Ignition circuit

The invention claimed is: 1. An ignition circuit comprising a series connection of at least first and second spark gaps, the first and second spark gaps suitable for limiting overvoltages corresponding to pulse shapes 8/20 μs and 10/350 μs with amplitudes between about 10 kA to about 200 kA, with the at least first and second spark gaps each being equipped with at least one auxiliary electrode and the ignition circuit having a first varistor and a second varistor, wherein the first and second varistors are suited to limiting overvoltages corresponding to pulse shape 8/20 μs with amplitudes between about 10 kA to about 100 kA, with the ignition circuit being designed to be connected to the at least one auxiliary electrode, with the ignition circuit having first and second ignition subcircuits, with the first ignition subcircuit having the first varistor and being designed to ignite the first spark gap, and with the second ignition subcircuit having the second varistor and being designed to ignite the second spark gap, wherein the first ignition subcircuit is designed to be connected to a first lead of the series connection of the at least first and second spark gaps. 2. The ignition circuit as set forth in claim 1 , wherein the first ignition subcircuit and the second ignition subcircuit constitute a series connection. 3. The ignition circuit as set forth in claim 1 , wherein the first varistor and the second varistor are part of a multi-contact varistor with at least one tap, with the tap being designed to be connected to a first of the at least one auxiliary electrode. 4. The ignition circuit as set forth in claim 1 , wherein the second ignition subcircuit is designed to be connected to a second lead of the series connection of the at least first and second spark gaps. 5. The ignition circuit as set forth in claim 1 , further comprising a gas discharge tube, with the first ignition subcircuit having the gas discharge tube and the first varistor as a series connection and being designed to ignite the first spark gap. 6. The ignition circuit as set forth in claim 1 , wherein one or more of the first varistor and the second varistor is a multi-contact varistor. 7. An overvoltage protection device with an ignition circuit comprising a series connection of at least first and second spark gaps, the first and second spark gaps suitable for limiting overvoltages corresponding to pulse shapes 8/20 μs and 10/350 μs with amplitudes between about 10 kA to about 200 kA, with the at least first and second spark gaps each being equipped with at least one auxiliary electrode and the ignition circuit having a first varistor and a second varistor, wherein the first and second varistors are suited to limiting overvoltages corresponding to pulse shape 8/20 μs with amplitudes between about 10 kA to about 100 kA, with the ignition circuit being designed to be connected to the at least one auxiliary electrode, with the ignition circuit having first and second ignition subcircuits, with the first ignition subcircuit having the first varistor and being designed to ignite the first spark gap, and with the second ignition subcircuit having the second varistor and being designed to ignite the second spark gap, wherein the first ignition subcircuit is designed to be connected to a first lead of the series connection of the at least first and second spark gaps. 8. The overvoltage protection device of claim 7 , wherein the first and second spark gaps are connected to each other in series such that electrodes at the shortest distance from the at least one auxiliary electrode are electrically contacted. 9. Use of a multi-contact varistor for triggering a spark gap of class I, wherein the multi-contact varistor is suited to limiting overvoltages corresponding to pulse shape 8/20 μs with amplitudes from about 10 to about 100 kA, wherein the multi-contact varistor comprises at least one tap of an internal series connection of varistors of the multi-contact varistor, and wherein the at least one tap is used to trigger the spark gap. 10. The use of the multi-contact varistor of claim 9 , wherein the multi-contact varistor contains at least one multiple-contact varistor.