Abstract
A free-flooded transducer that couples the vibration of a longitudinal vibration transducer and the fluid cavity of an aluminum ring was investigated. Given the transducer is based on a fluid cavity structure and has no air cavity, it can resist high hydrostatic pressure when working underwater, which is suitable for application in the deep sea. At first, the structure and working principle of the transducer were introduced. Then, the axisymmetric finite element model of the transducer was established; and the transmitting voltage response, admittance, and radiation directivity of the transducer were simulated using the finite element method. According to the size of the finite element model, a prototype of the transducer was designed and fabricated, and the electro-acoustic performance of the prototype was measured in an anechoic water tank. The experimental results were consistent with the simulation results and showed a good performance of the transducer. Finally, the improvement of the radiation directivity of the transducer by the optimal design of the free-flooded aluminum ring was obtained using the finite element method and verified by experiments.
Highlights
Since ocean exploration is developing towards the deep sea, underwater acoustic transducers require the performance of low frequency and high power in deepwater
This paper investigated a transducer with a free-flooded structure that couples the vibration of a longitudinal vibration transducer and the fluid cavity of an aluminum ring, which is suitable for application in the deep sea
The finite element method was used to model influence of the free‐flooded aluminum ring on radiation directivity is analyzed, the size of the and calculate the free-flooded transducer based on fluid cavity structure, where the influence of the transducer aluminum is optimally designed, and directivity the performance is verified byofexperiments in is theoptimally anechoic free-flooded ring on radiation is analyzed, the size the transducer water tank
Summary
Since ocean exploration is developing towards the deep sea, underwater acoustic transducers require the performance of low frequency and high power in deepwater. This paper investigated a transducer with a free-flooded structure that couples the vibration of a longitudinal vibration transducer and the fluid cavity of an aluminum ring, which is suitable for application in the deep sea. Using the finite the element method distribution of the transducer at resonance, and obtain the admittance curve, transmitting voltage to model the transducer we can calculate the resonant frequency, observe the displacement response curves, directivity pattern of and the transducer [10]. The finite element method was used to model influence of the free‐flooded aluminum ring on radiation directivity is analyzed, the size of the and calculate the free-flooded transducer based on fluid cavity structure, where the influence of the transducer aluminum is optimally designed, and directivity the performance is verified byofexperiments in is theoptimally anechoic free-flooded ring on radiation is analyzed, the size the transducer water tank. According to the the transducer size of the longitudinal vibration transducer, the longitudinal resonant frequency of the transducer is 4156 Hz, which is close to the above cavity resonant frequency
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
