Analysis of vertical and horizontal flows of liquids and gases through a wire-mesh sensor

• Autorzy: Rymarczyk Tomasz , Szumowski Jakub , Cieplak Tomasz , Niderla Konrad , Adamkiewicz Przemysław

Identyfikatory

DOI

10.15199/48.2020.03.38

Warianty tytułu

PL

Analiza pionowych i poziomych przepływów cieczy i gazów przez czujnik siatkowy

• Języki publikacji: EN

Abstrakty

EN

The article presents the analysis of vertical and horizontal flows of liquids and gases through a wire mesh sensor. The solution does not require complicated reconstruction of the program, which is characterized by a very high speed of operation depending on the analog-to-digital converter used. The sensor consists of two parts: the acquisition module and the working part. The device allows testing of multiphase flows and classic air bubble testing. The wires of one plane are used as transmitters, and the wires of the other plane as receivers. Samples from all receiving lines are taken at the same time.

PL

W artykule przedstawiono analizę pionowych i poziomych przepływów cieczy i gazów przez czujnik z siatki drucianej. Rozwiązanie nie wymaga skomplikowanej rekonstrukcji programu, która charakteryzuje się bardzo dużą prędkością działania w zależności od zastosowanego konwertera analogowo-cyfrowego. Czujnik składa się z dwóch części: modułu akwizycji i części roboczej. Urządzenie umożliwia badanie przepływów wielofazowych oraz klasyczne badanie pęcherzyków powietrza. Przewody jednej płaszczyzny są używane jako nadajniki, a przewody drugiej płaszczyzny jako odbiorniki. Próbki ze wszystkich linii odbiorczych są pobierane w tym samym czasie.

Słowa kluczowe

EN

wire mesh sensor; two-phase flow; flow of liquids; flow of gases

PL

sensor siatkowy; przepływ dwufazowy; przepływ cieczy; przepływ gazów

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2020
• Tom: R. 96, nr 3
• Strony: 174--177
• Opis fizyczny: Bibliogr. 37 poz., rys.

Twórcy

autor

Rymarczyk Tomasz

• Research & Development Centre Netrix S.A.
• University of Economics and Innovation, Projektowa 4, Lublin, Poland

autor

Szumowski Jakub

• Research & Development Centre Netrix S.A.

autor

Cieplak Tomasz

• Lublin University of Technology, Nadbystrzycka 38A, Lublin, Poland

autor

Niderla Konrad

• Research & Development Centre Netrix S.A.
• University of Economics and Innovation, Projektowa 4, Lublin, Poland

autor

Adamkiewicz Przemysław

• Research & Development Centre Netrix S.A.
• University of Economics and Innovation, Projektowa 4, Lublin, Poland

Bibliografia

• [1] Szumowski J., Rymarczyk T., Adamkiewicz P., Wire-mesh sensor for invasive imaging of vertical and horizontal flows of liquids and gases, 2019 Applications of Electromagnetics in Modern Engineering and Medicine, PTZE 2019, 2019, 241-245 PRZEGLĄD ELEKTROTECHNICZNY, ISSN 0033-2097, R. 96 NR 3/2020 177
• [2] Rodriguez, I., Velasco, H.F., Rodriguez, O.M., & Riano, "Capacitive wire-mesh sensor measurements in oilwater flow", A.B. (2014).
• [3] Dos Santos E. N., Da Silva M. J., Morales R. E. M., Thiele S., Schleicher E., Hampel U., Novel wire-mesh sensor for the visualization of three-phase flows, 15th Brazilian Congress of Thermal Sciences and Engineering, November 10-13, 2014, Belém, PA, Brazil
• [4] Da Silva M. J., Dos Santos E. N., Hampel U., Rodriguez I. H., Rodriguez O. M. H., Phase fraction distribution measurement of oil-water flow using a capacitance wire-mesh sensor, Measurement Science and Technology 22, 2011
• [5] Da Silva M. J., Hampel U., Capacitance wire-mesh sensor applied for the visualization of three-phase gas-liquid-liquid flows, Flow Measurementand Instrumentation, 34 (2013), 113- 117.
• [6] Sharaf S., Da Silva M., Hampel U., Zippe C., Beyer M., Azzopardi B., Comparison between wire mesh sensor and gamma densitometry void measurements in two-phase flows, Measurement Science and Technology 22, 2011
• [7] Da Silva M. J., Schleicher E., Hampel U., Advanced wire-mesh sensor technology for fast flow imaging, IST 2009 - International Workshop on Imaging Systems and Techniques, Shenzhen, China, May 11-12, 2009
• [8] Da Silva M. J., Hampel U., Arruda L., Amaral C. E. F., Morales R., Experimental Investigation of Horizontal Gas-Liquid Slug Flow by Means of Wire-Mesh Sensor, Journal of the Brazilian Society of Mechanical Sciences and Engineering, 33 (2010). 234-242.
• [9] Santos E., Reinecke S., Schleicher E., Hampel U., Da Silva M., Wire-mesh sensor applied to solid concentration visualization in slurries, 7th International Symposium on Process Tomography, Dresden, Germany, 1 - 3 September 2015.
• [10] Sujiwa A., Endarko E., Wire-Mesh 16 × 16 Capacitance Sensor for Analysis of Capacitance Distribution on Cylindrical Pipe, The 3rd International Seminar on Science and Technology, August 3rd 2017, Surabaya, Indonesia
• [11] Babout L., Grudzień K., Wiącek J., Niedostatkiewicz M., Karpiński B., and Szkodo M., Selection of material for X-ray tomography analysis and DEM simulations: comparison between granular materials of biological and non-biological origins, Granul. Matter, 20 (2018), No. 3, 38.
• [12] Grudzien K., Romanowski A., Chaniecki Z., Niedostatkiewicz M., Sankowski D., Description of the silo flow and bulk solid pulsation detection using ECT, Flow Measurement and Instrumentation, 21 (2010), No. 3,198-206.
• [13] Kryszyn J., Wanta D. M., Smolik W. T., Gain Adjustment for Signal-to-Noise Ratio Improvement in Electrical Capacitance Tomography System EVT4, IEEE Sens. J., 17 (2017), No. 24, 8107-8116.
• [14] Nowakowski J., Ostalczyk P., Sankowski D., Application of fractional calculus for modelling of two-phase gas/liquid flow system, Informatyka, Automatyka, Pomiary w Gospodarce i Ochronie Środowiska (IAPGOŚ) , 7 (2017), No. 1, 42-45.
• [15] Majchrowicz M., Kapusta P., Jackowska-Strumiłło L., Sankowski D., Acceleration of image reconstruction process in the electrical capacitance tomography 3d in heterogeneous, multi-gpu system, Informatyka, Automatyka, Pomiary w Gospodarce i Ochronie Środowiska (IAPGOŚ), 7 (2017), No. 1, 37-41
• [16] Romanowski A., Big Data-Driven Contextual Processing Methods for Electrical Capacitance Tomography, in IEEE Transactions on Industrial Informatics, 15 (2019), No. 3, 1609- 1618.
• [17] Rymarczyk T, Kłosowski G. Innovative methods of neural reconstruction for tomographic images in maintenance of tank industrial reactors. Eksploatacja i Niezawodnosc - Maintenance and Reliability, 21 (2019); No. 2, 261-267
• [18] Rymarczyk, T.; Kozłowski, E.; Kłosowski, G.; Niderla, K. Logistic Regression for Machine Learning in Process Tomography, Sensors, 19 (2019), 3400.
• [19] Kłosowski G., Rymarczyk T., Gola A., Increasing the reliability of flood embankments with neural imaging method. Applied Sciences, 8 (2018), No. 9, 1457.
• [20] Rymarczyk T., Adamkiewicz P., Polakowski K., Sikora J., Effective ultrasound and radio tomography imaging algorithm for two-dimensional problems, Przegląd Elektrotechniczny, 94 (2018), No 6, 62-69
• [21] Rymarczyk T., Szumowski K., Adamkiewicz P., Tchórzewski P., Sikora J., Moisture Wall Inspection Using Electrical Tomography Measurements, Przegląd Elektrotechniczny, 94 (2018), No 94, 97-100
• [22] Duda K., Adamkiewicz P., Rymarczyk T., Niderla K., Nondestructive Method to Examine Brick Wall Dampness, International Interdisciplinary PhD Workshop Location: Brno, Czech Republic Date: SEP 12-15, 2016, 68-71
• [23] Smolik W., Kryszyn J., Olszewski T., Szabatin R., Methods of small capacitance measurement in electrical capacitance tomography, Informatyka, Automatyka, Pomiary w Gospodarce i Ochronie Środowiska (IAPGOŚ) , 7 (2017), No. 1, 105-110.
• [24] Wajman R., Fiderek P., Fidos H., Sankowski D., Banasiak R., Metrological evaluation of a 3D electrical capacitance tomography measurement system for two-phase flow fraction determination, Measurement Science and Technology, 24 (2013), No. 6, 065302.
• [25] Wang M., Industrial Tomography: Systems and Applications, Elsevier, 2015.
• [26] Ye Z., Banasiak R., Soleimani M., Planar array 3D electrical capacitance tomography, Insight: Non-Destructive Testing and Condition Monitoring, 55 (2013), No. 12, 675-680.
• [27] Dušek J., Hladký D., Mikulka J., Electrical Impedance Tomography Methods and Algorithms Processed with a GPU, In PIERS Proceedings, 2017, 1710-1714.
• [28] Goetzke-Pala A., Hoła A., Sadowski Ł., A non-destructive method of the evaluation of the moisture in saline brick walls using artificial neural networks. Archives of Civil and Mechanical Engineering, 18 (2018), No 4, 1729-1742.
• [29] Kozlowski E., Mazurkiewicz D., Kowalska B., et al., Binary Linear Programming as a Decision-Making Aid for Water Intake Operators, 1st International Conference on Intelligent Systems in Production Engineering and Maintenance (ISPEM), Wroclaw, Poland, Sep 28-29.2017, Book Series: Advances in Intelligent Systems and Computing, 637 (2018), 199-208.
• [30] Krawczyk A., Korzeniewska E., Łada-Tondyra, E. Magnetophosphenes - History and contemporary implications, Przeglad Elektrotechniczny, 94 (2018), No 1, 61-64.
• [31] Korzeniewska E., Gałązka-Czarnecka I., Czarnecki A., Piekarska A., Krawczyk A., Influence of PEF on antocyjans in wine Przeglad Elektrotechniczny, 94 (2018), No 1, 57-60.
• [32] Kozłowski E., Mazurkiewicz D., Żabiński T., Prucnal S., Sęp J., Assessment model of cutting tool condition for real-time supervision system, Eksploatacja i Niezawodnosc - Maintenance and Reliability, 21 (2019); No 4, 679-685
• [33] Vališ D, Hasilová K., Forbelská M, Vintr Z, Reliability modelling and analysis of water distribution network based on backpropagation recursive processes with real field data, Measurement 149 (2020), 107026
• [34] Kowalska A., Banasiak R., Romanowski A., Sankowski D., Article 3D-Printed Multilayer Sensor Structure for Electrical Capacitance Tomography, 19 (2019), Sensors, 3416
• [35] Goclawski J., Korzeniewska E., Sekulska-Nalewajko J. et al., Extraction of the Polyurethane Layer in Textile Composites for Textronics Applications Using Optical Coherence Tomography, POLYMERS, 10 (2018), No. 5, 469
• [36] Galazka-Czarnecka, I.; Korzeniewska E., Czarnecki A. et al., Evaluation of Quality of Eggs from Hens Kept in Caged and Free-Range Systems Using Traditional Methods and Ultra- Weak Luminescence, Applied Sciences-Basel, 9 (2019), No. 12, 2430.
• [37] Valis D., Mazurkiewicz D., Application of selected Levy processes for degradation modelling of long range mine belt using real-time data, Archives of Civil and Mechanical Engineering, 18 (2018), No. 4, 1430-1440.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).