The connecting tube portion 20 has a bottom wall 22, an upper wall 24 facing the bottom wall 22 and a front opening 21 open forward. The resilient contact piece 50 includes a fulcrum portion 51 folded rearward from a front end edge of the bottom wall 22 in the connecting tube portion 20 and a contact point portion 54 provided at a position behind the fulcrum portion 51 to contact the male terminal 80. The auxiliary spring 70 is disposed at a position behind the fulcrum portion 51 and below the contact point portion 54. The auxiliary spring 70 includes protrusions 75 projecting in a direction intersecting the front-rear direction. The protrusions 75 and an inner surface of the upper wall 24 are visually confirmable through the front opening 21 of the connecting tube portion 20.

An electrical flat socket contact device includes a contact chamber, a plurality of electrical contact springs arranged in the contact chamber, and a mechanical retaining spring arranged in the contact chamber separately from the electrical contact springs. A tab contact is insertable into the contact chamber. The electrical contact springs electrically contact the tab contact and the mechanical retaining spring mechanically retains the tab contact.

A two-piece high voltage (HV) terminal frame having a terminal frame and a contact spring. The terminal frame includes at least a top portion, a bottom portion, and a middle portion forming an opening for receiving a first bus bar and a second bus bar. The contact spring is configured to engage the top portion of the terminal frame, wherein the contact spring includes a spring portion that extends into the opening of the terminal frame.

An electrical connector comprising a plug arranged and designed to connect to a receptacle. The plug includes an electrically-insulating body, a conductor ring, and a conductive member connected to the plug conductor ring. The receptacle includes an electrically-insulating body, a conductor ring having an axial inner bore and an annular groove facing radially inward, a conductive member connected to the receptacle conductor ring, and an electrically-conductive contact having a generally annular profile, at least a portion of the electrically-conductive contact received in and contacting the annular groove and at least a portion of the electrically-conductive contact not received in the annular groove. Upon insertion of the plug into the receptacle and substantially radially aligning the plug and receptacle conductor rings, the electrically-conductive contact is elastically deformed and provides electrical contact between the plug conductor ring and the receptacle conductor ring.

A system for electrically and mechanically connecting an electrical cord and a medical device includes: a cord-side connector including a cord connecting surface, a cord-side conductive portion, and at least one protrusion extending from an intermediate surface; and a device-side connector including a device connecting surface, a device-side conductive portion, and a recess configured to slidably receive the cord-side connector in a sliding direction, the recess including at least one slot configured to slidably receive the at least one protrusion to guide the cord-side connector in the recess in the sliding direction, where the at least one protrusion and slot are configured to form a mechanical connection through an interference fit upon slidable receipt of the at least one protrusion into the at least one slot, and the cord-side conductive portion and the device-side conductive portion are configured to contact each other upon formation of the interference fit.

A system for electrically and mechanically connecting an electrical cord and a medical device includes: a cord-side connector including a cord connecting surface, a cord-side conductive portion, and at least one protrusion extending from an intermediate surface; and a device-side connector including a device connecting surface, a device-side conductive portion, and a recess configured to slidably receive the cord-side connector in a sliding direction, the recess including at least one slot configured to slidably receive the at least one protrusion to guide the cord-side connector in the recess in the sliding direction, where the at least one protrusion and slot are configured to form a mechanical connection through an interference fit upon slidable receipt of the at least one protrusion into the at least one slot, and the cord-side conductive portion and the device-side conductive portion are configured to contact each other upon formation of the interference fit.

A connector includes a terminal, a housing, and a temperature sensor. The terminal includes a terminal connection portion that is electrically connected to a counterpart terminal, a wire connection portion that is electrically connected to a wire, and a tubular portion that is located between the terminal connection portion and the wire connection portion and is formed in a tubular shape having a space portion (accommodation space portion). The temperature sensor is disposed in the space portion of the terminal. The tubular portion is accommodated inside the housing in a state where the terminal is held by the housing.

A connector system includes an adapter with a first mating portion, a second mating portion and a transition portion. A continuous outer wall extends across the first mating portion, the transition portion and the second mating potion. A first terminal positioned in the adapter. At least one receptacle has a receptacle mating section and a receptacle transition section. A continuous receptacle outer conductive wall extends across the receptacle mating section and the receptacle transition section. A receptacle inner wall extends perpendicular to the receptacle outer wall. A second terminal is positioned in the at least one receptacle. A retention member is provided in the receptacle mating section. The continuous outer wall and the continuous receptacle outer wall form a grounding shield minimizing signal leakage from the first terminal and the second terminal.

A locking mechanism for first and second housing parts of a housing of a plug connector, includes a push button, which extends in the axial longitudinal direction through an opening of the first housing part into the interior of the housing. The push button is movably arranged, relative to the housing, between predetermined first and second axial positions, which correspond with the first and second positions of the housing parts. The push button and an interior locking element are configured such that the push button is in pressure contact to the locking element and interacts with the locking element such that, in the case of movement of the push button from the first to the second positions a radial pressure contact between the two housing parts is provided such that a gap between the first and second housing parts is minimized.

A locking mechanism for first and second housing parts of a housing of a plug connector, includes a push button, which extends in the axial longitudinal direction through an opening of the first housing part into the interior of the housing. The push button is movably arranged, relative to the housing, between predetermined first and second axial positions, which correspond with the first and second positions of the housing parts. The push button and an interior locking element are configured such that the push button is in pressure contact to the locking element and interacts with the locking element such that, in the case of movement of the push button from the first to the second positions a radial pressure contact between the two housing parts is provided such that a gap between the first and second housing parts is minimized.