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Measurement of Industrial Oil-Gas-Water Flow Using Multimode Conductance Sensing System

Abstract

To accurately decouple the individual phase fractions and velocities in three-phase flows, a novel multimode conductance sensing system is proposed. First, the sensitive field of the distributed coaxial double-ring conductance sensor (DRCS) along the pipe wall prevents it from being interfered by the gas in the center of the cross section. Thus, the DRCS provides the critical water-oil mixture conductance for the rotating electric field conductance sensors (REFCS) and the interdigital conductance sensor (ICS). In addition, the DRCS measures the oil holdup in the liquid phase. Second, the REFCS and ICS have excellent sensitive fields for quasi-uniform liquid slugs and nonuniform gas plugs, respectively. Therefore, the REFCS is utilized to determine the gas holdup of liquid slugs and bubble flows. The ICS determines the liquid film thickness and thus provides the gas holdup of the gas slugs. The average absolute percentage deviations (AAPDs) of the predicted gas and oil holdups are 3.33& and 4.22%, respectively. Moreover, the conductance sensor with multiheight electrodes (CSMHE) relies on surface charge matching to obtain global cross-correlation velocities. Finally, the proposed drift-flux model decouples the individual phase velocities. The AAPDs for predicting the superficial velocities of the oil and gas are 4.95% and 3.50%, respectively.

article Article

date_range 2025

language English

link Link of the paper

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Tang Ziyan

Jin Ningde

Ren Weikai

Yang Qiuyi

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Featured Keywords

Oils

Phase measurement

Sensors

Velocity measurement

Water

Volume measurement

Pressure measurement

Cross-correlation velocity

flow measurement

industrial oil-water-gas three-phase flow

multimode conductance sensing system

phase volume fraction

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Effect of corrosion on flexural strength of reinforced concrete beams with polypropylene fibers

Abstract

An experimental study was performed to investigate the effects of polypropylene fibers on uncorroded and corroded reinforced concrete beams. Three different volume fractions of polypropylene fibers having 0, 0.5, and 1.5%, were tested at four corrosion levels of 0% and approximately 5, 7, and 9%. A full scale of an accelerated corrosion pool was used for the accelerated corrosion process. Reinforced concrete beams were used for an under monotonic bending test. The contribution of the actual corrosion levels of transverse and longitudinal reinforcement bars to the total corrosion levels were obtained from reinforcement bars fully extracted from concrete. Flexural strength, bond-slip, and moment-curvature relationships were examined for uncorroded and corroded reinforced concrete beams. A new model was developed to predict the flexural strength of corroded reinforced concrete beams. The proposed model for predicting the residual flexural strength of corroded beams was compared with test data published in previous studies. Furthermore, a novel model is presented for improved predictions between the actual and theoretically estimated corrosion mass losses, based on Faraday’s law, with the aid of fully extracted reinforcement bars. The model used to predict the flexural strength of corroded reinforced concrete beams with large sizes demonstrated good agreement with current and previously published literature data. In the case of corroded beams comprising differing amounts of polypropylene fibers, the performance of the corroded beams was limited by a fiber volume fraction of 1.5% at low corrosion levels.

article Article

date_range 2018

language English

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