Magnetic-inductive flow meter and method for operating a magnetic-inductive flow meter

1 - 11 . (canceled) 12 . A magnetic-inductive flow meter, comprising: a measuring tube adapted to conduct a flowable medium and including a wall; at least three measuring electrodes disposed in the wall such that each measuring electrode is in galvanic contact with the flowing medium; at least one magnetic-field-generating device configured to generate a magnetic field that passes through the measuring tube; a measuring circuit configured to determine at least one measurement variable, wherein measured values of a first measurement variable of the at least one measurement variable are determined at a first measuring electrode pair, which includes two measuring electrodes of the at least three measuring electrodes; and an analysis circuit configured to determine a Reynolds number and/or a kinematic viscosity value of the medium in the measuring tube using measured values of the first measurement variable and a second measurement variable, which differs from the first measurement variable, wherein measured values of the second measurement variable are determined at a second measuring electrode pair or at a third measuring electrode relative to a reference potential. 13 . The magnetic-inductive flow meter of claim 12 , wherein the at least three measuring electrodes are arranged in the measuring tube such that, in a test measurement, quotients of current measured values of the first and second measurement variables correspond bijectively to the Reynolds number (Re) of the flowing medium in the measuring tube, at least within a Reynolds-number range of 1,000≤Re≤1,000,000. 14 . The magnetic-inductive flow meter of claim 13 , wherein the quotients of current measured values of the first and second measurement variables correspond bijectively to the Reynolds number (Re) of the flowing medium in the measuring tube, at least within a Reynolds-number range of 10,000≤Re≤100,000. 15 . The magnetic-inductive flow meter of claim 12 , wherein the at least three measuring electrodes are arranged substantially in a cross-sectional plane, wherein a first radius intersecting a second measuring electrode of the first measuring electrode pair and a second radius intersecting the third measuring electrode span an angle of at least 20°, wherein the measuring circuit is configured to determine measured values of the first measurement variable between the second measuring electrode and a first second measuring electrode of the first second measuring electrode pair and to determine measured values of the second measurement variable between the first and third measuring electrodes or at the third measuring electrode relative to a reference potential. 16 . The magnetic-inductive flow meter of claim 15 , wherein the angle spanning the first radius and the second radius is at least 40° but no more than 60°. 17 . The magnetic-inductive flow meter of claim 12 , wherein a first measuring electrode axis intersecting the first measuring electrode pair and a second measuring electrode axis intersecting the third measuring electrode and a fourth measuring electrode are substantially parallel, wherein the measuring circuit is configured to determine measured values of the first measurement variable between the first measuring electrode pair and to determine measured values of the second measurement variable between the third and fourth measuring electrodes. 18 . The magnetic-inductive flow meter of claim 12 , wherein, in a test measurement, the first measurement variable behaves substantially proportionally to a flow rate of the medium within a Reynolds-number range of 10,000≤Re≤1,000,000, and wherein, in the test measurement, a change in the second measurement variable within a Reynolds-number range of 10,000≤Re≤1,000,000 with increasing Reynolds number is not constant. 19 . The magnetic-inductive flow meter of claim 12 , wherein, in a test measurement, the medium is a Newtonian fluid, wherein, in the test measurement, the flow meter is introduced into a pipeline with a straight inlet section of at least DN 20 such that a substantially symmetrical flow profile is present in a measurement region, and wherein the measuring tube ( 1 ) has a diameter of DN 80. 20 . The magnetic-inductive flow meter of claim 12 , wherein the magnetic-field-generating device includes two oppositely attached coils that are connected in series in the same direction. 21 . A method for operating a magnetic-inductive flow meter, the method comprising: providing a magnetic-inductive flow meter according to claim 12 ; detecting a measured value of the first measurement variable and a measured value of the second measurement variable, wherein the respective measured values of the first and second measurement variables are determined at different measuring electrode pairs; and determining a Reynolds number dependent upon the measured values of the first and second measurement variables. 22 . The method of claim 21 , further comprising calculating a corrected flow rate and/or a corrected volumetric flow using a correction factor, which depends upon the determined Reynolds number. 23 . The method of claim 21 , further comprising determining a kinematic viscosity value of the medium using measured values of the first or the second measurement variable and the determined Reynolds number. 24 . The method of claim 21 , wherein a map that assigns Reynolds numbers to quotients of the first and second measurement variables is bijective, at least within a Reynolds-number range of 1,000≤Re≤1,000,000. 25 . The method of claim 24 , wherein the map that assigns Reynolds numbers to quotients of the first and second measurement variables is bijective, at least within a Reynolds-number (Re) range of 10,000≤Re≤100,000.