Magnetic flowmeter having in phase noise compensation

1. In an electromagnetic flowmeter provided with a flow tube through which is conducted the liquid to be metered, excitation coils to establish a magnetic field in the tube transverse to the direction of flow and a pair of electrodes disposed at diametrically opposed positions, whereby flowing liquid intersecting said field induces a signal in said liquid which is transferred to said electrodes and conducted by signal leads to a signal output;

• a unitary compensating system for eliminating in phase noise components from the signal, said system comprising;
  
  A. a circuit including a pair of first compensating coils for sensing a first class of in-phase noise arising from asymmetry of the main magnetic fluxes produced by said excitation coils in respective regions of the tube separated by a plane parallel to the lines of flux and including said electrodes, each of the first coils being disposed in one of these regions, and means connecting said first coils to first class output terminals to cause the voltage induced in one coil to oppose that of the other to produce an error voltage at said first class output terminals reflecting said asymmetry;
  
  B. a second compensating coil for sensing a second class of in-phase noise induced in a loop constituted by said signal leads in combination with the liquid in said tube bridging said electrodes, said noise being induced in said loop by reason of asymmetrical leakage magnetic fluxes arising from said asymmetrical main fluxes, said second coil being defined by said first compensating coils and a pair of lead wires;
  
  C. common output terminals connected through said pair of lead wires of the second coil to said first class output terminals whereby yielded at said common output terminals is a combined error voltage reflecting both the first class noise resulting from asymmetry of the main magnetic fluxes and second class noise resulting from the leakage magnetic fluxes; and
  
  D. means to apply said combined error voltage developed at said common output terminals in opposition to the induced signal appearing at said signal output to provide a noise-compensating output which is corrected for said first and second class in-phase noises.