Systems and methods provide a non-contact current measurement system which operates to measure alternating current flowing through an insulated wire without requiring galvanic contact with the insulated wire. The measurement system may include a magnetic field sensor that is selectively positionable proximate an insulated wire under test. In operation the magnetic field sensor detects a magnetic field generated by the current flowing in the insulated wire. Using an adjustable clamp assembly, the measurement system provides control over the mechanical positioning of the insulated wire relative to the magnetic field sensor to ensure consistent measurements. The non-contact current measurement system may determine information relating to the physical dimensions (e.g., diameter) of the insulated wire. Using the detected magnetic field, the known mechanical positioning, and the determined information relating to the physical dimensions of the insulated wire, the measurement system accurately determines the magnitude of the current flowing through the insulated wire without galvanic contact.

The present invention provides a current sensing module for a current sensor and a method for manufacturing the current sensing module. The current sensing module includes a spacer layer including a through hole and being annular in shape, and a circuit board electrically connected to the current sensor and includes at least two structural layers. The two structural layers cover the spacer layer and each of the structural layers includes at least one metal wire layer insulated from the spacer layer. The two metal wire layers are conducted to form a loop coil surrounding the spacer layer. When a wire is located in the through hole, an external power supply power to the circuit board, such that the circuit board has a detection state in which a sensing current is outputted due to magnetic induction generated by the loop coil during the wire is electrically conducted.

The present invention provides a current sensing module for a current sensor and a method for manufacturing the current sensing module. The current sensing module includes a spacer layer including a through hole and being annular in shape, and a circuit board electrically connected to the current sensor and includes at least two structural layers. The two structural layers cover the spacer layer and each of the structural layers includes at least one metal wire layer insulated from the spacer layer. The two metal wire layers are conducted to form a loop coil surrounding the spacer layer. When a wire is located in the through hole, an external power supply power to the circuit board, such that the circuit board has a detection state in which a sensing current is outputted due to magnetic induction generated by the loop coil during the wire is electrically conducted.

A clamp assembly comprises a base housing, an anchor member, at least one bracing member, an engaging member, and a clamp bolt. The anchor member supports the at least one brace member. The clamp bolt engages a threaded bore in the anchor member. When the at least one brace member is in an extended position, at least one set of brace teeth engages at least one set of base teeth to brace the at least one brace member against the base housing. When the at least one brace member is braced against the base housing, axial rotation of the clamp bolt applies a clamp force on the engaging member to clamp the cable between the engaging member and the base housing.

A clamp assembly comprises a base housing, an anchor member, at least one bracing member, an engaging member, and a clamp bolt. The anchor member supports the at least one brace member. The clamp bolt engages a threaded bore in the anchor member. When the at least one brace member is in an extended position, at least one set of brace teeth engages at least one set of base teeth to brace the at least one brace member against the base housing. When the at least one brace member is braced against the base housing, axial rotation of the clamp bolt applies a clamp force on the engaging member to clamp the cable between the engaging member and the base housing.

A clamp meter includes a meter body and a clamp jaw assembly mounted to the meter body. The clamp jaw assembly includes a first clamp jaw and a second clamp jaw that are movable in relation to each other between a closed position and an open position. In the closed position, distal ends of the first and second clamp jaws meet to define an enclosed area between the first and second clamp jaws, and in the open position, the distal ends of the first and second clamp jaws separate from each other to define a gap allowing a wire under test to pass therethrough. The clamp meter further includes a locking slider positioned within a slot inside the meter body. A switch assembly moves the locking slider longitudinally within the slot between locked and unlocked positions. In the locked position, the locking slider blocks the first clamp jaw from movement.

A clamp meter includes a meter body and a clamp jaw assembly mounted to the meter body. The clamp jaw assembly includes a first clamp jaw and a second clamp jaw that are movable in relation to each other between a closed position and an open position. In the closed position, distal ends of the first and second clamp jaws meet to define an enclosed area between the first and second clamp jaws, and in the open position, the distal ends of the first and second clamp jaws separate from each other to define a gap allowing a wire under test to pass therethrough. The clamp meter further includes a locking slider positioned within a slot inside the meter body. A switch assembly moves the locking slider longitudinally within the slot between locked and unlocked positions. In the locked position, the locking slider blocks the first clamp jaw from movement.

Systems and methods for measuring AC voltage of an insulated conductor are provided, without requiring a galvanic connection between the conductor and a test electrode. A non-galvanic contact voltage measurement system includes a sensor subsystem, an internal ground guard and a reference shield. A common mode reference voltage source is electrically coupled between the internal ground guard and the reference shield to generate an AC reference voltage which causes a reference current to pass through the conductive sensor. Control circuitry receives a signal indicative of current flowing through the sensor subsystem due to the AC reference voltage and the AC voltage in the insulated conductor, and determines the AC voltage in the insulated conductor based at least in part on the received signal. The sensor subsystem includes a plurality of sensors that are polled to compensate for conductor position while allowing for measurement of physical characteristics of the conductor.

Systems and methods for measuring AC voltage of an insulated conductor are provided, without requiring a galvanic connection between the conductor and a test electrode or probe. A non-galvanic contact (or non-contact) voltage measurement system includes a sensor subsystem, an internal ground guard and a reference shield. A common mode reference voltage source is electrically coupled between the internal ground guard and the reference shield to generate an AC reference voltage which causes a reference current to pass through the conductive sensor. Control circuitry receives a signal indicative of current flowing through the sensor subsystem due to the AC reference voltage and the AC voltage in the insulated conductor, and determines the AC voltage in the insulated conductor based at least in part on the received signal. The sensor subsystem includes at least two independent sensors that are used to compensate for conductor position while improving accuracy and dynamic range.

The present disclosure relates to systems and methods of locking a faulted circuit indicator (FCI). For example, the FCI may include a locking assembly. The locking assembly may include a lock plate that selectively moves between a locked position and an unlocked position. When in the locked position, the lock plate blocks a lock link of the FCI from moving in a first direction to prevent the FCI from opening. When in an unlocked position, the lock plate enables the lock link of the FCI to move in the first direction to allow the FCI to open.