Method for operating a system for a thermodynamic cycle with a multi-flow evaporator, control unit for a system, system for a thermodynamic cycle with a multi-flow evaporator, and arrangement of an internal combustion engine and a system

We claim: 1. A method for operating a system for a thermodynamic cycle with a multi-flow evaporator having at least two evaporator flow channels, the method comprising the steps of: making the evaporator flow channels to approximate each other with respect to at least one operating parameter of the individual evaporator flow channels, or controlling a pressure drop across the evaporator, wherein the evaporator flow channels are made to approximate each other by variation of control variables for control elements that are assigned to the individual evaporator flow channels, which control elements limit flow through the evaporator flow channels; and renormalizing the control variables so that the control element actuated by the control variable with a largest value is opened to a maximum extent. 2. The method according to claim 1 , wherein the evaporator flow channels are made to approximate each other with respect to a flow rate of a working medium or with respect to a temperature of the working medium downstream from a vaporization area of the individual evaporator flow channels. 3. The method according to claim 1 , including controlling the pressure drop across the evaporator by actuation of individual control elements assigned to the individual evaporator flow channels. 4. The method according to claim 3 , wherein the control elements are valves. 5. The method according to claim 1 , including varying the control variables by controlling the pressure drop. 6. The method according to claim 1 , including calculating a desired flow rate for a working medium in the individual evaporator flow channels as a total mass flow rate of the system divided by a total number of evaporator flow channels. 7. The method according to claim 2 , including calculating a desired temperature for the working medium downstream of the vaporization area as an average value of temperatures of the working medium downstream of the vaporization area of the individual evaporator flow channels or separately measuring the average temperature. 8. The method according to claim 1 , including reading out a desired pressure drop from a characteristic diagram as a function of at least one operating parameter of the system. 9. The method according to claim 2 , including operating the system with superheating of the working medium or in a wet steam region. 10. A control unit for a system for a thermodynamic cycle with a multi-flow evaporator having flow channels, wherein the control unit is constructed to make the evaporator flow channels approximate each other with respect to at least one operating parameter of the individual evaporator flow channels or wherein the control unit is constructed to control a pressure drop across the evaporator, wherein the evaporator flow channels are made to approximate each other by variation of control variables for control elements that are assigned to the individual evaporator flow channels, which control elements limit flow through the evaporator flow channels, and the control variables are renormalized so that the control element actuated by the control variable with a largest value is opened to a maximum extent. 11. A system for a thermodynamic cycle with a multi-flow evaporator comprising at least two evaporator flow channels, wherein each evaporator flow channel has its own control element arranged and set up to vary a flow cross section of the associated evaporator flow channel; and a control unit according to claim 10 , the control unit being functionally connected to the control elements and configured to make the evaporator flow channels approximate each other with respect to at least one operating parameter of the individual evaporator flow channels or automatically to control a pressure drop across the evaporator through variation of control variables for the control elements.