An electrical connector (1) including a male contact (5) and a female contact (10) movable between a non-inserted position, and an inserted position, wherein an electrically conductive insertable portion (12) of the male contact (5) is inserted along an insertion axis (D) into a housing (14) defined by the female contact, the female contact including: an electrically conductive body (22), a plurality of strips (26) protruding axially from the body and angularly distributed around the insertable portion in the inserted position, the strips being electrically conductive and radially flexible, the body and the strips defining the housing, and at least one annular contention member (28) positioned on radially external faces (30) of the strips and adapted for exerting a centripetal radial pressure on the strips in the inserted position, the strips having radially internal faces (42) flattened against the insertable portion in the inserted position.

A butting surface (21) of a first butting terminal fitting (20) held by a first terminal accommodating member (40) is formed in a curved-surface configuration protruding toward a second butting terminal fitting (30) side held by a second terminal accommodating member (50). A plurality of contact spring pieces (33a and 33b) of the second butting terminal fitting (30) which are butted against the butting surface (21) and resiliently deformed are flat plate type leaf springs arranged on the same plane.

A battery connector is disclosed. An insulating body has a first accommodating space and a limiting portion, and a second accommodating space, which is in communication with the first accommodating space, is provided above the first accommodating space and the limiting portion. In assembly, the battery is guided downward into the second accommodating space, and the battery is pressed downward such that the battery passes the limiting portion to enter the first accommodating space and abut a positive pole terminal and a negative pole terminal, thus achieving assembly of the battery conveniently, and effectively preventing the battery from falling out of the insulating body.

An electrical connector comprises a housing and a plurality of contacts. The housing has a card slot for insertion of an electronic card and openings in two sides of the card slot. The plurality of contacts each comprises a plurality of separate members. Each member is in the shape of a beam with a contact portion, and each contact is inserted into one opening. A plurality of contact portions of each contact is arranged along an inserting direction of the electronic card. The electrical connector is easy to assemble, since it only needs to insert the plurality of members included in the contact corresponding to each opening in the housing into the opening. Thus, the cost can be reduced. The plurality of members are held on the housing through the corresponding opening and these members can be reliably fixed to the housing without an additional fixing component. Thus, the electrical connector has a simple structure. In addition, manufacturing each contact into several separate members causes the structure of each member simple, thereby reducing the processing difficulty of the contact and further reducing the cost.

A connector assembly includes multiple terminals. Each terminal includes a conductive portion. The terminals include first and second high speed signal terminals and a low speed signal terminal. The conductive portions of the first and second high speed signal terminals and the low speed signal terminal are correspondingly defined as first, second and third conductive portions. An adapter board is located above a circuit board to be conductively connected to a cable directly or indirectly. The adapter board includes first and second signal circuit layers located at different heights. The first signal circuit layer includes a first high speed signal circuit conductively connecting the first conductive portion and a conductive wire of the cable. The second signal circuit layer includes a second high speed signal circuit conductively connecting the second conductive portion and another conductive wire of the cable. The third conductive portion is conductively connected to the circuit board.

A compact ECG snap connector is disclosed. A channeled U shaped body is formed from a thin sheet of electrically conductive and resilient material. The body is dimensioned to be compatible with standard ECG snap connector pins, and can be fastened to a printed circuit board. Fixed structures located in proximity to the channeled U shaped body provide mechanical restrictions on the expansion and contraction of the channeled U shaped body's aperture.

A connector structure is provided. The connector structure includes an insulated housing and at least one terminal assembly. The terminal assembly includes an insulated shelter and at least one pins. The pins are connected to and penetrated through the insulated shelter. The pin includes a pin body and at least two protrusive portions. Each protrusive portion is connected to the pin body, and in a length direction of the pin body, the protrusive portions respectively extend corresponding contact portions. The contact portion is in contact with a corresponding signal pad of a circuit board, and the contact portions are at different positions of the signal pad. In additional, a terminal components of connector is also provided.

Fixed conductive plates are buried in a case. In its internal space, a first contact surface, which is part of each fixed conductive plate, and a second contact surface, which is an inner surface of the case, are opposite to each other, and an elastic conductive plate is interposed in this opposing portion. The elastic conductive plate is structured so that, in a restricting portion, a support piece portion is fitted to the thin plate portion of the fixed conductive plate and that an elastic arm portion extends from the support piece portion.

An arrangement of components for transferring electric current from a current-feeding component to a current-discharging component, including a first component, which feeds current to the arrangement or discharges current from the arrangement. The first component includes a first metallic material and, on at least one surface, has at least one spring lamella composed of the first metallic material and machined out of the first metallic material at the surface. The lamella is machined out of the first metallic material at the surface of the first component such that it is connected monolithically to the first component in a connecting region and, starting therefrom extends as far as a free end and, when deflected out of a rest position toward the surface of the first component, exerts a spring force directed away from the surface. A second component is in immediate contact with the lamella of the first component.

The construction of a medical device having a disposable element is disclosed. Detachable elements comprising a body having a retention feature, an electrical contactor, and sensors are also disclosed. Further disclosed are detachable elements comprising a body having a hole and a retention pocket, an electrical contactor, and a printed circuit board assembly (PCB) in contact with the innermost surface of the body that forms the retention pocket. Further disclosed are detachable elements comprising a body having an opening and a printed film comprising conductive elements, where the conductive elements comprise a sensor configured to be aligned with the opening to expose the sensor. Further disclosed are reusable components having matching retention features.