Determination of the parameters of suspended particles using acoustic radiation

The flow of a gas or liquid can be visualized by detecting and analyzing sequential images of the particle distribution on the surface of the object under study through the determination of the motion parameters. However, this approach does not provide estimation of the mass and density of solid particles along with visualization of their distribution. We present the results of determining the mass and density of suspended particles using additional irradiation of the particle flux with acoustic radiation. The technique is based on the use of the method of visual processing of images of particle flows entrained by an acoustic field of a given frequency and amplitude for at least two periods of acoustic vibrations. Relaxation of the particles in the measuring plane «cut out» by the light «knife» was also taken into account. The basic mathematical expressions required for estimation of the mass, density, velocity field and shape of the particles using digital image processing and temperature measurement in the flow area are presented. The block diagram and design of the device used for the implementation of the proposed diagnostic method are presented. This technique can be used to determine the parameters of suspended particles in medicine, biology, ecology, powder metallurgy and other fields of science and technology.

1. Kolomiets S. M. Laser meter for liquid velocity / Optich. Zh. 1997. N 1. P. 58 – 50 [in Russian].

2. Kolomiets S. M. Measurement of the speed of movement of a transparent liquid by methods of acousto-optics / Izv. AN. Fiz. Atmosf. Okeana. 2000. Vol. 36. N 6. P. 847 – 852 [in Russian].

3. Kazakov L. I. On the propagation of sound in dispersed media / Akust. Zh. 2018. Vol. 64. N 3. P. 330 – 341 [in Russian].

4. Gabaidullin V. A., Fedorov Yu. V. Sound waves in a liquid with polydisperse para-gas bubbles / Akust. Zh. 2016. Vol. 62. N 2. P. 178 – 186 [in Russian].

5. Gurabatov S. N., Gryaznova I. Yu., Ivashchenko N. N. Investigation of backscattering of acoustic waves by discrete inhomogeneities of different sizes / Akust. Zh. 2016. Vol. 62. N 2. P. 203 – 207 [in Russian].

6. Shirkovsky P. N., Smagin N. V., Preobrazhensky V. L., et al. Scattering of phosphoconjugate ultrasonic waves on microinclusions in a liquid flow / Akust. Zh. 2016. Vol. 62. N 1. P. 52 – 58 [in Russian].

7. Albrecht H., Borys M., Damascke N., Tropea C. Laser Doppler and Phase Doppler Measurement Techniques. — Berlin: Springer, 2003. — 738 p.

8. Raffel M., Willert C., Kompenhans J. Particle Image Velocimetry — A practical Guide. — Berlin: Springer, 1998. — 460 p.

9. Hann D. B., Greated C. A. The measurement of flow velocity and acoustic particle velocity using particle image velocimetry. / Meas. Sci. Technol. 1997. Vol. 8. N 12. P. 1517 – 1522.

10. Physical foundations of ultrasonic technology / L. D. Rosenberg. — Moscow: Nauka, 1970. — 689 p. [in Russian].

11. Denisov A. S., Podolsky A. A., Turubarov V. I. On the entrainment of aerosol particles in a sound field at Reynolds numbers Re < 1 / Akust. Zh. 1965. N 1. P. 115 – 116 [in Russian].

12. Golubev I. F. Viscosity of gases and gas mixtures. — Moscow: GIFML, 1959. — 375 p. [in Russian].

13. Semenov V. V. Computer image processing in a television aerosol analyzer / Izv. YuFU. Tekhn. Nauki. 2014. N 10(159). P. 88 – 97 [in Russian].

14. Semenov V. V. Aerosol television analyzer / 9th Int. Sci.-Pract. Conf. «Research, development and application of high technologies in industry»: collection of works. — St. Petersburg: Izd. Politekhn. Univ., 2010. P. 260 – 261 [in Russian].

15. RF Pat. 2650753, IPC G01N15/02. Method for determining the parameters of suspended particles / Semenov V. V., Astsaturov Yu. G., Khanzhonkov Yu. B., Danilenko I. N.; applicant and patentee FGBOU VPO «Don State Technical University» (DSTU). — N 2017107631; declared 03.07.2017; publ. 04.17.2018. Byull. N 11 [in Russian].

16. RF Pat. 2655728, IPC G01N15/02, G01P5/26. Device for determining the parameters of suspended particles / Semenov V. V., Astsaturov Yu. G., Khanzhonkov Yu. B., Danilenko I. N.; applicant and patentee FGBOU VPO «Don State Technical University» (DSTU). — N 2017107615; declared 03.07.2017; publ. 05.29.2018. Byull. N 16 [in Russian].