A system provides a “virtual room” for remotely sharing content experiences via electronic devices at different locations. The system may enable synchronization of the content at the different locations, access control, be able to provide and/or experience interaction feedback regarding the content, control the interaction feedback that is provided and/or experienced, enhance the ability of people to distinguish the content from the interaction feedback, and so on. As such, people may be able to share content experiences more like they were present in a single location while remote from each other.

The present application relates to an electrical connector and an electronic product. The electrical connector includes a metal terminal; an insulating body configured to fixing the metal terminal; a metal shield covering an outer side of at least a portion of the insulating body; a metal latch connected to the insulating body, and provided with a ground terminal thereon, and wherein the insulating body, the metal shield, and the metal latch enclose an accommodating space; and a brazing solder disposed at least partially within the accommodating space, and the brazing solder being configured to be melted during welding and to fixedly connect the metal shield and the metal latch after being cooled, such that the metal shield is electrically connect to the metal latch.

A connector assembly includes an adapter connector and two end-connectors. Each connector includes a high-speed differential area and a low-speed area. The high-speed differential area of each end-connector includes an end differential unit. The high-speed differential area of the adapter connector includes an adapter differential module. Each end differential unit and a corresponding adapter differential unit include a signal contact and a ground shielding member. The plug-in parts of the two end-connectors, which are adapted with the adapter connector, are the same in structure, and of the end differential unit and the adapter differential unit, one is a male unit and the other is a female unit in corresponding plug-in fit. Due to the fact that the plug-in parts of the two end-connectors are the same in structure, when the end-connectors are plugged into the adapter connector, identification can be saved, and blind plugging operation can be directly performed.

A wafer includes a number of conductive terminals and an insulating frame. The conductive terminals include differential signal terminals, a first ground terminal and a second ground terminal. Each conductive terminal includes a connection portion and a contact portion. The connection portions of the differential signal terminals, the first ground terminal and the second ground terminal are located in a first plane. The first ground terminal includes a first torsion portion and the second ground terminal includes a second torsion portion. The contact portion of the first ground terminal and the contact portion of the second ground terminal are both perpendicular to the first plane. This present disclosure can provide better shielding effect, reduce crosstalk and improve the quality of signal transmission. In addition, the present disclosure also relates to a backplane connector having the wafer.

A power connector has a casing, a first power terminal, and a second power terminal. The casing has at least one cable-in opening. The first power terminal has a first inner connecting portion and a first outer connecting portion. The first inner connecting portion is secured in the casing and has a first through hole matrix. The first through hole matrix faces the at least one cable-in opening and has multiple first through holes. The first outer connecting portion is located outside of the casing. The second power terminal is basically the same as the first power terminal. The first power terminal is located between the second power terminal and the at least one cable-in opening. The first power terminal shields part of the second power terminal and allows the second through hole matrix of the second power terminal to be exposed to the at least one cable-in opening.

A connector includes a terminal-equipped electric wire having a terminal connected to an end portion of an electric wire, housing to accommodate the terminal and to hold the terminal-equipped electric wire and a heat transfer member having elasticity. The housing includes a first housing having a terminal accommodating portion, and a second housing to hold the terminal-equipped electric wire. The second housing includes a resin holder to be mounted on an electric wire connection portion of the terminal and the end portion of the electric wire, and a metal holder to be externally mounted on the resin holder. The heat transfer member is disposed in a compressed and deformed state between an outer circumferential surface of at least: one of the electric wire connection portion of the terminal and the end portion of the electric wire and an inner circumferential surface of the second housing.

A connection terminal includes a terminal connecting portion configured to be electrically connected to a counterpart terminal, an electric wire connecting portion configured to be electrically connected to an electric wire, a holding portion provided between the terminal connecting portion and the electric wire connecting portion and configured to be held by a housing, a sealed space formed in the holding portion, a latent heat storage material and a gas sealed in the sealed space, a sealing hole communicating the sealed space with a space outside the connection terminal, and a plug member configured to block the sealing hole.

A method for manufacturing a power pin of a power interface is provided. The method may includes the steps of: providing a pin workblank, wherein the pin workblank includes a first surface and a second surface adjacent to each other; performing a fine blanking process for the first surface in a predetermined blanking direction, while burrs forming on the second surface; and adjusting a position of the pin workblank, performing another fine blanking process for the second surface in the predetermined blanking direction, to form a power pin of the power interface and to omit a process of removing the burrs on the second surface. Before the step of adjusting a position of the pin workblank, the method further includes a step of forming a chamfer or a round fillet at an edge of the second surface adjacent to the first surface of the pin workblank.

A method for manufacturing a power pin of a power interface is provided. The method may includes the steps of: providing a pin workblank, wherein the pin workblank includes a first surface and a second surface adjacent to each other; performing a fine blanking process for the first surface in a predetermined blanking direction, while burrs forming on the second surface; and adjusting a position of the pin workblank, performing another fine blanking process for the second surface in the predetermined blanking direction, to form a power pin of the power interface and to omit a process of removing the burrs on the second surface. Before the step of adjusting a position of the pin workblank, the method further includes a step of forming a chamfer or a round fillet at an edge of the second surface adjacent to the first surface of the pin workblank.

A contact element for an electric vehicle (EV) connector that is configured to connect a charging wire to a connector interface on a vehicle side includes a front part and at least one base. The front part comprises walls having an inner and an outer side that enclose a hollow chamber, which is partly filled with a fluid, and the inner side of the walls are designed having a capillary structure.