A power distribution system includes a bus plug having an electrical switch configured to selectively control energization of the bus plug. The bus plug includes an electrical switch having a control knob operable to selectively control energization of the bus plug, and an actuator having an actuator adaptor coupling that couples movement of the actuator to the control knob. The bus plug includes a partition wall separating the internal volume into a line side and a load side. The bus plug includes an external handle coupled to mechanical linkages, and an adaptor bracket fixed to at least one of the mechanical linkages and oriented to interact with the control knob. The bus plug includes an actuator operable to move the mechanical linkages. Methods of controlling energization of a bus plug with a remote application and communication module configured to operate an actuator are also provided.

A circuit breaker lockout apparatus includes a base body having a first section, a second section, and a recess formed between the first and second sections to receive a switch lever of a circuit breaker; a fixing element installed at the first section of the base body and having an actuation section to fix the base body to a switch lever of a circuit breaker received in the recess; and a cover adjustably fastened between a release position and a lockout position at the base body, the actuation section of the fixing element is accessible in the release position and is covered in an inaccessible manner by the cover in the lockout position, and the cover is configured to be fixed to the base body in the lockout position to block an adjustment of the cover from the lockout position into the release position.

A lockout unit coupled to a gate to provide selective access to an electrical machine is provided. The lockout unit includes a stationary bracket, an arm, and a removable bracket. The stationary bracket includes a first aperture defined therein, and the arm includes a second aperture defined therein. The arm is selectively movable between an open position in which the arm is spaced from the stationary bracket, and a closed position in which the second aperture is substantially concentrically-aligned with the first aperture to receive a locking device therethrough. The removable bracket is selectively coupleable to the arm when the arm is in the closed position. The removable bracket includes a third aperture defined therein that is selectively aligned with one of the first aperture and the second aperture to receive the locking device therethrough when the removable bracket is coupled to the arm.

A device and related method temporarily restrict use of a control via one or more of lock out and tag out. The device includes a first and second portion. The first portion has a passageway adapted for the reception of a tie that extends through the first portion along a distance of passageway extension. The second portion has a tang and is movable relative to the first portion to move the tang transversely across the passageway relative to the direction of passageway extension to toggle the device between an opened position and a closed position. A tie may be received in the passageway and the reception of this tie in the passageway may prevent the device from being moved from the closed position back into the opened position due to inability of the tang of the second portion to be moved past the tie in the passageway of the first portion.

A driving force transmission mechanism is provided which includes an input switching clutch configured to selectively transmit, to the output shaft (output member), either one of the rotationally driving force applied to the electrically driven input gear (first input member) and the rotationally driving force applied to the manually driven input shaft (second input shaft). A speed reducer having a simple structure and having no self-locking function is attached to the input side of the electrically driven input gear so that the rotation torque necessary to rotate the electrically driven input gear through the input switching clutch from the manually driven input shaft is larger than the rotation torque necessary to rotate the output shaft through the input switching clutch from the manually driven input shaft.

A lockout device for securing a circuit breaker switch is provided. The lockout device comprises an outer housing having side walls extending away from a base wall formed on one axial end of the outer housing to define a cavity. An arm is received within a portion of the outer housing. The arm received within a portion of the housing, the arm having a hook section and an engaging section positioned apart from one another to receive the circuit breaker switch therein. A spring is positioned between the base wall and the arm and biases the outer housing axially relative to the arm. A screw extends through the engaging section of the arm toward the hook, and is movable between the engaging section and the hook.

A lockout device for securing a circuit breaker switch is provided. The lockout device comprises an outer housing having side walls extending away from a base wall formed on one axial end of the outer housing to define a cavity. An arm is received within a portion of the outer housing. The arm received within a portion of the housing, the arm having a hook section and an engaging section positioned apart from one another to receive the circuit breaker switch therein. A spring is positioned between the base wall and the arm and biases the outer housing axially relative to the arm. A screw extends through the engaging section of the arm toward the hook, and is movable between the engaging section and the hook.

A lockout device for preventing an electrical switch from being turned either ON or OFF while the lockout device is attached to the switch. The present lockout device can be capable of quick and easy attachment to the switch and can be secured to the switch with a padlock or similar locking device. The present lockout device can also have a peg for attaching a lockout tag, which prevents the tag from being removed while the lockout device is connected to a switch.

A lock assembly for a switch device of an electrical power distribution system includes a first lock and a second lock. The lock assembly also includes a connector arranged to inhibit movement of the first lock when the switch device is in a first position and inhibit movement of the second lock when the switch device is in a second position. The lock assembly further includes a guard coupled to at least one of the first lock and the second lock. The guard is positionable between a first position in which the guard allows access to an actuating mechanism of the switch device and a second position in which the guard inhibits access to the actuating mechanism. The guard is moveable between the first position and the second position when at least one of said first lock and said second lock is rotated.

A lockout unit coupled to a gate to provide selective access to an electrical machine is provided. The lockout unit includes a stationary bracket, an arm, and a removable bracket. The stationary bracket includes a first aperture defined therein, and the arm includes a second aperture defined therein. The arm is selectively movable between an open position in which the arm is spaced from the stationary bracket, and a closed position in which the second aperture is substantially concentrically-aligned with the first aperture to receive a locking device therethrough. The removable bracket is selectively coupleable to the arm when the arm is in the closed position. The removable bracket includes a third aperture defined therein that is selectively aligned with one of the first aperture and the second aperture to receive the locking device therethrough when the removable bracket is coupled to the arm.