaft circumference of the shaft at an acute angle with respect to the pin axis and a distal second groove face extending laterally and distally outward from the second minimum shaft circumference of the shaft at an obtuse angle with respect to the pin axis, and wherein the connector pin is located in a maintenance position within the shaft bore when at least a portion of the connector pin is located longitudinally between the front and rear housing faces with at least a portion of the first toroidal canted coil spring laterally extending into the first v-groove beyond the maximum shaft circumference and at least a portion of the second toroidal canted coil spring laterally extending into the second v-groove beyond the maximum shaft circumference. 3. The asymmetrical-force connector system of claim 1 , wherein the distal shaft end has a terminal diameter that is smaller than the maximum shaft circumference. 4. The asymmetrical-force connector system of claim 1 , wherein the proximal shaft end is in electrical communication with a component of an implanted electrical medical device. 5. The asymmetrical-force connector system of claim 1 , wherein the v-groove is in electrical contact with the toroidal canted coil spring when the connector pin is located in a maintenance position within the shaft bore. 6. The asymmetrical-force connector system of claim 1 , wherein a proximal end of the shaft bore is capped off to provide a plug function to the system when the connector pin is located in a maintenance position within the shaft bore. 7. The asymmetrical-force connector system of claim 1 , wherein the v-groove has an included angle in the range of 90-148 degrees. 8. The asymmetrical-force connector system of claim 1 , wherein the slidable insertion of the connector pin through the shaft bore through the front housing face longitudinally toward the rear housing face into the maintenance position develops an insertion force between the v-groove and the toroidal canted coil spring, the slidable retraction of the connector pin through the shaft bore through the rear housing face longitudinally away from the rear housing face from the maintenance position develops a retraction force of between the v-groove and the toroidal canted coil spring, and the retraction force is substantially greater than the insertion force. 9. An interconnect device for selectively electrically connecting first and second components to each other using the asymmetrical-force connector system of claim 1 , wherein the socket is in electrical contact with the first component and the connector pin is in electrical contact with the second component, and wherein the connector pin is inserted into the socket to place the first and second components into electrical contact with each other via an electrically-connective interface between the socket and the