This disclosure concerns a disconnector device for a surge arrester. The disconnector device comprises a housing encompassing a cavity and a disconnector unit provided inside the cavity. The disconnector device is connectable to the surge arrester and to ground potential. The housing forms an inner housing of a housing unit. The housing unit comprising an inner housing and an outer housing. The at least one ventilation opening of the inner housing is fluidly connected to the at least one further ventilation opening of the outer housing such that a labyrinth with a gas escape path for the gases from the operating disconnector cartridge is formed.

An overcurrent protection device comprises a current input terminal; a central terminal for output of current overshoots; and a terminal for output of non-impulse currents connected to a voltage of the central terminal. An electrical conductor element is connected between the input and output terminals at a reduced self-induction when operating without current overshoots. When current overshoots are present at the input terminal, the conductor produces a high drop of induction voltage between the input and output terminals. The central terminal is arranged in the vicinity of the input terminal at a distance that may be regulated. When due to current overshoot, the inductive voltage drop between the input and the non-impulse current output terminals exceeds the dielectric strength of the material present between the input and central terminals, an arc is generated between the input and central terminals to prevent the flow of current overshoots through the conductor element.

An overcurrent protection device comprises a current input terminal; a central terminal for output of current overshoots; and a terminal for output of non-impulse currents connected to a voltage of the central terminal. An electrical conductor element is connected between the input and output terminals at a reduced self-induction when operating without current overshoots. When current overshoots are present at the input terminal, the conductor produces a high drop of induction voltage between the input and output terminals. The central terminal is arranged in the vicinity of the input terminal at a distance that may be regulated. When due to current overshoot, the inductive voltage drop between the input and the non-impulse current output terminals exceeds the dielectric strength of the material present between the input and central terminals, an arc is generated between the input and central terminals to prevent the flow of current overshoots through the conductor element.

A surge protective device (SPD) module includes a module housing, first and second module electrical terminals mounted on the module housing, a gas discharge tube (GDT) mounted in the module housing, and a fail-safe mechanism mounted in the module housing. The GDT includes a first GDT terminal electrically connected to the first module electrical terminal and a second GDT terminal electrically connected to the second module electrical terminal. The fail-safe mechanism includes: an electrically conductive shorting bar positioned in a ready position and repositionable to a shorting position; a biasing member applying a biasing load to the shorting bar to direct the shorting bar from the ready position to the shorting position; and a meltable member. The meltable member maintains the shorting bar in the ready position and melts in response to a prescribed temperature to permit the shorting bar to transition from the ready position to the shorting position under the biasing load of the biasing member. In the shorting position, the shorting bar forms an electrical short circuit between the first and second GDT terminals to bypass the GDT.

This disclosure concerns a disconnector device for a surge arrester. The disconnector device comprises a housing encompassing a cavity and a disconnector unit provided inside the cavity. The disconnector device is connectable to the surge arrester and to ground potential. The housing forms an inner housing of a housing unit. The housing unit comprising an inner housing and an outer housing. The at least one ventilation opening of the inner housing is fluidly connected to the at least one further ventilation opening of the outer housing such that a labyrinth with a gas escape path for the gases from the operating disconnector cartridge is formed.

This disclosure concerns a disconnector device for a surge arrester. The disconnector device comprises a housing encompassing a cavity and a disconnector unit provided inside the cavity. The disconnector device is connectable to the surge arrester and to ground potential. The housing forms an inner housing of a housing unit. The housing unit comprising an inner housing and an outer housing. The at least one ventilation opening of the inner housing is fluidly connected to the at least one further ventilation opening of the outer housing such that a labyrinth with a gas escape path for the gases from the operating disconnector cartridge is formed.

The disclosure relates to a load current-bearing fuse with internal switch element. One example of the fuse includes a protective element with a first contact, a fuse element that connects the first contact with a second contact, and a protective element having a third contact that can be connected to a second potential of a supply network, but is electrically insulated from the fuse element. The fuse element is also disclosed to include a fluxing agent that has a lower fusion point that the fuse element itself. The fuse is further disclosed to include an internal switch element that monitors a protective element internally and can bring about a targeted disconnection.

The disclosure relates to a load current-bearing fuse with internal switch element. One example of the fuse includes a protective element with a first contact, a fuse element that connects the first contact with a second contact, and a protective element having a third contact that can be connected to a second potential of a supply network, but is electrically insulated from the fuse element. The fuse element is also disclosed to include a fluxing agent that has a lower fusion point that the fuse element itself. The fuse is further disclosed to include an internal switch element that monitors a protective element internally and can bring about a targeted disconnection.

The invention relates to a load current-bearing fuse with internal switch element having a protective element, wherein the protective element has a first contact for connecting to a first potential of a supply network and a second contact that can be connected via a device to be protected to a second potential of the supply network, wherein the protective element has a fuse element that connects the first contact and the second contact of the fuse element, wherein the protective element also has a third contact that can be connected to the second potential of the supply network and is arranged so as to be near to, but electrically insulated from, the fuse element, wherein the fuse element has a constriction in the proximity of the neighboring contact, with the constriction being embodied such that the fuse element has an electrically conductive fluxing agent in the proximity of the constriction, wherein the fluxing agent has a lower fusion point than the fuse element itself, wherein the load current-bearing fuse further comprises an internal switch element that monitors the protective element internally and can bring about a targeted disconnection, with the internal switch element being a voltage-sensitive element that is connected with one contact to the first contact and that is arranged so as to be near another contact of the voltage-sensitive element but electrically insulated from the fuse element and near to but electrically insulated from the third contact.