Systems of automatic transfer switches (ATS) are disclosed herein. One apparatus includes at least two automatic transfer switches coupled together. Each automatic transfer switches has contacts to couple a power source to a load. For each switch, an electromagnetic force biasing the contacts to each other is present if an electrical current flows through the switch. The automatic transfer switches may be on separate cassettes or on a single cassette. The power source of each switch may be the same or different.

A knife switch assembly including a pair of hinged contact knives, arranged in parallel, and moveable between at least two positions. An operator device for moving the pair of contact knives between the at least two positions, and a guide member located between the two contact knives, having two projecting side parts, each projecting side part extending along at least part of a respective side of each contact knife, which side faces a corresponding side of the other contact knife.

A knife switch assembly including a pair of hinged contact knives, arranged in parallel, and moveable between at least two positions. An operator device for moving the pair of contact knives between the at least two positions, and a guide member located between the two contact knives, having two projecting side parts, each projecting side part extending along at least part of a respective side of each contact knife, which side faces a corresponding side of the other contact knife.

The invention disclosed is a knife blade switch 2 having copper jaws 10 and a copper blade 4 with a steel end-plate 6 fastened to the free end of the blade, the steel end-plate having a higher resistivity than the resistivity of the copper blade and copper jaws. As the copper blade is withdrawn from the copper jaws, the steel end-plate of the blade remains in contact with a higher resistivity steel jaw-spring mounted on and electrically connected to the copper jaws. The connection of the steel end-plate 6 of the blade with the steel jaw-spring 12 imposes a greater resistance path for the current flowing through the switch than through the copper blade 4 and copper jaws 10, so that an arc formed at the plate and jaw-spring has a diminished current, over what would otherwise occur with a copper blade and jaws, when the contact separation occurs.

The invention disclosed is a knife blade switch 2 having copper jaws 10 and a copper blade 4 with a steel end-plate 6 fastened to the free end of the blade, the steel end-plate having a higher resistivity than the resistivity of the copper blade and copper jaws. As the copper blade is withdrawn from the copper jaws, the steel end-plate of the blade remains in contact with a higher resistivity steel jaw-spring mounted on and electrically connected to the copper jaws. The connection of the steel end-plate 6 of the blade with the steel jaw-spring 12 imposes a greater resistance path for the current flowing through the switch than through the copper blade 4 and copper jaws 10, so that an arc formed at the plate and jaw-spring has a diminished current, over what would otherwise occur with a copper blade and jaws, when the contact separation occurs.

Disconnector for switchgear, having a first contact position, in which a contact is between main and first terminals, and a second contact position, in which a contact is between the main and second terminal. The disconnector includes a connector body moveable in a first direction between the first and second positions and having an end extendable in a direction substantially perpendicular to the first direction for providing a contact force between the end and the first, second or main terminals, a first operating mechanism arranged to move the body between the first and second positions, and a second operating mechanism arranged to extend the end when the disconnector is in either the first or second contact positions, in which the end includes a conical inside surface and the second operating mechanism includes a first shaft having a first conically shaped end positioned inside the conical inside surface.

A non-fusible switch assembly including a line base assembly is disclosed. Line base assembly includes a load bus connector assembly with single-piece lug body, first and second load lugs formed in the lug body, and load-side sliding nuts slidably received in first and second load-side slide features, and load-side stationary contacts positioned directly underneath of the first and second load lugs within a projected footprint of the lug body. Line base assemblies, load lug connector assemblies and methods of operating a line base assembly are provided, as are other aspects.

A switch capable of withstanding short-circuit currents without being destroyed or deteriorated by the passage of such high currents includes at least one fixed contact and at least one movable contact, wherein the movable contact is displaceable between a closed position of the switch in which the fixed and the movable contacts are electrically connected, and an open position of the switch in which the fixed and movable contacts are separated. The switch includes at least one equipotential connecting member electrically connecting the fixed contact and the movable contact in the closed position of the switch, such that the fixed and the movable contacts are at the same electric potential, and wherein at least a part of the equipotential connecting member is pressed against the fixed contact and/or the movable contact in the closed position of the switch.

A switch capable of withstanding short-circuit currents without being destroyed or deteriorated by the passage of such high currents includes at least one fixed contact and at least one movable contact, wherein the movable contact is displaceable between a closed position of the switch in which the fixed and the movable contacts are electrically connected, and an open position of the switch in which the fixed and movable contacts are separated. The switch includes at least one equipotential connecting member electrically connecting the fixed contact and the movable contact in the closed position of the switch, such that the fixed and the movable contacts are at the same electric potential, and wherein at least a part of the equipotential connecting member is pressed against the fixed contact and/or the movable contact in the closed position of the switch.

An electric current switching device including: a first line portion including a first electrical conductor and a fixed contact secured to the first conductor; and a second line portion including a second electrical conductor and a movable contact in rotation configured to be moved between: an open position preventing the passage of current, and a closed position allowing the passage of current. The movable contact extends, in the closed position, in a direction transverse to a direction of extension of the first electrical conductor. The fixed contact includes a first portion configured to be in contact with the movable contact and a second portion fixed to the first electrical conductor, wherein the first portion and the second portion are offset in the direction of extension of the first electrical conductor.