The present disclosure includes a connector assembly that is a part of a sensor assembly for collecting patient physiological data. The connector assembly can include a first connector tab with catches, a second connector tab with openings, a retainer with pins, and a circuit board coupled to a cable. Each of the pins of the retainer can include a detent that can engage one of the catches of the first connector tab. The pins can extend through the openings of the second connector tab so that the retainer is coupled to the first connector tab by the detents engaging the catches. The first and second connector tabs can thereby be coupled together to support the circuit board and the cable between the first and second connector tabs.

An example dynamic connector as an absorber of impacts, is provided. An example dynamic connector includes a housing configured to engage a substrate. In addition, the example dynamic connector includes a pluggable connector having at least one electrical conductor. In an instance in which the housing is engaged with the substrate, a dynamic connector may allow the pluggable connector to move relative to the substrate while maintaining electrical communication between the at least one electrical conductor and the substrate. In another example, a circuit board assembly including a dynamic connector for impact resistance is provided. Further, an example electronic device including a dynamic connector as an absorber for impacts is provided.

An example dynamic connector as an absorber of impacts, is provided. An example dynamic connector includes a housing configured to engage a substrate. In addition, the example dynamic connector includes a pluggable connector having at least one electrical conductor. In an instance in which the housing is engaged with the substrate, a dynamic connector may allow the pluggable connector to move relative to the substrate while maintaining electrical communication between the at least one electrical conductor and the substrate. In another example, a circuit board assembly including a dynamic connector for impact resistance is provided. Further, an example electronic device including a dynamic connector as an absorber for impacts is provided.

A spring clip for a flat flexible cable includes a first beam and a second beam connected to the first beam and resiliently deflectable toward the first beam. The second beam has a first contact bend extending toward the first beam. The flat flexible cable is positioned between the first beam and the second beam and the first contact bend abuts a conductor exposed through an insulation material of the flat flexible cable to electrically connect the spring clip with the conductor.

A spring clip for a flat flexible cable includes a first beam and a second beam connected to the first beam and resiliently deflectable toward the first beam. The second beam has a first contact bend extending toward the first beam. The flat flexible cable is positioned between the first beam and the second beam and the first contact bend abuts a conductor exposed through an insulation material of the flat flexible cable to electrically connect the spring clip with the conductor.

A connector structure includes a first housing, a first shield terminal to be accommodated into the first housing, a second housing connectable to the first housing, and a second shield terminal to be accommodated into the second housing. The first shield terminal includes first inner conductors and a first outer conductor. The second shield terminal includes second inner conductors and a second outer conductor. The first outer conductor includes a first fitting portion and a first non-fitting portion. The second outer conductor includes a second fitting portion and a cut portion. The first housing includes rattling suppressing portions for suppressing rattling of the first shield terminal by coming into contact with an exposed portion of the first fitting portion exposed from the cut portion and a locking lance for retaining the first shield terminal by being locked to a lance locking portion provided on the first non-fitting portion.

A connector structure includes a first housing, a first shield terminal to be accommodated into the first housing, a second housing connectable to the first housing, and a second shield terminal to be accommodated into the second housing. The first shield terminal includes first inner conductors and a first outer conductor. The second shield terminal includes second inner conductors and a second outer conductor. The first outer conductor includes a first fitting portion and a first non-fitting portion. The second outer conductor includes a second fitting portion and a cut portion. The first housing includes rattling suppressing portions for suppressing rattling of the first shield terminal by coming into contact with an exposed portion of the first fitting portion exposed from the cut portion and a locking lance for retaining the first shield terminal by being locked to a lance locking portion provided on the first non-fitting portion.

A spring clip for securing contact partners is presented, wherein the contact partners can be connected electrically and in a form fitting manner. The spring clip has a socket section with at least one guide lug for a form fitting connection to a first contact partner, a snap-fit section with at least one snap-fit hook that snaps into a second contact partner, and a bending section between the socket section and the snap-fit section. The bending section can be bent thereby, between a relaxed state and a tensioned state.

A spring clip for securing contact partners is presented, wherein the contact partners can be connected electrically and in a form fitting manner. The spring clip has a socket section with at least one guide lug for a form fitting connection to a first contact partner, a snap-fit section with at least one snap-fit hook that snaps into a second contact partner, and a bending section between the socket section and the snap-fit section. The bending section can be bent thereby, between a relaxed state and a tensioned state.

The present disclosure includes a connector assembly that is a part of a sensor assembly for collecting patient physiological data. The connector assembly can include a first connector tab with catches, a second connector tab with openings, a retainer with pins, and a circuit board coupled to a cable. Each of the pins of the retainer can include a detent that can engage one of the catches of the first connector tab. The pins can extend through the openings of the second connector tab so that the retainer is coupled to the first connector tab by the detents engaging the catches. The first and second connector tabs can thereby be coupled together to support the circuit board and the cable between the first and second connector tabs.