28th IAHR symposium on Hydraulic Machinery and Systems | |
Flow velocity profiling using acoustic time of flight flow metering based on wide band signals and adaptive beam-forming techniques | |
Murgan, I.^1 ; Candel, I.^1 ; Ioana, C.^1 ; Digulescu, A.^1,2 ; Bunea, F.^3 ; Ciocan, G.D.^4 ; Anghel, A.^1,5 ; Vasile, G.^1 | |
Gipsa-lab, Université Grenoble Alpes, 11 rue des Mathématiques BP 46, Saint Martin d'Heres | |
38402, France^1 | |
Military Technical Academy, Bucharest, Romania^2 | |
National Institute for RandD for Electric Engineering ICPE-CA, Bucharest, Romania^3 | |
Laboratoire de Machines Hydrauliques, Université de Laval, Québec, Canada^4 | |
University Politehnica of Bucharest, 1-3 Iulie Maniu Blv., Bucharest | |
061071, Romania^5 | |
关键词: Acoustic doppler profilers; Acoustic techniques; Adaptive beam-forming; Conventional techniques; Geometrical constraints; Non-intrusive measurements; Time of flight estimation; Transmitted signal; | |
Others : https://iopscience.iop.org/article/10.1088/1755-1315/49/6/062003/pdf DOI : 10.1088/1755-1315/49/6/062003 |
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来源: IOP | |
【 摘 要 】
In this paper, we present a novel approach to non-intrusive flow velocity profiling technique using multi-element sensor array and wide-band signal's processing methods. Conventional techniques for the measurements of the flow velocity profiles are usually based on intrusive instruments (current meters, acoustic Doppler profilers, Pitot tubes, etc.) that take punctual velocity readings. Although very efficient, these choices are limited in terms of practical cases of applications especially when non-intrusive measurements techniques are required and/or a spatial accuracy of the velocity profiling is required This is due to factors related to hydraulic machinery down time, the often long time duration needed to explore the entire section area, the frequent cumbersome number of devices that needs to be handled simultaneously, or the impossibility to perform intrusive tests. In the case of non-intrusive flow profiling methods based on acoustic techniques, previous methods concentrated on using a large number of acoustic transducers placed around the measured section. Although feasible, this approach presents several major drawbacks such as a complicated signal timing, transmission, acquisition and recording system, resulting in a relative high cost of operation. In addition, because of the geometrical constraints, a desired number of sensors may not be installed. Recent results in acoustic flow metering based on wide band signals and adaptive beamforming proved that it is possible to achieve flow velocity profiles using less acoustic transducers. In a normal acoustic time of flight path the transducers are both emitters and receivers, sequentially changing their roles. In the new configuration, proposed in this paper, two new receivers are added on each side. Since the beam angles of each acoustic transducer are wide enough the newly added transducers can receive the transmitted signals and additional time of flight estimation can be done. Thus, several flow velocities are possible to be computed. Analytically defined emitted wide band signals makes possible the identification of signals coming from each transducer. Using the adaptive beam-forming algorithm the receiving transducers can record different signals from the receiver, equivalent to different propagation paths. Therefore, different measurements of time of flight are possible, leading to additional flow velocity measurements. Results carried out in an experiment facility belonging to ICPE-CA, Bucharest - Romania allowed to the validation of the flow velocities computed using this new technique, in symmetric, asymmetric and uneven flow conditions. The acoustic derived values were referenced with those provided from a Pitot tube probe installed in the test channel and the results obtained by the method proposed in this paper are relatively close to this reference.
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