It is aimed to improve durability by reducing a stress generated in a resilient contact piece. A terminal fitting (50) includes a box portion (60) in the form of a rectangular tube and a pair of resilient contact pieces (86, 87) accommodated in the box portion (60) and capable of contacting a tab (95) of a mating terminal inserted into the box portion (69) while resiliently sandwiching the tab.

An electrical connector is used for electrically connecting a chip module to a circuit board, and includes an insulating body provided with at least one accommodating slot, and at least one terminal provided in the at least one accommodating slot. The terminal has a first base and a second base formed by bending from the first base. An elastic arm is formed by bending upward and extending from the first base. The elastic arm is provided with a contact portion to be conductively connected with the chip module. The first base has a retaining portion located at a lower end thereof and extending downward. The retaining portion fits with the at least one accommodating slot to retain the terminal in the insulating body. A conducting portion extends downward from the second base to be conductively connected with the circuit board.

An electrical connector is used to electrically connect a first mating component to a second mating component. The electrical connector includes an insulating body, and at least one differential signal pair provided in the insulating body, including a long signal terminal and a short signal terminal. A length and a thickness of the long signal terminal are respectively greater than a length and a thickness of the short signal terminal. The long signal terminal includes a first contact portion, a first conducting portion and a first bending portion connecting the first contact portion and the first conducting portion. The short signal terminal includes a second contact portion, a second conducting portion and a second bending portion connecting the second contact portion and the second conducting portion. The first and second contact portions simultaneously contact the first mating component. The first and second conducting portions simultaneously contact the second mating component.

An electrical connector includes an insulating housing and a plurality of first terminals. A front surface of the insulating housing is recessed rearward to form an insertion space. The insulating housing opens a plurality of first terminal grooves. The insulating housing defines a plurality of upper adjusting slots. The plurality of first terminals are disposed in the plurality of the first terminal grooves. Each of the plurality of the first terminals has a first fastening portion and a first contact portion. A rear end of the first fastening portion extends downward to form an adjusting portion which opens an opening. The first fastening portions of the plurality of the first terminals are assembled in the plurality of the upper adjusting slots. The first contact portions of the plurality of the first terminals are assembled in the plurality of the first terminal grooves and project downward into the insertion space.

An electrical connector includes a conductive shell, a dielectric holder, and electrical contacts. The conductive shell defines a cavity. The dielectric holder is disposed within the cavity. The electrical contacts are mounted to the dielectric holder within the cavity and are arranged in pairs. The pairs include multiple pairs in a cancellation arrangement and an isolated pair spaced apart from the pairs in the cancellation arrangement. A separation distance from the isolated pair to a closest neighboring electrical contact of the electrical contacts is greater than respective separation distances from each of the pairs in the cancellation arrangement to corresponding closest neighboring electrical contacts of the electrical contacts.

The present invention relates to a method for producing a high-frequency connector. The method includes producing a basic body part from a dielectric material by means of an additive manufacturing method. The basic body part has a bushing between a first end and a second end of a longitudinal extent of the basic body part and an end face at the first end for making contact with a mating connector. In addition, the method includes coating the dielectric basic body part with an electrically conductive layer and removing the electrically conductive layer in a region surrounding the bushing in each case at the end face at the first end and at the second end of the basic body part so as to form an electrically conductive coating on the outer conductor side and an electrically conductive coating on the inner conductor side. The present invention also relates to a high-frequency connector.

An electrical connector is used to be electrically connected to a chip module, and includes a body provided with at least one accommodating groove. The body has a supporting block protrudingly provided upward at one side of the accommodating groove, and the supporting block is configured to upward support the chip module. At least one terminal is correspondingly accommodated in the at least one accommodating groove. The terminal includes: a first base accommodated in the accommodating groove; an elastic arm formed by bending and extending forward from the first base and located at one side of the supporting block to be electrically connected to the chip module; and a through slot running vertically through the elastic arm. The supporting block has a rear end. The first base is located behind the rear end. The through slot extends forward and does not pass beyond the rear end.

In a plug connector, a ground contact conductor includes: a fitting portion to fit to a ground contact conductor of a mate connector; and a clamp portion to hold a second exposing portion of a coaxial cable (a portion of a terminal portion of the coaxial cable where a part of an insulating sheath has been removed) to contact a shield exposed at the second exposing portion, without the ground contact conductor overlapping an outer peripheral surface of the insulating sheath. The clamp portion is located at an end of the ground contact conductor farthest from the fitting portion. The second exposing portion is adjacent to a first exposing portion formed at the terminal portion where a signal line is exposed.

In a plug connector, a ground contact conductor includes: a fitting portion to fit to a ground contact conductor of a mate connector; and a clamp portion to hold a second exposing portion of a coaxial cable (a portion of a terminal portion of the coaxial cable where a part of an insulating sheath has been removed) to contact a shield exposed at the second exposing portion, without the ground contact conductor overlapping an outer peripheral surface of the insulating sheath. The clamp portion is located at an end of the ground contact conductor farthest from the fitting portion. The second exposing portion is adjacent to a first exposing portion formed at the terminal portion where a signal line is exposed.

An electrical connector includes an insulating housing and a plurality of first terminals. A front surface of the insulating housing is recessed rearward to form an insertion space. The insulating housing opens a plurality of first terminal grooves. The insulating housing defines a plurality of upper adjusting slots. The plurality of first terminals are disposed in the plurality of the first terminal grooves. Each of the plurality of the first terminals has a first fastening portion and a first contact portion. A rear end of the first fastening portion extends downward to form an adjusting portion which opens an opening. The first fastening portions of the plurality of the first terminals are assembled in the plurality of the upper adjusting slots. The first contact portions of the plurality of the first terminals are assembled in the plurality of the first terminal grooves and project downward into the insertion space.