Embodiments of the present invention provide a power supply module and a soft start method. The power supply module includes an input detection circuit configured to output a first notification signal to a trigger drive circuit when it is determined that the power supply module receives a power supply signal; the trigger drive circuit configured to, upon receipt of the first notification signal sent from the input detection circuit, wait for a predetermined duration without sending a drive signal to a current limiting circuit, and to send the driver signal to the current limiting circuit when the predetermined duration elapses; and the current limiting circuit configured to limit a current on a Direct Current (DC) bus of the power supply module when the drive signal is not received by the current limiting circuit, and not to limit the current on the DC bus upon receipt of the drive signal.

Embodiments of the present invention provide a power supply module and a soft start method. The power supply module includes an input detection circuit configured to output a first notification signal to a trigger drive circuit when it is determined that the power supply module receives a power supply signal; the trigger drive circuit configured to, upon receipt of the first notification signal sent from the input detection circuit, wait for a predetermined duration without sending a drive signal to a current limiting circuit, and to send the driver signal to the current limiting circuit when the predetermined duration elapses; and the current limiting circuit configured to limit a current on a Direct Current (DC) bus of the power supply module when the drive signal is not received by the current limiting circuit, and not to limit the current on the DC bus upon receipt of the drive signal.

A plug unit for a hybrid vehicle is provided. The plug unit includes a low voltage plug connected to or disconnected from a low voltage circuit formed by a low voltage battery and a low voltage component, and allows a current to flow between the low voltage battery and the low voltage component when the low voltage plug is connected to the circuit. A high voltage plug connected to or disconnected from a high voltage circuit formed by a high voltage battery and a high voltage component, and allows a current to flow between the high voltage battery and the high voltage component when the high voltage plug is coupled to the circuit. Further, a main base having the high voltage plug mounted thereon, allows current flow in the circuits when the base is mounted and obstructs the current flowing in the high voltage circuit when the base is demounted.

A plug unit for a hybrid vehicle is provided. The plug unit includes a low voltage plug connected to or disconnected from a low voltage circuit formed by a low voltage battery and a low voltage component, and allows a current to flow between the low voltage battery and the low voltage component when the low voltage plug is connected to the circuit. A high voltage plug connected to or disconnected from a high voltage circuit formed by a high voltage battery and a high voltage component, and allows a current to flow between the high voltage battery and the high voltage component when the high voltage plug is coupled to the circuit. Further, a main base having the high voltage plug mounted thereon, allows current flow in the circuits when the base is mounted and obstructs the current flowing in the high voltage circuit when the base is demounted.

A single prong, multiple signal conducting plug and plug detection circuitry is provided. The plug may be electrically coupled to a stereo headset including a microphone. The plug may include four signal conducting regions arranged in a predetermined order along the length of the prong. Detection circuitry may be operative to determine whether a microphone type of plug (e.g., a four region plug including a microphone region and two audio regions, or a three region plug including microphone region and only one audio region) or a non-microphone type of plug (e.g., stereo plug) is inserted into the jack of an electronic device (e.g., mobile phone). Detection circuitry may also detect user activated functions performed in response to user activation of one or more switches included with the headset. For example, the headset may include a single switch for performing a function with respect to a microphone (e.g., end-call function).

A single prong, multiple signal conducting plug and plug detection circuitry is provided. The plug may be electrically coupled to a stereo headset including a microphone. The plug may include four signal conducting regions arranged in a predetermined order along the length of the prong. Detection circuitry may be operative to determine whether a microphone type of plug (e.g., a four region plug including a microphone region and two audio regions, or a three region plug including microphone region and only one audio region) or a non-microphone type of plug (e.g., stereo plug) is inserted into the jack of an electronic device (e.g., mobile phone). Detection circuitry may also detect user activated functions performed in response to user activation of one or more switches included with the headset. For example, the headset may include a single switch for performing a function with respect to a microphone (e.g., end-call function).

A stackable connector interface with magnetic retention for electronic devices and accessories can allow power and data to be transferred between one or more stacked connectors. Each interconnected stackable connector includes one or more magnetic elements, which magnetic elements have poles arranged to facilitate mating with other stackable connectors. The magnetic elements provide a magnetic retention force that holds mated connectors in contact with each other. In some embodiments, the connectors include connection detection circuitry for determining whether the connectors are mated with other connectors, thereby allowing the connectors to prevent live contacts from being exposed at an unmated surface of the connectors. In some embodiments, routing circuitry is included to determine how signals should be transferred between the interconnected stackable connectors and/or corresponding devices.

A plug connector includes a first connector half configured as a socket connector and a second connector half configured as a plug connector, each of the connector halves including an insulating body housing at least a respective pair of electric contact elements, respectively female and male, a short-circuit element being provided between the contacts of the socket connector half, adapted to hold such contacts shorted upon unmated connector, wherein the short-circuit element is made from a strip of resilient metallic material, shaped so as to constitute a spring and to offer, at each of its ends, a resilient contact, the first end of the short-circuit element being substantially rigid and stable in contact with a respective female electric contact element, while the second end of the short-circuit element, upon plug connector unmated, goes intimately into contact with the other element of female electrical contact of the socket connector.

A Universal Serial Bus (USB) cable includes a connector and a switch. The connector includes a housing configured for gripping by a user to manually insert/remove the connector to/from a port of an electronic device. The connector includes a power line configured to enable transfer of power to the electronic device and a data line configured to enable exchange of data with the electronic device. The switch is integrated into the outer surface of the housing and includes, for example, a toggle that is mechanically movable between a first position that activates a private mode and a second position that deactivates the private mode. The exchange of data with the electronic device is only enabled while the toggle is in the second position, and the transfer of power to the electronic device is enabled regardless of whether the toggle is in the first position or the second position.

The present disclosure discloses a universal socket converter with power bank, including a housing, wherein the front of the housing is provided with a USB power jack, a universal power jack and an indicator light, the upper and lower ends of the back of the housing are respectively provided with a retractable power-taking plug, the middle part of the back of the housing is provided with a foldable power-taking plug; the inside of the housing is provided with a circuit board and a storage battery, wherein the circuit board is provided with a USB power socket and an integrated universal power socket, wherein the USB power socket and the integrated universal power socket are provided with conductors inside, wherein the conductors are connected with the circuit board, the circuit board is connected with the storage battery, the retractable power-taking plug and the foldable power-taking plug.