Monitoring device for a slipform paver for monitoring the compaction of concrete and a method for monitoring the compaction of concrete during operation of a slipform paver

What is claimed is: 1. A method for monitoring, during operation of a slipform paver, the compaction of concrete introduced into a slipform of the slipform paver via at least one concrete compacting device which has an asynchronous motor for driving an unbalanced mass which generates vibrations, the method comprising: monitoring a stator current of the asynchronous motor of the at least one concrete compacting device; and determining a change in the compaction of the concrete introduced into the slipform of the slipform paver based on an analysis of the stator current; and generating a control signal signaling the change in the compaction of the concrete introduced into the slipform of the slipform paver. 2. The method of claim 1 , wherein an amplitude spectrum of the stator current is determined in order to analyse the stator current. 3. The method of claim 1 , wherein the amplitude spectrum of the stator current is determined by a discrete-time Fourier transformation (DFT) of the stator current. 4. The method of claim 1 , wherein: a distribution of individual harmonics, which are attributable to the unbalanced mass, over the frequency of the spectral components is continuously determined and is compared with a distribution of individual harmonics over the frequency of the spectral components, which distribution is characteristic of a predefined speed of the asynchronous motor, and the control signal is generated when a deviation occurs in the distribution of the individual harmonics. 5. The method of claim 1 , wherein: a distribution of individual harmonics, which are attributable to the unbalanced mass, over the frequency of the spectral components is continuously determined, a speed of the asynchronous motor is continuously determined based on the distribution of individual harmonics over the frequency of the spectral components and over the frequency of the stator current, and the control signal is generated when a deviation in the speed occurs. 6. The method of claim 5 , wherein a threshold value for amplitudes of the harmonics is predefined for the analysis of the stator current of the asynchronous motor, and the distribution of individual harmonics over the frequency of the spectral components that are above the threshold value is determined. 7. The method of claim 5 , wherein the continuously determined speed of the asynchronous motor is compared with a predefined limit value, the control signal being generated when the limit value is not reached. 8. The method of claim 1 , further comprising: generating a first output signal indicating improper compaction of the concrete during operation of the slipform paver when the control signal is generated, and generating a second output signal indicating proper compaction of the concrete during operation of the slipform paver when the control signal is not generated. 9. A monitoring device for monitoring the compaction of concrete introduced into a slipform of a slipform paver via at least one concrete compacting device which has an asynchronous motor for driving an unbalanced mass which generates vibrations, the monitoring device comprising: a current sensor configured to generate an output representing a stator current of the asynchronous motor of the at least one concrete compacting device; and a data processor configured to determine a change in the compaction of the concrete introduced into the slipform of the slipform paver based on an analysis of the stator current of the asynchronous motor, and to generate a control signal signaling a change in the compaction of the concrete introduced into the slipform of the slipform paver. 10. The slipform paver of claim 9 , wherein an amplitude spectrum of the stator current is determined in order to analyse the stator current. 11. The monitoring device of claim 9 , wherein an amplitude spectrum of the stator current is determined in order to analyse the stator current. 12. The slipform paver of claim 11 , wherein the stator current is sampled, and the amplitude spectrum of the stator current is determined by a discrete-time Fourier transform (DFT) of the stator current. 13. The monitoring device of claim 11 , wherein the stator current is sampled, and the amplitude spectrum of the stator current is determined by a discrete-time Fourier transform (DFT) of the stator current. 14. The monitoring device of claim 9 , wherein: a first distribution of individual harmonics over a frequency of the spectral components is continuously determined, said first distribution being attributable to the unbalanced mass, and is compared with a second distribution of individual harmonics over the frequency of the spectral components, said second distribution being characteristic of a predefined speed of the asynchronous motor, and the control signal is generated when a deviation occurs, which control signal signals a change in the compaction of the concrete introduced into the slipform of the slipform paver. 15. The monitoring device of claim 9 , wherein: a distribution of individual harmonics, which are attributable to the unbalanced mass, over the frequency of the spectral components is continuously determined, a speed of the asynchronous motor is continuously determined based on the distribution of individual harmonics over the frequency of the spectral components and over a network frequency of the stator current, and the control signal is generated when a deviation in the speed occurs, which control signal signals a change in the compaction of the concrete introduced into the slipform of the slipform paver. 16. The monitoring device of claim 15 , wherein the continuously determined speed of the asynchronous motor is compared with a predefined limit value, the control signal being generated when the limit value is not reached. 17. The monitoring device of claim 15 , wherein a threshold value for the amplitudes of the harmonics is predefined for the analysis of the stator current of the asynchronous motor, the distribution of individual harmonics over the frequency of the spectral components that are above the threshold value being determined. 18. The monitoring device of claim 9 , further comprising a signal unit configured to generate a first output signal indicating improper compaction of the concrete during operation of the slipform paver when the signal unit receives the control signal, and to generate a second output signal indicating proper compaction of the concrete during operation of the slipform paver when the signal unit does not receive the control signal. 19. The monitoring device of claim 9 , wherein the current sensor comprises a current transformer having a primary side coupled to receive the stator current and a secondary side coupled to a resistor, wherein a voltage across said resistor is representative of the stator current. 20. A slipform paver comprising: a slipform; at least one concrete compacting device which has an asynchronous motor for driving an unbalanced mass which generates vibrations; a current sensor configured to generate an output representing a stator current of the asynchronous motor of the at least one concrete compacting device; and a data processor configured to determine a change in the compaction of the concrete introduced into the slipform of the slipform paver based on an analysis of the stator current of the asynchronous motor.