A power distribution system includes a backplane communication busbar and a circuit breaker. The backplane communication busbar includes at least one slot, and a first interface is configured in each slot. Each first interface is connected to a first resistor R1 having a different resistance value. A second interface of each circuit breaker is connected to a second resistor R2, and when the second interface of the circuit breaker is plugged in any first interface, a preset voltage interval corresponding to a resistance value of the first resistor R1 is uniquely determined by using a series circuit including the first resistor R1 and the second resistor R2.

A switch that includes a sensor device capable of transmitting data related to a sensor signal of at least one sensor of the sensor device to an external unit through wireless communication.

An earth leakage circuit breaker and a method of controlling the same are disclosed. An earth leakage circuit breaker according to the present disclosure can detect a type of leakage current and output the type of the leakage current in various forms such that a user can recognize the type of the leakage current. Therefore, the user can easily recognize whether or not the leakage current has occurred and the type of the leakage current. This may facilitate the user to recognize the cause of the leakage and take an effective measure for preventing an accident.

A system may include a power supply that generates a first voltage. The power supply may couple upstream from an electrical load. The electrical load may operate based at least in part on the first voltage. In some cases, a solid-state circuit breaker may be coupled between the power supply and the electrical load. Furthermore, a control system may be communicatively coupled to the power supply, the electrical load, and the solid-state circuit breaker. The control system may receive an operational status from the solid-state circuit breaker and may update a visualization rendered on a graphical user interface based at least in part on the operational status. The operational status may indicate an operation of the solid-state circuit breaker coupling the power supply to the electrical load.

A system may include a power supply that generates a first voltage. The power supply may couple upstream from an electrical load. The electrical load may operate based at least in part on the first voltage. In some cases, a solid-state circuit breaker may be coupled between the power supply and the electrical load. Furthermore, a control system may be communicatively coupled to the power supply, the electrical load, and the solid-state circuit breaker. The control system may receive an operational status from the solid-state circuit breaker and may update a visualization rendered on a graphical user interface based at least in part on the operational status. The operational status may indicate an operation of the solid-state circuit breaker coupling the power supply to the electrical load.

At least one example embodiment provides a low-voltage circuit breaker for interrupting a low-voltage circuit. The low-voltage circuit breaker includes at least one first current sensor configured to determine a magnitude of an electrical current of the low-voltage circuit, an interruption unit with contacts configured to interrupt the low-voltage circuit, an electronic trip unit connected to the first current sensor and the interruption unit and configured in such a way that an interruption of the low-voltage circuit is instigated upon current or/and current period limit values being exceeded, and a power supply unit configured to supply power to the electronic trip unit and to at least one additional component of the low-voltage circuit breaker, wherein a second current sensor is between the power supply unit and the at least one additional component, said second current sensor configured to determine the magnitude of the current of the additional component.

The present invention is a smart electrical system comprising a smart control panel connected to various electrical interfaces. Each electrical interface is inbuilt with at least one IC chip to identify it. The smart control panel comprises a processing unit to process information from various electrical interfaces and load connected to each electrical interface. The processed information is displayed on the display unit, as at least one menu list, that allows the user to select and control various electrical interfaces from panel itself. The smart control panel allows the user to reset the circuit breaker box in case if it is tripped due to overload. The panel monitors each electrical interface and alerts user when overload or marginal load condition occurs.

A system may include a power supply that generates a first voltage. The power supply may couple upstream from an electrical load. The electrical load may operate based at least in part on the first voltage. In some cases, a solid-state circuit breaker may be coupled between the power supply and the electrical load. Furthermore, a control system may be communicatively coupled to the power supply, the electrical load, and the solid-state circuit breaker. The control system may receive an operational status from the solid-state circuit breaker and may update a visualization rendered on a graphical user interface based at least in part on the operational status. The operational status may indicate an operation of the solid-state circuit breaker coupling the power supply to the electrical load.

An electrical switch for switching an electric current is disclosed. The electrical switch includes an electronic trip unit, embodied in a bipartite fashion. A first part of the trip unit is fixedly connected to the electrical switch and includes protection functions of the electrical switch. A second part of the trip unit is embodied mountably and detachably on the electrical switch and defines the protection functions enabled for the customer.

A method for calculating the contact state of an electrical switch is disclosed, In an embodiment, the method includes: collecting first input values for calculating the contact state in a first component of the electrical switch; collecting second input values for calculating the contact state in a second component of the electrical switch; and calculating the contact state of the electrical switch from the first input values and the second input values.