Method for operating a measuring device and measuring device

The invention claimed is: 1. A method of operating a measuring device, the measuring device including a measurement tube for receiving or conveying a fluid, a first oscillation transducer and a second oscillation transducer arranged on a side wall of the measurement tube, and a control device, the method comprising: for a first measurement direction, driving the first oscillation transducer with the control device chronologically in succession for a respective mode-selective excitation of a first and a second oscillation mode of a first wave conducted in the side wall of the measurement tube; for a second measurement direction, driving the second oscillation transducer with the control device chronologically in succession for a respective mode-selective excitation of a first and a second oscillation mode of a second wave conducted in the side wall of the measurement tube; wherein the first wave thus excited is conducted either directly in the side wall or indirectly in the side wall and through the fluid to the second oscillation transducer and recorded there, and the second wave thus excited is conducted either directly in the side wall or indirectly in the side wall and through the fluid to the first oscillation transducer and recorded there, for determining respective measurement data for the respective measurement direction and oscillation mode; and determining, with the control device, result information that relates to a property of the fluid or a state of the measuring device from the measurement data for both measurement directions and both oscillation modes; and initially mode-selectively exciting the first oscillation mode by the first and second oscillation transducers and recording measurement values for the first oscillation mode for both measurement directions; and subsequently mode-selectively exciting the second oscillation mode by the first and second oscillation transducers and recording measurement values for the second oscillation mode for both measurement directions. 2. The method according to claim 1 , which comprises exciting oscillation modes with equal frequency as the first oscillation mode and the second oscillation mode, and/or generating the first and second oscillation modes as oscillation modes of a Lamb wave. 3. The method according to claim 1 , wherein the result information relates to at least one parameter selected from the group consisting of a temperature of the fluid, a static pressure of the fluid, a type of the fluid, a composition of the fluid, and a presence of deposits in the measurement tube. 4. The method according to claim 1 , wherein the respective measurement data relate to a respective signal time of flight of the respective oscillation mode for the respective measurement direction between the first and second oscillation transducers and/or to a reception amplitude for the respective oscillation mode and measurement direction. 5. The method according to claim 4 , which comprises respectively determining a difference of the signal times of flight between the first and second measurement direction for the first and second oscillation modes, determining the result information as a function of the difference or of a ratio of the differences between the signal times of flight, and/or determining the result information as a function of a difference or of a ratio of the signal times of flight or reception amplitudes between the first and second oscillation modes for one given measurement direction. 6. The method according to claim 1 , wherein at least one of the first or second oscillation transducers comprises a plurality of oscillation elements, and the method comprises carrying out the mode-selective excitation of at least one of the first or second oscillation modes by exiting partial waves conducted in the side wall, which are superimposed to form the respective conducted wave, in a plurality of mutually separated excitation regions of the side wall by at least one of the oscillation elements, which is oscillation-coupled to the respective excitation region, and driving the oscillation elements to at least partially suppress the respective other oscillation mode by destructive interference of the partial waves. 7. The method according to claim 6 , which comprises carrying out the excitation of the oscillation elements such that oscillation patterns of a first and a second of the oscillation elements correspond to one another with a predetermined relative polarity and/or a predetermined relative phase shift, and wherein the predetermined relative polarities and/or phase shifts used for the mode-selective excitation of the first oscillation mode and for the mode-selective excitation of the second oscillation mode differ from one another. 8. The method according to claim 6 , which comprises, for the mode-selective excitation of the first and/or second oscillation mode, driving a first and a second of the oscillation elements in such a way that a time profile of the oscillation amplitude of the second oscillation element corresponds to a time profile of the oscillation amplitude of the first oscillation element delayed by a delay time. 9. The method according to claim 1 , which further comprises: for at least one of the measurement directions, mode-selectively exciting a further mode of the wave conducted in the side wall of the measurement tube by one of the oscillation transducers and conducting the further mode wave either directly in the side wall or indirectly in the side wall and through the fluid to the respectively other oscillation transducer and recording the further mode wave there in order to determine further measurement data for the further oscillation mode, wherein an oscillation frequency of the further mode differs from the oscillation frequency of the first and/or second mode; and determining the result information as a function of the further measurement data. 10. The method according to claim 1 , which comprises determining the result information from the measurement data by an algorithm which is trained by a machine learning method. 11. The method according to claim 1 , wherein the measuring device is a flow meter. 12. A measuring device, comprising: a measurement tube disposed to receive or convey a fluid; a first oscillation transducer and a second oscillation transducer each arranged on a side wall of said measurement tube; and a control device connected to said first and second oscillation transducers and configured for carrying out the method according to claim 1 . 13. The measuring device according to claim 12 being a flow meter.