The present invention discloses a connecting assembly, applied to the technical field of wearable devices. The connecting assembly is used for connecting a main body assembly and an electric control assembly of an assembly-detachable intelligent apparatus, and includes a first connector. The connecting assembly is detachably connected to the main body assembly in a first connecting mode. The main body assembly is electrically connected to the first connector. The electric control assembly includes a second connector. The connecting assembly is detachably connected to the electric control assembly in a second connecting mode and/or a third connecting mode. The first connector is electrically connected to the second connector. The present invention further discloses an assembly-detachable intelligent apparatus, which includes a main body assembly, an electric control assembly and a connecting assembly.

A Peripheral Component Interconnect Express/Serial Attached SCSI (PSAS) female connector includes a frame member, a terminal member, and a cover member; the frame member including a terminal groove disposed in the frame member and a tilt portion disposed in the terminal groove adjacent to a plug end; the terminal member inserted in the frame member and including a Serial Advanced Technology Attachment (SATA) 7 pin terminal, a Serial Attached SCSI (SAS) 40 pin terminal, a 15 Pin signal terminal, a 6 Pin terminal, and a 4 Pin terminal. When the PSAS female connector is engaged with the male connector, the SATA 7 Pin terminal and the SAS 40 Pin terminal are pressed by a terminal of the male connector to be bent toward an outer lateral side of the terminal groove to contact the elastic plate of the cover member. The present invention effectively improves the cross interference during high speed transmission, thereby achieving the Generation 5 performance requirement.

A connector includes a contact connected to a flexible conductor, a housing that is attached to a flexible substrate and retains the contact, and a protection sheet that is constituted of an insulating film having a pressure-sensitive adhesive layer formed on one surface thereof and is disposed between the housing and the flexible substrate such that the pressure-sensitive adhesive layer faces the flexible substrate, the protection sheet being disposed so as to cover at least a front surface part of the flexible substrate on which the flexible conductor is formed, and is adhered to the flexible substrate with the pressure-sensitive adhesive layer, the housing having a flat surface facing the flexible substrate, an adhesive layer bonding the housing to the protection sheet being disposed between the flat surface and the protection sheet.

A power cord slide connector coupling includes a power cord, a low-profile connector coupled with the power cord, a receptacle including a housing with a concave opening sized to receive the low-profile connector in an insert direction, and a plug disposed in the receptacle and configured to electrically engage the low-profile connector. The plug includes contact members that are positioned such that with the low-profile connector in the concave opening, the plug engages the low-profile connector by displacing the low profile connector in a connect direction, perpendicular to the insert direction.

An angle connector, including an angle holder, a cable, and multiple contacts, is provided. The angle holder includes a first receiving portion, a second receiving portion, and a first bending portion connected therebetween. Each of the first receiving portion and the second receiving portion has multiple receiving grooves. The cable includes multiple core wires. Each of the contacts includes a first connecting portion, a second connecting portion, and a second bending portion connected therebetween. The first connecting portions for electrically connecting to another electrical connector are embedded in the receiving grooves of the first receiving portion. The second connecting portions electrically connected to the core wires are embedded in the receiving grooves of the second receiving portion.

Methods, structures, and apparatus that are able to detect the presence of liquid, moisture, or other contaminants in or on a connector. Examples provide a connector having a dedicated liquid-detect contact that does not have a corresponding contact in a corresponding connector. Examples provide liquid-detect circuitry that can use the liquid-detect contact to determine the presence of a liquid on or in the connector and can perform self-diagnostic tests such as continuity checks and calibration.

A connector assembly includes: a housing having a plurality of accommodating grooves into which a plurality of terminals are insertable, respectively, and having an insertion space recessed in a first direction intersecting a second direction in which the accommodating grooves extend, the plurality of accommodating grooves being formed in one surface of the housing; a terminal position assurance (TPA) mechanism inserted into the insertion space of the housing in the first direction, having a plurality of through-holes extending parallel to the plurality of accommodating grooves, and inhibiting the terminals inserted into the through-holes from being separated; joint terminals extending from an inside of the housing to the accommodating grooves, and electrically connected to the terminals inserted into the accommodating grooves; and a noise filter fixed to the housing or the TPA mechanism, and enclosing the accommodating grooves of the housing, the through-holes of the TPA mechanism, or the joint terminals.

An automated wire insertion machine for inserting wires into grommet cavity locations of an electrical connector includes a controllable wire insertion robot and a processor to generate pre-generated plug maps based upon an original plug map of the grommet cavity locations and to control the wire insertion robot based upon one pre-generated plug map to insert the wires into the grommet cavity locations. The pre-generated plug maps are generated by defining a range of potential error of the grommet cavity locations that includes at least one of a potential rotational error and a potential translational error, defining an acceptable tolerance of the grommet cavity locations that includes at least one of an acceptable rotational tolerance and an acceptable translational tolerance, and calculating offset values of the grommet cavity locations based on the range of potential error and the acceptable tolerance, thereby generating the plurality of pre-generated plug maps.

The invention relates to an electrical connector (2) including a connector body (20), which includes at least one accommodation (21), and at least two electrical connecting organs (22, 22′), which each include at least one internal section (220, 220′) extending inside said at least one accommodation (21). This electrical connector (2) is characterized in that it includes electrical insulating means (23), which have a tracking resistance index, CTI, higher than 600, which are located at least inside said at least one accommodation (21), which surround at least the internal section (220, 220′) of the at least two electrical connecting organs (22, 22′), and which extend at least over the internal section (220, 220′) of the at least two electrical connecting organs (22, 22′).

This disclosure describes high voltage electrical connector assemblies for connecting components of electrified vehicles or components of any other type of power connection/power transfer system. Exemplary high voltage electrical connector assemblies include blocking devices adapted for blocking disconnection from a mating connector without first using a separate tool to remove the blocking device.