Method performed by a control unit for controlling energy flows of a vehicle

The invention claimed is: 1. A method performed by a control unit for controlling energy flows of a vehicle, wherein the vehicle comprises an energy system which comprises a plurality of energy subsystems, wherein within each energy subsystem one form of energy is used, and wherein the energy subsystems are operationally connected by converters, wherein converters are devices converting at least one form of energy to another form of energy, the method comprising setting, via the control unit, a unitary energy price for a quantity of energy used within a respective energy subsystem continuously, continuously controlling energy flows within the vehicle via the control unit at a first sample frequency by setting a respective unitary energy price for a respective energy subsystem for a sample interval t+n, wherein the respective unitary energy price is dependent on a total energy demand and a total energy supply of the respective energy subsystem, and during the sample interval t+n; providing a quantity of power to a first energy subsystem from a second energy subsystem, wherein the provided quantity of power corresponds to a determined supplied quantity of power of the converters at the unitary energy price of the first energy subsystem, wherein the quantity of power provided is limited by a power limitation of a common converter providing a quantity of power to the first energy subsystem from the second energy subsystem, setting, via the control unit, a price limit for a converter converting energy to an energy subsystem, providing, via the converter, energy to the first energy subsystem from the second energy subsystem only if a unitary energy price of the second energy subsystem is lower than the price limit of the converter, continuously updating, via the control unit, the price limit of the converter according to a second sample frequency, and wherein the second sample frequency is longer than the first sample frequency. 2. A method according to claim 1 , wherein the energy systems at least comprises a mechanical energy system and a propulsion energy system. 3. A method according to claim 1 , wherein the respective price limits are provided with a prioritisation, such that a more prioritised energy subsystem is provided with a higher price limit. 4. A method according to claim 1 , wherein the control unit is; setting a common price limit for all converters converting energy from one common energy subsystem to another common energy subsystem. 5. A method according to claim 1 , wherein the control unit is; setting respective price limit for respective energy subsystem dependent on a driver command. 6. A method according to the preceding claim 5 , wherein the driver command is at least one among; selecting a driving mode, or selecting a driver specific vehicle setting. 7. A method according to claim 1 , wherein the control unit is; setting respective price limit dependent on at least one ambient condition. 8. A method according to claim 7 , wherein the at least one ambient condition is one of; topography, ambient temperature, air humidity, indication of slippery road conditions, driving schedule, wet conditions, or sunny conditions. 9. A method according to claim 1 , wherein the price limits are predetermined. 10. A non-transitory computer readable medium carrying a computer program for performing a method for controlling energy flows of a vehicle when the computer program is run by a control unit, wherein the vehicle comprises an energy system which comprises a plurality of energy subsystems, wherein within each energy subsystem one form of energy is used, and wherein the energy subsystems are operationally connected by converters, wherein the converters are devices converting at least one form of energy to another form of energy, the method comprising: setting, via the control unit, a unitary energy price for a quantity of energy used within p respective energy subsystem continuously, continuously controlling energy flows within the vehicle via the control unit at a first sample frequency by setting a respective unitary energy price for a respective energy subsystem for a sample interval t+n, wherein the respective unitary energy price is dependent on a total energy demand and a total energy supply of the respective energy subsystem, and during the sample interval t+n; providing a quantity of power to a first energy subsystem from a second energy subsystem, wherein the provided quantity of power corresponds to a determined supplied quantity of power of the converters at the unitary energy price of the first energy subsystem, wherein the quantity of power provided is limited by a power limitation of a common converter providing a quantity of power to the first energy subsystem from the second energy subsystem, setting, via the control unit, a price limit for a converter converting energy to an energy subsystem, providing, via the converter, energy to the first energy subsystem from the second energy subsystem only if a unitary energy price of the second energy subsystem is lower than the price limit of the converter, continuously updating, via the control unit, the price limit of the converter according to a second sample frequency, and wherein the second sample frequency is longer than the first sample frequency.