Разработка акустической измерительной системы анализа состава веществ
Работая с нашим сайтом, вы даете свое согласие на использование файлов cookie. Это необходимо для нормального функционирования сайта, показа целевой рекламы и анализа трафика. Статистика использования сайта отправляется в «Яндекс» и «Google»
Научный журнал Моделирование, оптимизация и информационные технологииThe scientific journal Modeling, Optimization and Information Technology
Online media
issn 2310-6018

Developing of an acoustic measuring system for analyzing the composition of substances

idBochkarev A.V. Lyubimova M.A.   Popov K.S.  

UDC 544.07
DOI: -

  • Abstract
  • List of references
  • About authors

The relevance of the study is due to the problem of untimely analysis of the composition of liquid mixtures during their production by enterprises of the food, chemical and oil refining industries. The traditional method of such analysis is carried out after the formation of a batch of products, which is why enterprises incur costs associated with the disposal of defective batches of products. This article is devoted to the development of an acoustic measuring system for analyzing the composition of liquid substances, capable of being used to analyze various liquid products in industry in a continuous mode when transporting these products through the internal industrial pipeline system, which makes it possible to identify defects before the formation of a batch of products, thereby reducing disposal costs. The sounded system, built into the pipeline, contains two measuring channels, including two piezoelectric receivers and one piezoelectric emitter, common to the two channels. As part of this work, equipment is selected based on an analysis of the repeatability of research results, in particular, the possibility of using one or another generator that generates exciting signals for a piezoelectric emitter is considered. The possibility of using excitation signals of various shapes and/or durations is investigated, and repeatability is assessed based on the linear correlation coefficient between several repetitions of experiments with the same type of excitation signal. The need for two measuring channels is analyzed. The materials are of practical value for enterprises producing liquid products, as well as for manufacturers of analytical equipment.

1. Schipilliti L., Dugo P., Bonaccorsi I., Mondello L. Headspace-solid phase microextraction coupled to gas chromatography–combustion-isotope ratio mass spectrometer and to enantioselective gas chromatography for strawberry flavoured food quality control. Journal of Chromatography A. 2011;1218(42):7481–7486. https://doi.org/10.1016/j.chroma.2011.07.072

2. Yanovskaya A.V., Kalyakina O.P., Kuzmin A.P., Zakharchenko P.V. Application of instrumental analysis methods in detecting alcoholic beverages falsification. Vestnik KrasGAU = Bulletin of KSAU. 2021;(2):161–166. (In Russ.). https://doi.org/10.36718/1819-4036-2021-2-161-166

3. Sawicki E., Hillebrand M.J., Rosing H., Schellens J.H.M., Nuijen B., Beijnen J.H. Validation of a liquid chromatographic method for the pharmaceutical quality control of products containing elacridar. Journal of Pharmaceutical Analysis. 2016;6(4):268–275. https://doi.org/10.1016/j.jpha.2016.04.005

4. Lahon D., Bora P.K., Sarmah J., Bhuyan M., Haldar S. A high performance thin layer chromatography (HPTLC) method for the quality assessment of citronella oil: application in commercial sample analysis. Natural Product Research. 2023. https://doi.org/10.1080/14786419.2023.2257355

5. Isaev I.Z., Isaeva M.S. Fractional composition of oil. In: Innovatsionnaya traektoriya sovremennykh issledovanii: Sbornik statei Mezhdunarodnoi nauchno-prakticheskoi konferentsii, 25 September 2023, Petrozavodsk, Russia. Petrozavodsk: International Center for Scientific Partnership «New Science»; 2023. P. 145–151. (In Russ.).

6. Christian G.D., Dasgupta P.K., Schug K.A. Analytical Chemistry. Hoboken, NJ: John Wiley & Sons; 2013. 848 p.

7. Taverniers I., De Loose M., Van Bockstaele E. Trends in quality in the analytical laboratory. II. Analytical method validation and quality assurance. TrAC Trends in Analytical Chemistry. 2004;23(8):535–552. https://doi.org/10.1016/j.trac.2004.04.001

8. Smith I. Chromatographic and Electrophoretic Techniques. Volume I – Chromatography. Bath: Elsvier; 2013. 1100 p.

9. Shewhart W.A. Economic Control of Quality of Manufactured Product. Milwaukee, WI: American Society for Quality Control; 1980. 501 p.

10. Awad T.S., Moharram H.A., Shaltout O.E., Asker D., Youssef M.M. Applications of ultrasound in analysis, processing and quality control of food: A review. Food Research International. 2012;48(2):410–427. https://doi.org/10.1016/j.foodres.2012.05.004

11. Zhang X.-D. Modern Signal Processing. Berlin: De Gruyter; 2023. 601 p. https://doi.org/10.1515/9783110475562

12. Tzanakis I., Lebon G.S.B., Eskin D.G., Pericleous K.A. Characterizing the cavitation development and acoustic spectrum in various liquids. Ultrasonics Sonochemistry. 2017;34:651–662. https://doi.org/10.1016/j.ultsonch.2016.06.034

Bochkarev Andrey Vladimirovich
Candidate of Technical Sciences
Email: bochkarevpubliciit@gmail.com

WoS | Scopus | ORCID | eLibrary |

Samara State Technical University

Samara, Russia

Lyubimova Maria Andreevna

Samara State Technical University

Samara, Russia

Popov Konstantin Sergeevich

Samara State Technical University

Samara, Russia

Keywords: acoustic measurement method, piezoelectric transducer, analytical studies, repeatability of results, linear correlation coefficient

For citation: Bochkarev A.V. Lyubimova M.A. Popov K.S. Developing of an acoustic measuring system for analyzing the composition of substances. Modeling, Optimization and Information Technology. 2024;12(2). Available from: https://moitvivt.ru/ru/journal/pdf?id=1569 DOI: - (In Russ).

45

Full text in PDF

Received 03.05.2024

Revised 15.05.2024

Accepted 27.05.2024