Ultrasonic time of flight flow measuring device and method

The invention claimed is: 1. A method for operating a measuring device, the measuring device serving the purpose of determining a fluid quantity relating to at least one of a fluid or a flow of the fluid, the method comprising the following steps: providing a measuring tube for at least one of receiving the fluid or conducting the fluid flow therethrough; providing first and second oscillation transducers disposed at a distance from one another along the measuring tube and defining a propagation path therebetween including only components of the measuring device; recording a first time of flight at the second oscillation transducer after an ultrasound signal excited by the first oscillation transducer is conducted along the propagation path to the second oscillation transducer; recording a second time of flight at the first oscillation transducer after an ultrasound signal excited by the second oscillation transducer is conducted along the propagation path to the first oscillation transducer; subsequently checking for a fulfillment of a report condition related to zero flow error, the fulfillment depending on a time-of-flight difference between the first and second times of flight; and upon the report condition being fulfilled, performing at least one of: outputting a report to a user or sending a report message to an external device or adapting at least one correction parameter used in determining the fluid quantity. 2. The method according to claim 1 , which further comprises fulfilling the report condition or only permitting the report condition to be fulfilled when a deviation between the time-of-flight difference and a reference value for the time-of-flight difference exceeds or reaches a predetermined deviation limit value. 3. The method according to claim 2 , which further comprises recording a temperature of at least one of the fluid or at least one component of the measuring device, and additionally making the fulfillment of the report condition dependent on the recorded temperature. 4. The method according to claim 3 , which further comprises specifying the reference value as a function of the recorded temperature. 5. The method according to claim 1 , which further comprises, repeatedly at time intervals: recording a respective first time of flight at the second oscillation transducer after an ultrasound signal excited by the first oscillation transducer is conducted along the propagation path to the second oscillation transducer; recording a respective second time of flight at the first oscillation transducer after an ultrasound signal excited by the second oscillation transducer is conducted along the propagation path to the first oscillation transducer; subsequently determining a respective time-of-flight difference between the respective first and second times of flight; and making the fulfillment of the report condition dependent on a plurality of the time-of-flight differences or on at least three of the time-of-flight differences. 6. The method according to claim 1 , which further comprises: determining a third time of flight by additionally conducting the ultrasound signal, excited by the first oscillation transducer to determine the first time of flight, through the fluid to the second oscillation transducer and recording the ultrasound signal at the second oscillation transducer; determining a fourth time of flight by additionally conducting the ultrasound signal, excited by the second oscillation transducer to determine the second time of flight, through the fluid to the first oscillation transducer and recording the ultrasound signal at the first oscillation transducer; and determining the fluid quantity as a function of the time-of-flight difference between the third and fourth times of flight. 7. The method according to claim 1 , which further comprises relating the fluid quantity to a flow rate of the fluid through the measuring tube, and at least one of only fulfilling the report condition or only determining the time-of-flight difference between the first and second times of flight, when the fluid quantity continuously exceeds a flow-rate limit value over at least one predetermined time interval. 8. The method according to claim 1 , which further comprises: recording a third time of flight at the second oscillation transducer after an ultrasound signal excited by the first oscillation transducer is conducted through the fluid to the second oscillation transducer; recording a fourth time of flight at the first oscillation transducer after an ultrasound signal excited by the second oscillation transducer is conducted through the fluid to the first oscillation transducer; and determining the fluid quantity as a function of a corrected time-of-flight difference determined by adding the correction parameter from the first and second times of flight to the time-of-flight difference between the third and fourth times of flight or subtracting the correction parameter from the time-of-flight difference between the third and fourth times of flight. 9. The method according to claim 1 , wherein, the ultrasound signal excited by the first oscillation transducer conducted along the propagation path to the second oscillation transducer comprises exciting a Lamb wave as the ultrasound signal conducted in a wall of the measuring tube for determination of the fluid quantity by at least one of the first or second oscillation transducers or separating at least one of the first or second oscillation transducers from the fluid by the wall of the measuring tube. 10. A measuring device for determining a fluid quantity relating to at least one of a fluid or a flow of the fluid, the measuring device comprising: a measuring tube for at least one of receiving the fluid or conducting the fluid flow therethrough; first and second oscillation transducers disposed at a distance from one another along said measuring tube and defining a propagation path therebetween including only components of the measuring device; and a control device for driving said first and second oscillation transducers and evaluating measurement data recorded by said first and second oscillation transducers, said control device being adapted for: recording a first time of flight at said second oscillation transducer after an ultrasound signal excited by said first oscillation transducer is conducted along said propagation path to said second oscillation transducer; recording a second time of flight at said first oscillation transducer after an ultrasound signal excited by said second oscillation transducer is conducted along said propagation path to said first oscillation transducer; subsequently checking for a fulfillment of a report condition related to zero flow error, said fulfillment depending on a time-of-flight difference between said first and second times of flight; and upon said report condition being fulfilled, performing at least one of: outputting a report to a user or sending a report message to an external device or adapting at least one correction parameter used in determining the fluid quantity.