SU1185090A1 - Method and apparatus for measuring the consumption of electroconductive media - Google Patents

Abstract

1. A method of measuring the flow rate of electrically conductive media by creating a magnetic field of excitation in the controlled area and measuring the fast component of a secondary magnetic field, characterized in that, in order to improve measurement accuracy, the radial component of the magnetic field of the field and the flow rate t according to the ratio of the radial component of the magnetic field of excitation and the velocity component of the secondary magnetic field. 2. A device for measuring the flow rate of electrically conductive media, comprising a primary transducer consisting of a pipeline section with coaxial excitation coils and receiving coils placed on it, and a transmitting transducer whose input is connected to the receiving coils, in order to improve the accuracy measurements, it is equipped with additional saddle-shaped coils placed on the outer surface of the receiving coils and covering them around the perimeter, and the size of the additional coils in the direction enii pipe axis is a quarter of the internal diameter of the pipeline, and the additional coil outputs are also connected to the converter before tsemu.

Description

The invention relates to flow measurement and can be used to measure the flow rate of electrically conductive media in metallurgical, chemical and other industries, the purpose of the invention is to improve the accuracy of flow measurement. FIG. 1 is a block diagram of the proposed device for measuring consumption in FIG. 2 - primary converter circuit. The device consists of a primary converter containing a section of pipeline 1, on which the excitation winding 2 and the two-section receiving winding 3 and 4 are coaxially placed. Additional saddle-shaped windings 5 and 6 are placed on the surface of the receiving windings. Winding 3-6 are connected to the front converter consisting of instrumental amplifier 7, a phase-sensitive amplifier 8, a voltage converter 9 into a unified output signal, an internal indicator 10 and a generator of the excitation current 11, to which is connected 2 excitation coil. The number of turns of the windings is selected, for example, so that the signal removed from the additional windings is equal to the speed signal at the nominal flow rate. Additional windings may also be located under the receiving windings. The flow measurement is carried out as follows. In the presence of flow in the receiving windings 3 and 4, a signal is induced, the proportional velocity of the controlled medium and the radial component of the induction of the magnetic excitation field. This signal is fed to the input of the instrumental amplifier 7. An emf is induced in the additional windings proportional to the radial component of the magnetic excitation field the reference input of the phase sensitive amplifier 8, from the output of which the secondary signal is fed to the input of the converter 9 and to the internal indicator 10. For the purpose of setting zero b By stopping the medium flow, the phase of the excitation current is changed by 180 while simultaneously switching the inputs of the instrumental amplifier, achieving equal readings on the indicator 10 when the excitation winding is turned on and back in. In the calibration mode, the signal from the additional windings is also fed to the input of the amplifier 7. For high-speed the components of the signal is true, its expression k | 6vRH-e, where ep is the emf, is proportional to the mi- nitational field of excitation, induced in the additional winding j k is the proportionality coefficient, which takes into account the structure ivnye especially primary converter} (Co magnetic permeability of vacuum, - the electrical conductivity of the medium, V --skorost fluid flow, R - radius truboprovodaJ W - the number of turns of the receiving coil W ,, - number of turns of the additional winding. Thus, the magnitude of the en can serve as an example of calibration and calibration of the flow transducer in the absence of a pouring metrological test bench. The value of e is measured using an internal indicator 10, and when calibrating on a pouring stand, the value of e is also determined, the ratio of which allows determining the coefficient - K, the graduated coefficient of the transmitting converter S. determined by the relation K. Improving the accuracy of the flow measurement method and the device for its implementation is provided by periodically setting the flow meter to zero,

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Claims (2)

METHOD FOR MEASURING CONSUMPTION OF ELECTRIC CONDUCTING MEDIA AND DEVICE · FOR. ITS IMPLEMENTATION. (57) 1. A method of measuring the flow rate of electrically conductive media by creating in the controlled area a magnetic field of excitation and measuring the velocity component of a secondary magnetic field, characterized in that, in order to increase the accuracy of measurement, excitation ra are measured at the same time and the flow rate is judged by the ratio of the radial component magnetic field excitation and velocity component of the secondary magnetic field. 2. A device for measuring the flow rate of electrically conductive media, comprising a primary transducer, consisting of a section of the pipeline with coils of excitation and receiving coils placed on it, and a transmitting transducer, the input of which is connected to the receiving coils, characterized in that, in order to improve the measurement accuracy, it is equipped with additional saddle-shaped coils located on the outer surface of the receiving coils and covering them around the perimeter, and the size of the additional coils in the direction of pipe is a quarter of the internal diameter of the pipeline, and also outputs the additional coil subfamily <about