Device for regulating a burner system

What is claimed is: 1. A method for regulating a burner system with at least one burner, at least one memory, and at least one ionization electrode arranged to lie in an area of a flame of the at least one burner during operation of the burner, the method comprising: recording an ionization current based on the at least one ionization electrode, setting an air volume flow rate of the burner system, based on the ionization current, storing, in the at least one memory, pairs consisting of air volume flow rate of the burner system and ionization current, forming a difference between a reciprocal value of a first ionization current for a first air volume flow rate and a reciprocal value of a second ionization current which was recorded prior to the first ionization current and associated with the first air volume flow rate, calculating a reciprocal value and a value of a displaced ionization current as the sum of the difference and a reciprocal value of a further ionization current, wherein the further ionization current and the displaced ionization current are associated with a second air volume flow rate of the burner system different from the first air volume flow rate of the burner system, filtering the reciprocal value or the value of the displaced ionization current using a filter constant on the reciprocal value or value of a historical ionization current which was recorded prior to the first ionization current and which is associated with the second air volume flow rate, such that a filtered ionization current and its reciprocal value are calculated as a result of the filtering, and calculating a second difference from a reciprocal value of the filtered ionization current and from a reciprocal value of the further ionization current. 2. A regulating device for regulating a burner system having at least one burner and at least one ionization electrode arranged to lie in an area of a flame of the at least one burner during operation of the burner system, wherein the regulation device is configured to: record an ionization current based on the at least one ionization electrode, set an air volume flow rate of the burner system based on the ionization current, store, in a memory of the regulation device, pairs consisting of air volume flow rate of the burner system and ionization current, determine a difference between a reciprocal value of a first ionization current and a first air volume flow rate and a reciprocal value of a second ionization current which was recorded prior to the first ionization current and which is associated with the first air volume flow rate, calculate the reciprocal value and the value of a displaced ionization current as the sum of the determined difference and of the reciprocal value of a further ionization current, wherein the further ionization current and the displaced ionization current are associated with a second air volume flow rate of the burner system that is different from the first air volume flow rate of the burner system, and filter the reciprocal value or the value of the displaced ionization current using a filter constant on the reciprocal value or value of a historical ionization current which was recorded prior to the first ionization current and which is associated with the second air volume flow rate, such that a filtered ionization current and its reciprocal value are calculated as result of the filtering; wherein the second ionization current was recorded under laboratory conditions at a new or little-aged ionization electrode. 3. A regulating device for regulating a burner system having at least one burner and at least one ionization electrode arranged to lie in an area of a flame of the at least one burner during operation of the burner system, wherein the regulation device is configured to: record an ionization current based on the at least one ionization electrode, set an air volume flow rate of the burner system based on the ionization current, store, in a memory of the regulation device, pairs consisting of air volume flow rate of the burner system and ionization current, determine a difference between a reciprocal value of a first ionization current and a first air volume flow rate and a reciprocal value of a second ionization current which was recorded prior to the first ionization current and which is associated with the first air volume flow rate, calculate the reciprocal value and the value of a displaced ionization current as the sum of the determined difference and of the reciprocal value of a further ionization current, wherein the further ionization current and the displaced ionization current are associated with a second air volume flow rate of the burner system that is different from the first air volume flow rate of the burner system, and filter the reciprocal value or the value of the displaced ionization current using a filter constant on the reciprocal value or value of a historical ionization current which was recorded prior to the first ionization current and which is associated with the second air volume flow rate, such that a filtered ionization current and its reciprocal value are calculated as result of the filtering; wherein the further ionization current was recorded under laboratory conditions at a new or little-aged ionization electrode. 4. The regulating device of claim 3 , wherein the regulation device is additionally embodied to calculate a second difference from a reciprocal value of the filtered ionization current and from a reciprocal value of the further ionization current. 5. The regulating device of claim 4 , wherein the regulation device is additionally embodied to add the second difference to the reciprocal value of a third ionization current and to obtain from said addition a displaced third ionization current, wherein the third ionization current was recorded at a point in time before first ionization current and belongs to the second air volume flow rate of the burner system. 6. The regulating device of claim 5 , wherein the regulation device is additionally embodied, to join together pairs consisting of air volume flow rate of the burner system and ionization current into a regulating curve and to store them. 7. The regulating device of claim 6 , wherein the regulation device is additionally embodied, to compute and/or to store the displaced third ionization current as part of a corrected regulating curve and/or to compute and/or to store from this ionization current, the correction, especially the deviation, from the original regulating curve. 8. The regulating device of claim 3 , wherein the value or the reciprocal value of the displaced ionization current are filtered on the value or reciprocal value of a historical ionization current, in that the value or reciprocal value of the displaced ionization current are reduced by a percentage and the value or the reciprocal value of the historical ionization current are increased by the same percentage. 9. The regulating device of claim 3 , wherein the regulation device is embodied to form a difference between the reciprocal value of a first ionization current for a first air volume flow rate and a reciprocal value of a second ionization current, which was recorded at a point in time before the first ionization current, and belongs to the first air volume flow rate or essentially belongs to the first air volume flow rate, and wherein the formation of the difference only occurs for the first time after an hour or after two hours or after five hours or after ten hours or after 20 hours or after one day or after two days or after 5 days or after 10 or after 20 days. 10. The regulating device of claim 3 , wherein the regulation device is embodied, on the basis of the at le