An intelligent leakage current detection and interruption device for a power cord, including a switch module configured to control electrical connection of first and second power lines between input and output ends; a leakage current detection module, including first and second leakage current detection lines coupled in series, configured to detect a leakage current on the first and second power lines, respectively; a detection monitoring module, coupled in series to the first and second leakage current detection lines and to the first and second power lines, configured to detect an open circuit condition in the first or second leakage current detection line; and a drive module, coupled to the switch module, the leakage current detection module and the detection monitoring module, configured to drive the switch module to cut off power to the output end in response to any detected leakage current or open circuit condition.

A splitter cord for use with a power pedestal including a plurality of receptacles, the splitter cord includes a plurality of branch circuits each having a first end including a connector structured to electrically connect to one of the plurality of receptacles, a second end electrically connected to a common node, and a current regulator electrically connected between the first and second ends and being structured to control current flowing through said branch circuit such that current exiting said one receptacle is substantially equal to current entering said one receptacle, and a stem circuit having a first end including a connector structured to electrically connect to a device or vehicle receptacle and a second end electrically connected to the common node. A sum of currents flowing through the plurality of branch circuits is equal to current flowing through the stem circuit.

An emulating device for emulating a bimetallic strip, the emulating device comprising a current sensor capable of measuring a line current (I.sub.P) flowing through the emulating device, the emulating device being capable of providing a value representative of a cumulative thermal state over time t, which value is referred to as cumulative thermal state, by recursively adding a value representative of an initial thermal state, which value is referred to as initial thermal state, and a value representative of a present thermal state, which value is referred to as present thermal state, which is determined on the basis of the line current (I.sub.P).

Described are system and method embodiments for establishing a weak ground path, comprising: disabling a first ground path for a shield pin of a cable connection interface, the first ground path including a first switch; enabling a second ground path for the shield pin, the second ground path comprises a second switch, and the second ground path having a higher resistance than the first ground path; determining a connection of a device to the cable connection interface with the second ground path; and enabling the first ground path based on the connection of the device being determined.

A power cord with leakage current detection and interruption (LCDI) function includes at least two power supply lines, at least two insulating layers respectively covering the at lease two power supply lines, at least two leakage current detection lines respectively disposed around the at least two insulating layers, including a first leakage current detection line and a second leakage current detection line, at least one connector line, electrically coupled to the first leakage current detection line and/or the second leakage current detection line, and at least one insulating structure, covering at least one of the at least two leakage current detection lines, to electrically insulate the first and second leakage current detection lines from each other.

A main electrical cabling is subject to variations in ambient temperature over its length. A detection system for detecting a fault in the main electrical cabling able to cause a serial arc, or heating within a connection, includes a monitor electrical cabling placed alongside the main electrical cabling and a controllable current generator injecting, at the input of the monitor electrical cable, a current proportional to the current flowing through the main electrical cabling. The main and monitor sets of electrical cabling being joined at the output, an electronic circuitry measures the difference between the electrical potential at the input of the main electrical cabling and that at the input of the monitor electrical cabling and detects a fault in the main electrical cabling when the difference of the electrical potentials exceeds a predefined threshold. A fault in the main electrical cabling is detected despite the variations in temperature.

Systems and methods for electrical connection monitoring using cable shielding are described. For example, a system may include a high-voltage power supply; a first high-voltage cable including a first conductor connected to the high-voltage power supply and a first shielding that encircles the first conductor; a second high-voltage cable including a second conductor connected to the high-voltage power supply and a second shielding that encircles the second conductor; and a continuity detection circuit connected to the first shielding and to the second shielding, wherein the second shielding is connected to the first shielding to form a loop with the continuity detection circuit.

The application relates to direct current, DC, charging cable including two DC conductors configured for transmitting electrical energy between an electrical vehicle and a charging device, at least a signal line having a first signal line end and a second, opposite signal line end and a control device, the first signal line end is connected at a first connection point to one of the DC conductors, and the control device is configured for measuring a voltage difference between the second signal line end and a second connection point of the one of the DC conductors distant to the first connection point for determining a temperature of the DC charging cable.

Systems and methods for electrical connection monitoring using cable shielding are described. For example, a system may include a high-voltage power supply; a first high-voltage cable including a first conductor connected to the high-voltage power supply and a first shielding that encircles the first conductor; a second high-voltage cable including a second conductor connected to the high-voltage power supply and a second shielding that encircles the second conductor; and a continuity detection circuit connected to the first shielding and to the second shielding, wherein the second shielding is connected to the first shielding to form a loop with the continuity detection circuit.

Described are system and method embodiments for shield fault detection to protect the cable, components and other circuits connected to the cable shield, and to avoid high short circuit currents flowing from a power source to ground during unexpected events. A threshold voltage detector and a slope detector may be used to sense the voltage on a shield pin switchably coupled to ground via a shield ground. Method embodiments to distinguish the shield ground switch current caused by a shield fault from normal operation are also discussed. In certain situations, a weak ground path is established first to sense or identify a valid attachment on the cable before establishing a strong ground path. The disclosed embodiments, separately or in combination, may effectively detect shield fault with improved performance.