Resources for structural optimization of gas-hydrodynamic measuring transducers

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dc.citation.epage143
dc.citation.issue2
dc.citation.spage136
dc.contributor.affiliationНаціональний університет “Львівська політехніка”
dc.contributor.affiliationLviv Polytechnic National University
dc.contributor.authorПістун, Євген
dc.contributor.authorМатіко, Галина
dc.contributor.authorКрих, Ганна
dc.contributor.authorPistun, Yevhen
dc.contributor.authorMatiko, Halyna
dc.contributor.authorKrykh, Hanna
dc.coverage.placenameЛьвів
dc.coverage.placenameLviv
dc.date.accessioned2023-09-19T07:59:56Z
dc.date.available2023-09-19T07:59:56Z
dc.date.created2021-06-01
dc.date.issued2021-06-01
dc.description.abstractПроаналізовано та обґрунтовано ресурси структурного синтезу схем газогідродинамічних дросельних перетворювачів для вимірювання фізико-механічних параметрів плинних середовищ. Такі ресурси, як: кількість дроселів у схемі та їх компонування; тип дросельних елементів; вимірювальні канали із певним типом вихідного сигналу; режим живлення вимірювального перетворювача, можуть бути інтегровані в проєктування вимірювального перетворювача конкретного параметра. Для формування можливих структур дросельних схем, зокрема, запропоновано математичний апарат на основі теорії множин та комбінаторного аналізу, для формування множини вимірювальних каналів – на основі теорії графів. Наведено приклади, які демонструють можливості побудови різних схем вимірювальних перетворювачів за допомогою розглянутих ресурсів структурного синтезу. Запропоновані ресурси є засобами структурно-параметричної оптимізації для створення газогідродинамічних вимірювальних перетворювачів із оптимальними характеристиками.
dc.description.abstractThe paper presents the analysis of the resources of structural and parametric optimization of gas-hydrodynamic measuring transducers of physical and mechanical parameters of fluids. Resources such as the number of throttles and their arrangement in the diagram, type of throttle elements, measuring channels with a certain type of output signal, the supply mode of the measuring transducer can be integrated into the design process of the measuring transducer of a specific parameter. A mathematical apparatus based on set theory and combinatorial analysis is proposed for synthesizing the possible structures of throttle diagrams, graph theory – for forming a set of measuring channels. The authors have given examples demonstrating the possibilities of building different diagrams of measuring transducers using the resources for structural synthesis. The proposed resources are the means of structural and parametric optimization for synthesizing the gas-hydrodynamic measuring transducers with optimal characteristics.
dc.format.extent136-143
dc.format.pages8
dc.identifier.citationPistun Y. Resources for structural optimization of gas-hydrodynamic measuring transducers / Yevhen Pistun, Halyna Matiko, Hanna Krykh // Energy Engineering and Control Systems. — Lviv : Lviv Politechnic Publishing House, 2021. — Vol 7. — No 2. — P. 136–143.
dc.identifier.citationenPistun Y. Resources for structural optimization of gas-hydrodynamic measuring transducers / Yevhen Pistun, Halyna Matiko, Hanna Krykh // Energy Engineering and Control Systems. — Lviv : Lviv Politechnic Publishing House, 2021. — Vol 7. — No 2. — P. 136–143.
dc.identifier.urihttps://ena.lpnu.ua/handle/ntb/60145
dc.language.isoen
dc.publisherВидавництво Львівської політехніки
dc.publisherLviv Politechnic Publishing House
dc.relation.ispartofEnergy Engineering and Control Systems, 2 (7), 2021
dc.relation.references[1] Van der Wouden, E., Groenesteijn, J., Wiegerink, R., Lötters, J. (2015). Multi Parameter Flow Meter for On-Line Measurement of Gas Mixture Composition. Micromachines, 6(4), 452–461. DOI: 10.3390/mi6040452.
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dc.relation.references[3] Pistun, Ye., Matiko, H., Krykh, H., Matiko, F. (2017). Synthesizing the Schemes of Multifunctional Measuring Transducers of the Fluid Parameters. Eastern-European Journal of Enterprise Technologies, 6, 5(90), 13–22. https://doi.org/10.15587/1729-4061.2017.114110.
dc.relation.references[4] Pistun, Ye., Matiko, H., Krykh, H., Matiko, F. (2018). Structural Modeling of Throttle Diagrams for Measuring Fluid Parameters. Metrology аnd Measurement Systems. 25(4), 659–673. DOI: 10.24425/mms.2018.124884.
dc.relation.references[5] Pistun, Y., Matiko, H., Krykh, H. (2019). Mathematical Models of Throttle Elements of Gas-hydrodynamic Measuring Transducers. Energy Engineering and Control Systems, 5(2), 94–107. https://doi.org/10.23939/jeecs2019.02.094.
dc.relation.references[6] Nitecki, J.-P., Patrick, S., U. S. Patent 6,073,483. (2000). Device for Measuring the Viscosity of Fluid.
dc.relation.references[7] Teplukh, Z., Dilay, I., Stasiuk, I., Tykhan, M., Kubara, I. (2018). Design of Linear Capillary Measuring Transducers for Low Gas Flow Rates. Eastern-European Journal of Enterprise Technologies, 6/5 (96), 25–32. DOI:10.15587/1729-4061.2018.150526.
dc.relation.references[8] Pistun, Y., Lesovoy, L., Matiko, F., Fedoryshyn, R. (2014). Computer Aided Design of Differential Pressure Flow Meters. World Journal of Engineering and Technology. 2, 68–77. DOI:10.4236/wjet.2014.22009.
dc.relation.references[9] Drevetskiy, V., Klepach, M. (2012). The Method for Determining the Octane Number of Automotive Gasoline of Different Types. Patent UA No. 75959. Bul. No. 24 (in Ukrainian).
dc.relation.references[10] Drevetskiy, V., Klepach, M. (2013). The Intelligent System for Automotive Fuels Quality Definition, “Informatics, Control, Measurement in Economy and Environment Protection”, 3 (3), 11–13. DOI:10.35784/iapgos.1455.
dc.relation.references[11] Pistun, Ye. P., Matiko, H. F., Krykh, H. B., Matiko, F. D. (2021). Modeling Throttle Bridge Measuring Transducers of Physical-Mechanical Parameters of Newtonian Fluids. Mathematical Modeling and Computing, 8 (3), 515–525. DOI: 10.23939/mmc2021.03.515.
dc.relation.references[12] Zosimovych. N. (2016). Structural and Parametric Optimization for Flight Vehicle Structures. Conference: “Areas of Scientific Thought - 2016/2017”, XII International Scientific and Practical Conference, December, 30, 2016 – January, 7, 2017, Technical Science. At: Sheffield, UK: Vol. 8, 59–68.
dc.relation.references[13] Winskel, G. (2010). Set Theory for Computer Science.
dc.relation.references[14] Keller, M., Trotter, W. (2015) Applied Combinatorics.
dc.relation.references[15] Pistun, Ye., Matiko, H., Krykh, H. (2016) Modeling the Measuring Transducers Schemes Using Set Theory, Metrology and Instruments, 3, 53–61 (in Ukrainian).
dc.relation.references[16] Pistun, Ye., Leskiv, H. (2002) Gas-hydrodynamic Measuring Transducers Built on Complex Throttle Elements. Bulletin of Lviv Polytechnic National University: Heat Power Engineering. Environmental Engineering. Automation, 460, 81–88 (in Ukrainian).
dc.relation.references[17] Diestel, R. (2016) Graph Theory. Springer–Verlag, Heidelberg.
dc.relation.referencesen[1] Van der Wouden, E., Groenesteijn, J., Wiegerink, R., Lötters, J. (2015). Multi Parameter Flow Meter for On-Line Measurement of Gas Mixture Composition. Micromachines, 6(4), 452–461. DOI: 10.3390/mi6040452.
dc.relation.referencesen[2] Niedermayer, A. O., Voglhuber-Brunnmaier, T., Feichtinger, F., Heinisch, M., Jakoby, B. (2016). Monitoring Physical Fluid Properties Using a Piezoelectric Tuning Fork Resonant Sensor. BHM Berg- und Hüttenmännische Monatshefte, 161(11), 510–514. DOI: 10.1007/s00501-016-0540-0.
dc.relation.referencesen[3] Pistun, Ye., Matiko, H., Krykh, H., Matiko, F. (2017). Synthesizing the Schemes of Multifunctional Measuring Transducers of the Fluid Parameters. Eastern-European Journal of Enterprise Technologies, 6, 5(90), 13–22. https://doi.org/10.15587/1729-4061.2017.114110.
dc.relation.referencesen[4] Pistun, Ye., Matiko, H., Krykh, H., Matiko, F. (2018). Structural Modeling of Throttle Diagrams for Measuring Fluid Parameters. Metrology and Measurement Systems. 25(4), 659–673. DOI: 10.24425/mms.2018.124884.
dc.relation.referencesen[5] Pistun, Y., Matiko, H., Krykh, H. (2019). Mathematical Models of Throttle Elements of Gas-hydrodynamic Measuring Transducers. Energy Engineering and Control Systems, 5(2), 94–107. https://doi.org/10.23939/jeecs2019.02.094.
dc.relation.referencesen[6] Nitecki, J.-P., Patrick, S., U. S. Patent 6,073,483. (2000). Device for Measuring the Viscosity of Fluid.
dc.relation.referencesen[7] Teplukh, Z., Dilay, I., Stasiuk, I., Tykhan, M., Kubara, I. (2018). Design of Linear Capillary Measuring Transducers for Low Gas Flow Rates. Eastern-European Journal of Enterprise Technologies, 6/5 (96), 25–32. DOI:10.15587/1729-4061.2018.150526.
dc.relation.referencesen[8] Pistun, Y., Lesovoy, L., Matiko, F., Fedoryshyn, R. (2014). Computer Aided Design of Differential Pressure Flow Meters. World Journal of Engineering and Technology. 2, 68–77. DOI:10.4236/wjet.2014.22009.
dc.relation.referencesen[9] Drevetskiy, V., Klepach, M. (2012). The Method for Determining the Octane Number of Automotive Gasoline of Different Types. Patent UA No. 75959. Bul. No. 24 (in Ukrainian).
dc.relation.referencesen[10] Drevetskiy, V., Klepach, M. (2013). The Intelligent System for Automotive Fuels Quality Definition, "Informatics, Control, Measurement in Economy and Environment Protection", 3 (3), 11–13. DOI:10.35784/iapgos.1455.
dc.relation.referencesen[11] Pistun, Ye. P., Matiko, H. F., Krykh, H. B., Matiko, F. D. (2021). Modeling Throttle Bridge Measuring Transducers of Physical-Mechanical Parameters of Newtonian Fluids. Mathematical Modeling and Computing, 8 (3), 515–525. DOI: 10.23939/mmc2021.03.515.
dc.relation.referencesen[12] Zosimovych. N. (2016). Structural and Parametric Optimization for Flight Vehicle Structures. Conference: "Areas of Scientific Thought - 2016/2017", XII International Scientific and Practical Conference, December, 30, 2016 – January, 7, 2017, Technical Science. At: Sheffield, UK: Vol. 8, 59–68.
dc.relation.referencesen[13] Winskel, G. (2010). Set Theory for Computer Science.
dc.relation.referencesen[14] Keller, M., Trotter, W. (2015) Applied Combinatorics.
dc.relation.referencesen[15] Pistun, Ye., Matiko, H., Krykh, H. (2016) Modeling the Measuring Transducers Schemes Using Set Theory, Metrology and Instruments, 3, 53–61 (in Ukrainian).
dc.relation.referencesen[16] Pistun, Ye., Leskiv, H. (2002) Gas-hydrodynamic Measuring Transducers Built on Complex Throttle Elements. Bulletin of Lviv Polytechnic National University: Heat Power Engineering. Environmental Engineering. Automation, 460, 81–88 (in Ukrainian).
dc.relation.referencesen[17] Diestel, R. (2016) Graph Theory. Springer–Verlag, Heidelberg.
dc.relation.urihttps://doi.org/10.15587/1729-4061.2017.114110
dc.relation.urihttps://doi.org/10.23939/jeecs2019.02.094
dc.rights.holder© Національний університет “Львівська політехніка”, 2021
dc.subjectвимірювальний перетворювач
dc.subjectфізико-механічні параметри
dc.subjectдросельний елемент
dc.subjectструктурний синтез
dc.subjectструктура схеми
dc.subjectmeasuring transducer
dc.subjectphysical and mechanical parameters
dc.subjectthrottle element
dc.subjectstructural synthesis
dc.subjectstructure of diagram
dc.titleResources for structural optimization of gas-hydrodynamic measuring transducers
dc.title.alternativeРесурси структурної оптимізації газогідродинамічних вимірювальних перетворювачів
dc.typeArticle

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Energy Engineering and Control Systems. – 2021. – Vol. 7, No. 2