Thick-wall electrical capacitance tomography and its application in dense-phase pneumatic conveying under high pressure

D.Y. Yang; B. Zhou; C.L. Xu; S.M. Wang

Thick-wall electrical capacitance tomography and its application in dense-phase pneumatic conveying under high pressure

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Thick-wall electrical capacitance tomography and its application in dense-phase pneumatic conveying under high pressure

Author(s): D.Y. Yang ; B. Zhou ; C.L. Xu ; S.M. Wang
DOI: 10.1049/iet-ipr.2009.0209

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Author(s): D.Y. Yang ¹ ; B. Zhou ² ; C.L. Xu ² ; S.M. Wang ²
- Affiliations: 1: College of Automation and Electrical Engineering, Nanjing University of Technology, Nanjing, People's Republic of China
  2: School of Energy and Environment, Southeast University, Nanjing, People's Republic of China
Source: Volume 5, Issue 5, August 2011, p. 513 – 522
DOI: 10.1049/iet-ipr.2009.0209 , Print ISSN 1751-9659, Online ISSN 1751-9667

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The thick-wall ECT system applied in high pressure is introduced, and the pipe wall thickness of ECT sensor is 5 mm. To analyse the effect of pipe wall thickness on ECT sensor, radius–electrode ratio is defined as the ratio of inner and outer radius of pipeline. ANSYS and Matlab are combined to simulate sensor characteristic. Linear back projection algorithm is adopted to reconstruct the images of stratified flow, core flow and annular flow with different radius–electrode ratios. The results of simulation indicate that there is a small image error under high radius–electrode ratio, and the images reconstructed from stratified flow are better than those from core flow and annular flow. The independently developed ECT system is applied to identify the flow regime of gas–solid flows in horizontal pipeline with 10 mm inner diameter in a pulverised coal dense-phase pneumatic conveying experimental setup. The pressure is up to 4.0 MPa and the solid–gas ratio is up to 11.73 kg/kg. The experimental results of eight-electrode ECT with thick pipeline sensor, which is used on the pulverised coal dense-phase pneumatic conveying experimental setup, are given. Finally, the Fluent simulation of concentration distribution at the similar condition is introduced to validate the ECT imaging result.

References

1. 1)
  - C.G. Xie , S.M. Huang , B.S. Hoyle . Transputer-based electrical capacitance tomography for real-time imaging of oilfield flow pipeline. Tomographic Tech. Process Des. Oper. , 333 - 346
2. 2)
  - W.Q. Yang . Modelling of capacitance tomography sensor. IEE Proc. Sci. Meas. Technol. , 5 , 203 - 208
3. 3)
  - C.G. Xie , A. Plaskowski , M.S. Beck . 8-electrode capacitance system for two-component flow identification. Part 1: Tomographic flow imaging. IEEE Proc. A Phys. Sci. , 4 , 173 - 183
4. 4)
  - A.J. Jaworski , G.T. Bolton . The design of an electrical capacitance tomography sensor for use with media of high dielectric permittivity. Meas. Sci. Technol , 6 , 743 - 757
5. 5)
  - A.M. Olmos , J.A. Primicia , J.L.F. Marron . Simulation design of electrical capacitance tomography sensors. IET Sci. Meas. Technol. , 4 , 216 - 223
6. 6)
  - W.Q. Yang , A.L. Stott , M.S. Beck , C.G. Xie . Development of capacitance tomographic imaging systems for oil pipeline measurements. Rev. Sci. Instrum. , 8
7. 7)
  - J.M. Jin . (1998) Finite elements for electromagnetic field.
8. 8)
  - H. Yan , J. Gao . The simulation study of the electrical capacitance tomography. J. Syst. Simul. , 11 , 1625 - 1627
9. 9)
  - W.Q. Yang , Y.A. York . New AC-based capacitance tomography system. IEE Proc. Sci. Meas. Technol. , 1 , 47 - 53
10. 10)
  - W.Q. Yang , M.S. Beck , M. Byars . Electrical capacitance tomography – from design to applications. Meas. Control , 9 , 261 - 266
11. 11)
  - L.J. Yang , H. Yan . Normalization approach for capacitance tomography measurement data. Chinese J. Sci. Instrum. , 3 , 229 - 231
12. 12)
  - C. Liang , C. Zhao , X.P. Chen , W.H. Pu , P. Lu , C.L. Fan . Flow characteristics and Shannon entropy analysis of dense-phase pneumatic conveying of variable moisture content under high pressure. Chem. Eng. Technol. , 7 , 926 - 931
13. 13)
  - W.H. Pu , C.S. Zhao , Y.Q. Xiong . Numerical simulation of dense pneumatic conveying of pulverized coal in horizontal pipe at high pressure. J. Chem. Ind. Eng. , 10 , 2601 - 2607
14. 14)
  - W.Q. Yang , L.H. Peng . Image reconstruction algorithms for electrical capacitance tomography. Meas. Sci. Technol. , L1 - L13
15. 15)
  - C.G. Xie , S.M. Huang , B.S. Hoyle . Electrical capacitance for flow imaging: system model for development of image reconstruction algorithms and design of primary sensors. IEE Proc. G , 89 - 98
16. 16)
  - W.H. Pu , C.S. Zhao , Y.Q. Xiong . Three-dimensional numerical simulation of dense pneumatic conveying of pulverized coal in vertical pipe at high pressure. Chem. Eng. Technol. , 2 , 215 - 223

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Thick-wall electrical capacitance tomography and its application in dense-phase pneumatic conveying under high pressure

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