System and method for estimating engine temperature of an engine

The invention claimed is: 1. A method for monitoring the temperature of a motor (M) with an electromechanically drivable motor shaft using a differential equation system (DGL) which describes the thermal behavior of the motor (M), the motor (M) being in a system that includes: a sensor based on a thermal model (MOD), which describes thermal behavior of the motor (M); a measuring means for determining electrical input power (P) of the motor (M); and a measuring means for recording shaft speed n of the motor shaft, wherein an evaluation device is also provided, which is configured to determine, respectively, current motor temperature of the motor (M) from the input power (P), a reference temperature T Ref , the determined shaft speed n, and the thermal model (MOD); the method comprising the following steps: a. recording the electrical input power of the motor; b. calculating the mechanical shaft power from the recorded speed of the motor (M) and determining the corresponding torque of the motor (M); c. calculating the thermal power loss that leads to the increase in motor temperature, in particular by subtracting the mechanical shaft power from the electrical input power; and d. the determined thermal power loss is fed into the differential equation system (DGL) as an input variable for solving the differential equation system (DGL), and a temperature increase is calculated therefrom, in particular using an additional reference temperature T ref , which is added to the temperature increase in order to determine the motor temperature therefrom. 2. The method according to claim 1 , wherein the differential equation system (DGL), as a modular system, enables several alternative solution methods for determining the temperature, by means of numerical integration, by means of an analog calculation method based on an analog computer, or by means of an analog calculation method by means of a model comprising passive components. 3. The method according to claim 1 , wherein the differential equation system (DGL) for determining the motor temperature is solved by numerical integration. 4. The method according to claim 3 , wherein the electrical input power of the motor is recorded by measuring an intermediate circuit voltage and an intermediate circuit current and by multiplying the two measured values by means of a microcomputer or programmable circuits. 5. The method according to claim 3 , wherein a voltage proportional to the speed is generated from a phase voltage of the motor to be measured with the aid of an analog frequency-voltage conversion in order to determine the shaft power therefrom. 6. The method according to claim 1 , wherein the solution of the differential equation system (DGL) for determining the motor temperature is calculated analogously by using a corresponding circuit in the manner of an analog computer with corresponding computer modules or on the basis of freely programmable circuits or by means of suitable RC modules and passive components. 7. The method according to claim 1 , wherein the electrical input power of the motor is recorded by measuring an intermediate circuit voltage and an intermediate circuit current and by multiplying the two measured values by means of a microcomputer or programmable circuits. 8. The method according to claim 7 , wherein the speed is determined by measuring the frequency of the phase voltage and determining the corresponding torque from a correspondingly stored characteristic map, or by means of the q component of the current iq, or by means of a strain gauge. 9. The method according to claim 7 , wherein a voltage proportional to the speed is generated from a phase voltage of the motor to be measured with the aid of an analog frequency-voltage conversion in order to determine the shaft power therefrom. 10. The method according to claim 1 , wherein the speed is determined by measuring the frequency of the phase voltage and determining the corresponding torque from a correspondingly stored characteristic map, or by means of the q component of the current iq, or by means of a strain gauge. 11. The method according to claim 10 , wherein a voltage proportional to the speed is generated from a phase voltage of the motor to be measured with the aid of an analog frequency-voltage conversion in order to determine the shaft power therefrom. 12. The method according to claim 1 , wherein a voltage proportional to the speed is generated from a phase voltage of the motor to be measured with the aid of an analog frequency-voltage conversion in order to determine the shaft power therefrom. 13. A method for monitoring the temperature of a motor (M) with an electromechanically drivable motor shaft using a differential equation system (DGL) which simulates the thermal behavior of the motor (M), the motor (M) being in a system that includes: a sensor based on a thermal model (MOD), which describes thermal behavior of the motor (M); a measuring means for determining electrical input power (P) of the motor (M); and a measuring means for recording shaft speed n of the motor shaft, wherein an evaluation device is also provided, which is configured to determine, respectively, current motor temperature of the motor (M) from the input power (P), a reference temperature T Ref , the determined shaft speed n, and the thermal model (MOD); the method comprising with the following steps: a. recording the electrical input power of the motor; b. calculating the mechanical shaft power from the recorded speed of the motor (M) and determining the corresponding torque of the motor (M); c. calculating the thermal power loss that leads to the increase in motor temperature, in particular by subtracting the mechanical shaft power from the electrical input power; and d. the determined thermal power loss is fed into the differential equation system (DGL) as an input variable for solving the differential equation system (DGL), and a temperature increase is calculated therefrom, in particular using an additional reference temperature T ref , which is added to the temperature increase in order to determine the motor temperature therefrom; wherein the differential equation system (DGL), as a modular system, enables several alternative solution methods for determining the temperature, by means of numerical integration, by means of an analog calculation method based on an analog computer, or by means of an analog calculation method by means of a model comprising passive components. 14. The method according to claim 13 , wherein the differential equation system (DGL) for determining the motor temperature is solved by numerical integration. 15. The method according to claim 13 , wherein the solution of the differential equation system (DGL) for determining the motor temperature is calculated analogously by using a corresponding circuit in the manner of an analog computer with corresponding computer modules or on the basis of freely programmable circuits or by means of suitable RC modules and passive components. 16. The method according to claim 13 , wherein the electrical input power of the motor is recorded by measuring an intermediate circuit voltage and an intermediate circuit current and by multiplying the two measured values by means of a microcomputer or programmable circuits. 17. The method according to claim 13 , wherein the speed is determined by measuring the frequency of the phase voltage and determining the corresponding torque from a correspondingly stored characteristic map, or by means of the q component of the current iq, or by means of a strain gauge.