A retrofit switch apparatus is designed for attaching to a mechanical switch. The mechanical switch has a manual switch for performing an operation of a connected target device. The retrofit switch apparatus includes an assembly box, a wireless module, a switch unit, and a control unit. The assembly box covers the mechanical switch. The wireless module is used for receiving an external command. The switch unit has a driving structure. The driving structure is disposed in the assembly box for engaging with the mechanical switch for moving the mechanical switch to perform the operation according to the external command. The control unit has an operating unit and a trigger unit connected to the operating unit. A portion of the operating unit is exposed outside a surface of the assembly box for a user to operate to directly trigger the mechanical switch.

A retrofit switch apparatus is designed for attaching to a mechanical switch. The mechanical switch has a manual switch for performing an operation of a connected target device. The retrofit switch apparatus includes an assembly box, a wireless module, a switch unit, and a control unit. The assembly box covers the mechanical switch. The wireless module is used for receiving an external command. The switch unit has a driving structure. The driving structure is disposed in the assembly box for engaging with the mechanical switch for moving the mechanical switch to perform the operation according to the external command. The control unit has an operating unit and a trigger unit connected to the operating unit. A portion of the operating unit is exposed outside a surface of the assembly box for a user to operate to directly trigger the mechanical switch.

The disclosed concept relates to compositions and methods for the manufacture of electrically resistive, thermally conductive electrical switching apparatus. The composition includes a polymer component and a nanofiber component. The thermal conductivity of the nanofiber component is higher than the thermal conductivity of the polymer component such that the electrical switching apparatus which includes the composition of the disclosed concept has improved heat dissipation as compared to an electrical switching apparatus constructed of the polymer component in the absence of the nanofiber component. Further, the disclosed concept relates to methods of lowering the internal temperature of an electrically resistive, thermally conductive electrical switching apparatus by forming the internals of the apparatus, e.g., circuit breakers, and/or the enclosure from the composition of the disclosed concept.

The disclosed concept relates to compositions and methods for the manufacture of electrically resistive, thermally conductive electrical switching apparatus. The composition includes a polymer component and a nanofiber component. The thermal conductivity of the nanofiber component is higher than the thermal conductivity of the polymer component such that the electrical switching apparatus which includes the composition of the disclosed concept has improved heat dissipation as compared to an electrical switching apparatus constructed of the polymer component in the absence of the nanofiber component. Further, the disclosed concept relates to methods of lowering the internal temperature of an electrically resistive, thermally conductive electrical switching apparatus by forming the internals of the apparatus, e.g., circuit breakers, and/or the enclosure from the composition of the disclosed concept.

Provided is a technology pertaining to a panel attachment fixture wherein a single or a pair of electrical components can be efficiently arranged on an attachment-receiving panel by use of a common fixture body, said panel attachment fixture has predetermined electric components such as switches disposed on the front surface of a flange section thereof and can be attached to the attachment-receiving panel in a state in which a body section protruding rearward from the back surface of the flange section is inserted in an attachment opening of the attachment-receiving panel. The body section has on the periphery thereof: a first member fitting part to which a single first attachment member serving as an attachment member is fitted in an independent-attachment state for independently attaching a single fixture body to the attachment-receiving panel; and a second member fitting part to which a single second attachment member serving as an attachment member is fitted in a parallel-attachment state for attaching one pair of fixture bodies to the attachment-receiving panel, with the fixture bodies being arranged parallel to each other along a first direction in an in-plane direction of the attachment-receiving panel.

Provided is a technology pertaining to a panel attachment fixture wherein a single or a pair of electrical components can be efficiently arranged on an attachment-receiving panel by use of a common fixture body, said panel attachment fixture has predetermined electric components such as switches disposed on the front surface of a flange section thereof and can be attached to the attachment-receiving panel in a state in which a body section protruding rearward from the back surface of the flange section is inserted in an attachment opening of the attachment-receiving panel. The body section has on the periphery thereof: a first member fitting part to which a single first attachment member serving as an attachment member is fitted in an independent-attachment state for independently attaching a single fixture body to the attachment-receiving panel; and a second member fitting part to which a single second attachment member serving as an attachment member is fitted in a parallel-attachment state for attaching one pair of fixture bodies to the attachment-receiving panel, with the fixture bodies being arranged parallel to each other along a first direction in an in-plane direction of the attachment-receiving panel.

A switch assembly, which is part of a chain of switch assemblies, includes a communication unit (CU) configured to receive, from an external controller, a fire command to activate a detonator, a voltage measuring unit configured to locally measure a voltage (V) at the switch assembly after receiving the fire command to activate the detonator, a computing core (CC) configured to locally make a decision whether or not to activate the detonator, after receiving the fire command to activate the detonator and after measuring the voltage (V), based on whether or not the measured voltage (V) at the switch assembly is larger than a threshold value.

A remote control for a wireless load control system, the remote control comprising: a housing having a front surface and an outer periphery defined by a length and a width; an actuator provided at the front surface of the housing; a wireless transmitter contained within the housing; and a controller contained within the housing and coupled to the wireless transmitter for causing transmission of a wireless signal in response to an actuation of the actuator, the wireless transmitter and the controller adapted to be powered by a battery contained within the housing; wherein the length and the width of the housing are slightly smaller than a length and a width of a standard opening of a faceplate, respectively, such that the outer periphery of the housing is adapted to be received within the standard opening of the faceplate when the housing and the faceplate are mounted to a vertical surface.

A remote control for a wireless load control system, the remote control comprising: a housing having a front surface and an outer periphery defined by a length and a width; an actuator provided at the front surface of the housing; a wireless transmitter contained within the housing; and a controller contained within the housing and coupled to the wireless transmitter for causing transmission of a wireless signal in response to an actuation of the actuator, the wireless transmitter and the controller adapted to be powered by a battery contained within the housing; wherein the length and the width of the housing are slightly smaller than a length and a width of a standard opening of a faceplate, respectively, such that the outer periphery of the housing is adapted to be received within the standard opening of the faceplate when the housing and the faceplate are mounted to a vertical surface.

A changeover switch for medium voltage switchgear is provided. The changeover switch includes a first terminal body, a second terminal body, and two elongate pole bodies. The two elongate pole bodies are arranged parallel to each other and rotatably arranged with first ends on opposite sides of, and in direct contact with the first terminal body around a rotation axis. The two elongate pole bodies are rotatable between an open position and a closed position. The second ends of the two elongate pole bodies are positioned in direct contact with opposite sides of the second terminal body. The changeover switch further includes one or more springs arranged between the two elongate pole bodies to urge the two elongate pole bodies towards each other.