Protection of a surge arrester with a better protection against failure from thermal overload in case of a temporary overvoltage in an electrical grid line

The invention claimed is: 1. A method comprising: providing an electrical grid line, a surge arrester and a disconnector device with a disconnector unit; connecting the surge arrester at one terminal to the electrical grid line; connecting the surge arrester at its other terminal to a first terminal of the disconnector device; connecting a second terminal of the disconnector device to ground potential; interrupting an electrical connection in between the electrical grid line and the ground potential in response to a temporary overvoltage; forcibly separating the first terminal from the second terminal before a current across the surge arrester causes a thermal overload of the surge arrester, the forcibly separating producing gasses and solid particles; facilitating escape of the gasses from a housing defining a cavity around a disconnector cartridge connected between the first terminal and the second terminal of the disconnector device; and inhibiting escape of the solid particles from the housing. 2. The method of claim 1 , wherein the forcibly separating is in response to the current exceeding a predetermined current threshold for a predetermined time span, wherein the predetermined time span is selected to be less than a time span required for the current above the predetermined current threshold to cause the thermal overload of the surge arrester. 3. The method of claim 1 , wherein the disconnector cartridge comprises a blank cartridge and a varistor element connected between the first terminal and the second terminal, wherein forcibly separating comprises: heating the blank cartridge to a predetermined temperature in response to the current flowing across the varistor element for a predetermined time span before the current causes the thermal overload of the surge arrester, and igniting the blank cartridge at the predetermined temperature to disconnect the first terminal from the second terminal. 4. The method of claim 3 , wherein the varistor element comprises silicon carbide (SiC). 5. The method of claim 3 , wherein the surge arrester comprises a second varistor element coupled to the electrical grid line. 6. The method of claim 5 , wherein the second varistor element comprises a metal oxide. 7. The method of claim 1 , further comprising causing a visual indicator connected to the first terminal configured to, in response to operation of the disconnector cartridge, remain connected to the first terminal and visibly protrude from the housing. 8. The method of claim 1 , wherein the cavity has a first non-circular cross section, wherein the disconnector unit further comprises a movable member coupled to the first terminal, the movable member having a second non-circular cross section at least partially corresponding to the first non-circular cross section to inhibit rotation of the movable member and the first terminal with respect to the housing about a first axis, and wherein the forcibly separating further comprises propelling the movable member and the first terminal in a linear direction along the first axis. 9. The method of claim 1 , the disconnector device further comprsing a retaining unit, wherein the forcibly separating further comprises propelling the first terminal in a first direction toward the retaining unit, the retaining unit configured to inhibit movement of the first terminal in a second direction opposite the first direction. 10. The method of claim 1 , further comprising: protecting the disconnector device against unintentional operation in case of an impulse voltage in the electrical grid line by bypassing a disconnector cartridge of the disconnector unit via a spark gap. 11. The method of claim 10 , the disconnector device further comprising a conductive element coupled to the first terminal and extending toward the second terminal adjacent to the disconnector cartridge, wherein the conductive element and the second terminal define the spark gap between the surge arrester and the ground potential, wherein the spark gap is shorter in dimension than a thickness of the disconnector cartridge. 12. The method of claim 11 , further comprising an insulating element surrounding the disconnector cartridge, the method further comprising electrically isolating the disconnector cartridge from the spark gap by the insulating element. 13. The method of according to claim 1 , further comprising: guiding gases generated at the time of operating the disconnector device to escape through a labyrinth of the disconnector unit to an environment of the disconnector device; and retaining hot particles having enough energy to ignite a fire in the environment within the labyrinth of the disconnector unit such that they cannot leave the disconnector unit. 14. A failure protection system for an electrical grid line, the failure protection system comprising: a surge arrester comprising: a first terminal configured to be connected to an electrical grid line; and a second terminal; a disconnector device comprising: a first terminal configured to be connected to the second terminal of the surge arrester; a second terminal configured to be connected to ground potential; and a disconnector unit connected between the first terminal and the second terminal of the disconnector device, the disconnector device configured to operate in response to a temporary overvoltage before the surge arrester fails due to a thermal overload of the surge arrester; and a spark gap configured to protect the disconnector device against unintentional operation in case of an impulse voltage in the electrical grid line by bypassing a disconnector cartridge of the disconnector unit. 15. The failure protection system of claim 14 , the disconnector unit further comprising a labyrinth configured to: guide gases generated at the time of operating the disconnector device to escape through a labyrinth of the disconnector unit to an environment of the disconnector device; and retain hot particles having enough energy to ignite a fire in the environment within the labyrinth such that they cannot leave the disconnector unit. 16. The failure protection system of claim 14 , wherein the disconnector cartridge is connected between the first terminal of the disconnector device and the second terminal of the disconnector device, the disconnector cartridge configured to forcibly separate the first terminal of the disconnector device from the second terminal of the disconnector device before a current across the surge arrester causes the thermal overload of the surge arrester. 17. The failure protection system of claim 14 , wherein the disconnector cartridge comprises a blank cartridge and a varistor element connected between the first terminal of the disconnector device and the second terminal of the disconnector device. 18. A disconnector device for a failure protection system for an electrical grid line, the failure protection system comprising: a first terminal configured to be connected to a terminal of a surge arrester connected to an electrical grid line; a second terminal configured to be connected to ground potential; and a disconnector unit connected between the first terminal and the second terminal of the disconnector device, the disconnector device configured to operate in response to a temporary overvoltage before the surge arrester fails due to a thermal overload of the surge arrester; and a labyrinth configured to: guide gases generated at the time of operating the disconnector device to escape through a labyrinth of the disconnector unit