Measuring system having a measuring transducer of vibration-type

The invention claimed is: 1. A measuring system for flowing media, said measuring system comprising: a measuring transducer of a vibration-type configured to convey a medium therethrough during operation, said measuring transducer comprising: a measuring tube, which extends with an oscillatory length between an inlet-side first measuring tube end and an outlet-side second measuring tube end, said measuring tube exhibiting a plurality of natural oscillation modes, wherein said measuring tube is configured to convey the medium; an oscillation exciter adapted to convert electrical excitation power into vibrations of said measuring tube; and an oscillation sensor configured to measure the vibrations of said measuring tube and to generate an oscillation signal representing the vibrations; and a transmitter electronics electrically connected to the measuring transducer and adapted to: provide a driver signal to the oscillation exciter, thereby supplying electrical excitation power to the oscillation exciter for effecting the vibrations of said measuring tube, provide said driver signal with a sinusoidal signal component of a first type with a signal frequency corresponding to an instantaneous eigenfrequency of a natural mode of oscillation of said measuring tube such that said measuring tube executes, at least partially, resonance oscillations with an oscillation frequency corresponding to the instantaneous eigenfrequency of said natural mode of oscillation, wherein the oscillation signal includes a sinusoidal signal component of a first type with a signal frequency that corresponds to the signal frequency of the signal component of the first type of the driver signal; provide said driver signal with a sinusoidal signal component of a second type, which deviates from each instantaneous eigenfrequency of said measuring tube by more than 1 Hz and/or by more than 1% of said eigenfrequency, wherein the driver signal and the oscillation signal are generated such that said measuring tube excites, at least partially, forced oscillations out of resonance and such that said oscillation signal includes a sinusoidal signal component of a second type having a signal frequency corresponding to said signal frequency of the signal component of the second type of the driver signal; generate, using the signal component of the first type of the oscillation signal, measured values that represent at least one of: a mass flow rate, a totaled mass flow, a density and a viscosity of the medium; and generate, using the signal component of the second type of the oscillation signal, a system status report that indicates at least one of: wear of the measuring tube exceeding a predetermined tolerance; that structural integrity of said measuring tube is no longer assured; that a deposit has formed on an inner surface of the measuring tube during operation; a loss of material of said measuring tube exceeding a predetermined tolerance; a crack has formed in said measuring tube; a change of oscillation characteristics of said measuring tube exceeding a predetermined tolerance; a change of an electrical impedance of said measuring transducer exceeding a predetermined tolerance; that a deviation of the measuring system from a reference state exceeds a predetermined tolerance; and that a change of at least one of: an electrical impedance of said oscillation exciter, an electro-mechanical transducer constant of said oscillation exciter, an electrical impedance of said oscillation sensor, and an electro-mechanical transducer constant of said oscillation sensor exceeds a predetermined tolerance. 2. The measuring system as claimed in claim 1 , wherein: the signal frequency of said sinusoidal signal component of the second type of the driver signal deviates from each instantaneous eigenfrequency of said measuring tube by more than 10 Hz. 3. The measuring system as claimed in claim 1 , wherein: the signal frequency of said sinusoidal signal component of the second type of the driver signal deviates from each instantaneous eigenfrequency of said measuring tube by more than 10% of said eigenfrequency. 4. The measuring system as claimed in claim 1 , wherein: the transmitter electronics is adapted to generate, using the signal component of the second type of the oscillation signal, a system status report that signals that the structural integrity of said measuring tube is no longer assured as a result of at least one of: material removal, overloading, crack formation, and material fatigue. 5. The measuring system as claimed in claim 1 , wherein: the measuring tube is U-shaped. 6. The measuring system as claimed in claim 1 , wherein: the measuring tube is V-shaped. 7. The measuring system as claimed in claim 1 , wherein: the signal frequency of said sinusoidal signal component of the second type of the oscillation signal does not correspond to any of the instantaneous eigenfrequencies of said measuring tube. 8. The measuring system as claimed in claim 1 , wherein: the transmitter electronics is adapted to generate the status report in a visually perceptible manner. 9. The measuring system as claimed in claim 1 , wherein: the transmitter electronics is adapted to generate the status report in an acoustically perceptible manner. 10. The measuring system as claimed in claim 1 , wherein: the transmitter electronics is adapted to generate the system status report in the form of an alarm. 11. The measuring system as claimed in claim 1 , wherein: said transmitter electronics includes a data memory for measured values produced by the measuring system, in which data memory is stored a data set of measured values produced during operation of the measuring system and representing an operating state of the measuring system, said data set including system parameter measured values for different system parameters characterizing the measuring system and said data set produced based on at least one of: the signal component of the second type of the driver signal and the signal component of the second type of said sensor signal from said oscillation sensor. 12. The measuring system as claimed in claim 11 , wherein the data set includes at least one of: a system parameter measured value for the signal component of the second type of said driver signal provided to said oscillation exciter during operation of the measuring system; a system parameter measured value for the signal component of the second type of the oscillation signal generated by said measuring transducer during operation of the measuring system; and a system parameter measured value derived from the signal component of the second type of the driver signal provided to said oscillation exciter and derived from the signal component of the second type of said oscillation signal generated by said measuring transducer during operation of the measuring system. 13. The measuring system as claimed in claim 11 , wherein: said data set includes media parameter measured values for parameters characterizing the medium and said data set produced based on at least one of: the signal component of the first type of the driver signal and the signal component of the first type of said at least one sensor signal. 14. The measuring system as claimed in claim 1 , wherein: the driver signal simultaneously contains the signal component of the first type and the signal component of the second type, whereby said measuring tube, excited by said oscillation exciter, simultaneously executes partially resonance oscillations with an oscillation frequency corresponding to the instantaneous eigenfrequency of the mode