Abstract: An apparatus for electrical safety is disclosed. A system and an alternate apparatus also perform the functions of the apparatus. The apparatus includes a test point accessible from an exterior of an enclosure while the enclosure is in a closed state. The enclosure houses one or more electrical components and the closed state prevents a user from touching the one or more electrical components. The apparatus includes a test conductor connected to a point on a conductor connected to an electrical component of the one or more electrical components where the test conductor is within the enclosure. The apparatus includes an impedance connecting the test point to the test conductor. The impedance is within the enclosure. The test point meets an Ingress Protection code rating of 20.

Abstract: An apparatus for dynamic braking is disclosed. The apparatus includes a first switch connected to a first connection of a dynamic braking resistor and to a first power bus of a motor controller. The apparatus includes a second switch connected to a second connection of the dynamic braking resistor and to a second power bus of the motor controller. The motor controller provides power to and controls a motor. The apparatus includes a switch control module that controls the first and second switches to connect the dynamic braking resistor to the first and second power buses. The switch control module controls the first and second switches in response to a signal from the motor controller.

Abstract: An apparatus for protecting a motor includes two or more motor overloads, within a motor overload enclosure, protecting two or more motors. Each motor overload includes one or more current sensors where each current sensor includes a magnetic core and each current sensor includes a conductor positioned within the magnetic core where the conductor providing power to a motor protected by the two or more motor overloads (“protected motor”). Each motor overload includes a motor trip module that stops current flow to the protected motor in response determining that a thermal state of the protected motor has reached a thermal limit. Determining that the protected motor has reached a thermal limit includes using a current signal from at least one current sensor of the one or more current sensors that senses current of the protected motor to determine a thermal state of the protected motor.

Abstract: An apparatus for dynamic braking is disclosed. The apparatus includes a first switch connected to a first connection of a dynamic braking resistor and to a first power bus of a motor controller. The apparatus includes a second switch connected to a second connection of the dynamic braking resistor and to a second power bus of the motor controller. The motor controller provides power to and controls a motor. The apparatus includes a switch control module that controls the first and second switches to connect the dynamic braking resistor to the first and second power buses. The switch control module controls the first and second switches in response to a signal from the motor controller.

Abstract: An apparatus for protecting a motor includes two or more motor overloads, within a motor overload enclosure, protecting two or more motors. Each motor overload includes one or more current sensors where each current sensor includes a magnetic core and each current sensor includes a conductor positioned within the magnetic core where the conductor providing power to a motor protected by the two or more motor overloads (“protected motor”). Each motor overload includes a motor trip module that stops current flow to the protected motor in response determining that a thermal state of the protected motor has reached a thermal limit. Determining that the protected motor has reached a thermal limit includes using a current signal from at least one current sensor of the one or more current sensors that senses current of the protected motor to determine a thermal state of the protected motor.

Abstract: An apparatus for electrical safety is disclosed. A system and an alternate apparatus also perform the functions of the apparatus. The apparatus includes a test point accessible from an exterior of an enclosure while the enclosure is in a closed state. The enclosure houses one or more electrical components and the closed state prevents a user from touching the one or more electrical components. The apparatus includes a test conductor connected to a point on a conductor connected to an electrical component of the one or more electrical components where the test conductor is within the enclosure. The apparatus includes an impedance connecting the test point to the test conductor. The impedance is within the enclosure. The test point meets an Ingress Protection code rating of 20.

Abstract: A sensing and switching device, such as an overload relay, is provided which includes a processor configured to make measurements and control operation (e.g., tripping) of the device. The processor regulates measurement of voltage and/or current, and the supply of power to power supplies. The power supplies store charge to provide operational power for the processor and that can be used for tripping and resetting contacts within the device. The processor opens a burden resistor measurement circuit when charge is being stored in the power supplies, and opens switches in the power supplies while closing the burden resistor switch to permit measurements. By alternatively switching for charging of the power supplies and making of measurements, the processor is able to reliably make measurements, control the device, and store sufficient power for operation of the device despite a demanding power budget.

Abstract: A sensing and switching device, such as an overload relay, is provided which includes a processor configured to make measurements and control operation (e.g., tripping) of the device. The processor regulates measurement of voltage and/or current, and the supply of power to power supplies. The power supplies store charge to provide operational power for the processor and that can be used for tripping and resetting contacts within the device. The processor opens a burden resistor measurement circuit when charge is being stored in the power supplies, and opens switches in the power supplies while closing the burden resistor switch to permit measurements. By alternatively switching for charging of the power supplies and making of measurements, the processor is able to reliably make measurements, control the device, and store sufficient power for operation of the device despite a demanding power budget.

Abstract: A technique is provided for controlling and protecting loads such as electric motors. In the technique, current sensing circuitry detects electrical current applied to the load. Device thermal modeling circuitry, such as circuitry for modeling heating of a motor, determines heating based upon the sensed current, and generates a first trip signal in a first range based upon the current. Conductor thermal modeling circuitry estimates heating of conductors that supply current to the load, and generates a second trip signal in a second range based upon the conductor heating. The system provides an extended range of operation for a wide range of loads by effectively modeling conventional thermal overload and instantaneous trip devices.

Abstract: A technique is provided for controlling operation of motors of different sized or ratings. Components used to apply and interrupt current to the motors may be shared in control devices for the different motors. The components may include contactors or circuit interrupters, and instantaneous trip devices. The components may be sized for the higher rated motors, and be oversized for the lower rated motors. Control circuitry permits the devices to be controlled in accordance with the characteristics of the particular motor to which the devices are applied, providing accurate circuit interruption while reducing the number of different components and component packages in a product family for the various motors.