Proper Orthogonal Decomposition as a technique for identifying two-phase flow pattern based on electrical impedance tomography

Flow Measurement and Instrumentation

2018

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Section: Gas-liquid Test Ringmentioning

confidence: 99%

Section: Gas-liquid Test Ringmentioning

confidence: 99%

Vertical annular flow pattern characterisation using proper orthogonal decomposition of Electrical Impedance Tomography

Polanský

Flow Measurement and Instrumentation

2018

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“…POD was also adopted to understand the flow dynamics information about the coherent structures of different energy modes. Polansky and Wang (2017) utilized the POD to identify flow structure and revealed the air-water flow regimes in a horizontal pipeline with slag, plug and wavy stratified phenomena. Zhang and Xiang (2015) proposed an efficient method based on POD to resolve the transient heat conduction problems with enough computational accuracy.…”

Section: Introductionmentioning

confidence: 99%

Using proper orthogonal decomposition to solve heat transfer process in a flat tube bank fin heat exchanger

Xia

et al. 2017

Adv. Geo-Energ. Res.

Proper orthogonal decomposition (POD) reduced-order model can save computing time by reducing the dimension of physical problems and reconstructing physical fields. It is especially suitable for large-scale complex problems in engineering, such as ground heat utilization, sea energy development, mineral exploitation, multiphase flow and flow and heat transfer with complex structure. In this paper, the POD reduced-order model was used to calculate the heat transfer in a flat tube bank fin heat exchanger. The calculating results of the finite volume method (FVM) were adopted as the snapshot samples. SVD method was used to decompose the samples to obtain a series of bases and corresponding coefficients on sampling conditions. With these coefficients, interpolation method was used to calculate the coefficients on predicting conditions. And the physical field has been reconstructed using the bases and the interpolated coefficients directly.In the calculation of heat transfer unit of flat tube fin heat exchanger, air-side Reynolds number, transverse tube spacing and the fin spacing were chosen as the variables. The results obtained by the POD method are in good agreement with the results calculated by the FVM. Moreover, the POD reduced-order model presented in this paper is more advantageous in comparison with the FVM in terms of accuracy, suitability, and computational speed.Keywords: Proper orthogonal decomposition (POD), POD reduced-order model, flat tube bank fin heat exchanger, interpolation method, reconstructed temperature field.Citation: Wang, Y., Xia, X., Wang, Y., et al. Using proper orthogonal decomposition to solve heat transfer process in a flat tube bank fin heat exchanger.

“…The Proper Orthogonal Decomposition method was also utilised to identify and analyse typical flow regimes in the horizontal pipeline ( Figure 3). The intention of the method for recognition of flow regime [7] using decomposition mathematical technique comes from the fact that each regime is characterised by typical dynamic behaviour. To recognise the multiphase flow dynamic structures [8], means indeed the recognition of the prevalent regime to indicate the actual flow conditions of the measurement domain.…”

mentioning

confidence: 99%

“…To recognise the multiphase flow dynamic structures [8], means indeed the recognition of the prevalent regime to indicate the actual flow conditions of the measurement domain. The direct approach of Proper Orthogonal Decomposition are used to identify a typical multiphase flow instability [9]. Mathematical method, such as Wavelet Transformation and Kalman Filtering was used as a complementary techniques for detection of multiphase fluid motion and flow structures [10].…”

mentioning

confidence: 99%

Experimental tomographic methods for analysing flow dynamics of gas-oil-water flows in horizontal pipeline

et al. 2016

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Gas-oil-water three phase flow is of practical significance in oil and gas industries. An insight into the dynamics of such multiphase flows is significantly valuable to obtain optimal design parameters and operational conditions. Since flow patterns are sensitive to pipe geometry, flow conditions and thermophysicalfluid properties, it is extremely challenging to provide a universal solution for visualisation of three phase horizontal flows. This study deals with a fully developed turbulent three phase flow with no phase changing, and presents the outcomes of tomographic imaging techniques to visualise gas-oil-water flows in a horizontal pipeline.