TY - JOUR
T1 - Phononic crystals for suppressing crosstalk in ultrasonic flowmeters
AU - Valappil, Sabiju Valiya
AU - Goosen, Johannes F.L.
AU - Aragon, Alejandro M.
PY - 2023
Y1 - 2023
N2 - Ultrasonic flowmeters that use transit-time ultrasonic transducers face measurement errors due to 'crosstalk,' whereby the working signal travels through the pipe wall and couplings, interfering with the signal from the fluid. Although various procedures have been proposed to solve the issue of crosstalk, they're limited to low-frequency ranges, or they are not effective in high-pressure environments. We propose a mounting mechanism based on a single-phase 3-D phononic crystal (PnC) waveguide that can mitigate crosstalk at high frequencies (megahertz range) and thus improve the flowmeters' measurement accuracy. PnCs are artificial materials consisting of periodically arranged scatterers thereby showing bandgaps (BGs) - ranges of frequencies where elastic/acoustic waves are attenuated - due to Bragg scattering. We design PnC wave filters by engineering the BG frequency range to the working signal of the ultrasonic flowmeter. We then fabricate the waveguide using additive manufacturing and connect it between the transducer and the pipe wall. Transient ultrasonic experiments show that transducers with PnC mountings attain a 40 dB crosstalk reduction in comparison with a standard transducer mounting configuration.
AB - Ultrasonic flowmeters that use transit-time ultrasonic transducers face measurement errors due to 'crosstalk,' whereby the working signal travels through the pipe wall and couplings, interfering with the signal from the fluid. Although various procedures have been proposed to solve the issue of crosstalk, they're limited to low-frequency ranges, or they are not effective in high-pressure environments. We propose a mounting mechanism based on a single-phase 3-D phononic crystal (PnC) waveguide that can mitigate crosstalk at high frequencies (megahertz range) and thus improve the flowmeters' measurement accuracy. PnCs are artificial materials consisting of periodically arranged scatterers thereby showing bandgaps (BGs) - ranges of frequencies where elastic/acoustic waves are attenuated - due to Bragg scattering. We design PnC wave filters by engineering the BG frequency range to the working signal of the ultrasonic flowmeter. We then fabricate the waveguide using additive manufacturing and connect it between the transducer and the pipe wall. Transient ultrasonic experiments show that transducers with PnC mountings attain a 40 dB crosstalk reduction in comparison with a standard transducer mounting configuration.
KW - Acoustics
KW - band gap
KW - band structure
KW - Crosstalk
KW - finite element analysis
KW - Flowmeters
KW - Fluids
KW - metal additive manufacturing
KW - Phononic crystals
KW - Solids
KW - Transducers
KW - transient experiments
KW - transmissibility
KW - ultrasonic flowmeters
KW - ultrasonic transducers
KW - Ultrasonic variables measurement
KW - wave attenuation
UR - http://www.scopus.com/inward/record.url?scp=85163474102&partnerID=8YFLogxK
U2 - 10.1109/TIM.2023.3284960
DO - 10.1109/TIM.2023.3284960
M3 - Article
AN - SCOPUS:85163474102
SN - 0018-9456
VL - 72
JO - IEEE Transactions on Instrumentation and Measurement
JF - IEEE Transactions on Instrumentation and Measurement
M1 - 7504711
ER -