Tolerance and wear compensation of a fuel pump

The invention claimed is: 1. A method for determining an inflection point (OP) of a parameter profile (i, n) representative of a component tolerance and a state of wear of a fuel pump ( 12 ), wherein the fuel pump is provided for a fuel supply system ( 2 ) for use in a device equipped with an internal combustion engine, wherein the method comprises: under defined conditions, at least partially actively shutting off a fuel-conducting point ( 26 , 20 b ) of a feed line of the fuel supply system ( 2 ) downstream of the fuel pump ( 12 ), so as to at least reduce a flow of fuel to the internal combustion engine ( 28 ), by incrementally increasing, in steps, a rotational speed n of a fuel pump motor so as to increase a pressure upstream of the shut-off fuel-conducting point ( 26 , 20 b ) while simultaneously determining a phase current i that occurs in the fuel pump motor, wherein the rotational speed is increased until a valve ( 24 , 36 ) of the fuel supply system ( 2 ) opens (OP=opening point) so as to reduce the pressure, wherein individual rotational speed stages are assigned a determined value for the phase current i, and by approximating, using a graphical determination, and without using a pressure sensor, a first set of value pairs (i, n) below an inflection point (OP) by a first straight line, approximating of a second set of value pairs (i, n) above the inflection point (OP) by a second straight line, and determining an intersection point between the two straight lines, wherein the intersection point corresponds to the inflection point (OP) that corresponds to the opening time (OP) of the valve ( 24 , 36 ), wherein a rotational speed n OP is assigned to the intersection point. 2. The method as claimed in claim 1 , wherein the method is carried out during an overrun mode of the internal combustion engine or during an operating phase of the internal combustion engine under constant conditions. 3. The method as claimed in claim 2 , wherein the rotational speed n is increased until a valve ( 24 , 36 ) of a low-pressure part ( 30 ) of the fuel supply system ( 2 ) opens so as to reduce the pressure. 4. The method as claimed in claim 3 , wherein a valve ( 24 , 36 ) of a fuel-conducting return line of the low-pressure part ( 30 ) opens so as to reduce the pressure. 5. The method as claimed in claim 4 , wherein the method is carried out repeatedly at regular intervals. 6. The method as claimed in claim 5 , wherein the method is carried out after a definable number of operating hours of the device or a definable kilometrage status of the vehicle. 7. The method as claimed in claim 6 , wherein the method is first carried out after a first number of operating hours of 1 to 3 hours (h) or a first kilometrage status of 20 to 100 km and after that carried out at intervals that respectively correspond to a multiple of the first number of operating hours or of the kilometrage status. 8. The method as claimed in claim 6 , wherein the method is first carried out after a first number of operating hours of 1 to 3 hours (h) or a first kilometrage of 20 to 100 km and after that after each refueling process of a fuel tank. 9. The method as claimed in claim 8 , wherein the rotational speed n is increased at least essentially in the form of a rotational speed ramp. 10. The method as claimed in claim 9 , wherein the rotational speed n assigned to the inflection point (OP) is stored in a non-volatile memory of a system-side control unit ( 8 ). 11. A non-transitory computer readable medium storing a computer program that, when executed by a program-controlled processor, causes the processor to perform the method as claimed in claim 1 . 12. A fuel supply system for use in a device having an internal combustion engine, comprising: a low-pressure part ( 30 ) having a fuel pump ( 12 ) drivable by an electric motor and configured to deliver fuel from a fuel tank ( 9 ), a shut-off unit for at least partially or completely actively shutting off a fuel-conducting point ( 26 , 20 b ) in a feed line of the fuel supply system ( 2 ) downstream of the fuel pump ( 12 ) so as to, under defined conditions, at least reduce or completely prevent a flow of fuel to the internal combustion engine ( 28 ), and at least one control unit ( 4 , 8 ) configured to perform the method as claimed in claim 1 as modeled by software. 13. The fuel supply system as claimed in claim 12 , further comprising a high-pressure part ( 32 ) configured to have a fluidic communication connection to the low-pressure part ( 30 ). 14. The fuel supply system as claimed in claim 13 , wherein the fuel supply system ( 2 ) comprises a high-pressure pump ( 20 ) configured to connect the low-pressure part ( 30 ) to the high-pressure part ( 32 ) and configured to form the shut-off unit. 15. The fuel supply system as claimed in claim 14 , further comprising a pump control unit ( 8 ) having a communication connection to the engine control unit ( 4 ). 16. The fuel supply system as claimed in claim 15 , wherein the low-pressure part ( 30 ) is configured such that in the non-shut-off state of the fuel-conducting point ( 26 , 20 b ) a fuel pressure of up to approximately 3.5 bar can be achieved in the low-pressure part ( 30 ) by the fuel pump ( 12 ), while in the at least partially or completely shut-off state of the fuel-connecting point ( 26 , 20 b ) a fuel pressure of up to approximately 3.9 bar, at which a valve ( 24 , 36 ) opens in order to reduce the pressure, can be achieved by the fuel pump ( 12 ). 17. The fuel supply system as claimed in claim 16 , wherein the valve ( 24 , 36 ) is assigned to a fuel-conducting return line of the fuel supply system ( 2 ). 18. A device having a fuel supply system ( 2 ) as claimed in claim 17 , the device being one selected from the group consisting of a vehicle and a stationary or mobile power generator.