Three-Dimensional Acoustic Device for Testing the All-Directional Anisotropic Characteristics of Rock Samples
Abstract
:1. Introduction
2. Design and Test of the 3-D Measurement Device
2.1. Structural Design of the Device
2.2. Workflow of the Measurement Device
- Measure the radius of the rock sample and enter this data into the computer control software.
- Push the rock sample into the instrument and lock it vertically and horizontally. Thereafter, automatically lift the rock sample with the support rod to a suitable position.
- Place the pair of transducers into the holders and fix them to the initial measurement positions.
- Produce electrical excitation signals with the signal generator that are amplified by the amplifier and loaded on the transmitting transducers to generate acoustic signals.
- Propagate the acoustic signals into the rock. These reach the receiving transducers and are then collected by the oscilloscope and uploaded to the computer.
- Rotate the transducers synchronously in the vertical direction by a latitude of ϕ and repeat steps 3–5 until all the measurements in one circle are finished.
- Loosen the rock sample, rotate it by a longitude of λ in the horizontal direction, and re-lock it again. Then, repeat steps 3–6 until the measurements are completed in all directions.
3. Examples of Measurements by the Device
3.1. Measurement of Longitudinal Waves
3.2. Measurement of Shear Waves
4. Discussion
4.1. Calculation of Velocities
4.2. Calculation of Elastic Physical Parameters
5. Conclusions
- The measured granite rock samples exhibited anisotropy characteristics. The velocities of its longitude and shear waves changed with the measured latitude circle, and the velocities were biggest when the circles were parallel to the bedding direction of the rock sample. The anisotropy characteristics were very small in the longitude orientations, and little velocity change happened.
- The velocities of the longitudinal and shear waves were positively related. The calculated goodness of fit was 0.7416. The relationship between the compressional and shear wave velocities of the granite samples was similar to those of sandstone and mudstone.
- The anisotropy characteristics of Poisson’s ratio, bulk modulus, shear modulus, and Young’s modulus were calculated based on the measured velocities of the longitudinal and shear waves. These data play an important role in guiding formation fracturing and analyzing the stability of borehole walls in the processes of exploration and exploitation.
- The design principle of the 3-D acoustic measurement device could also be used in devices for other kinds of measurements, such as resistivity, permeability, and computed tomography measurements.
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
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Zhang, K.; Li, S.; Su, Y.; Tan, B.; Wu, W.; Xin, S. Three-Dimensional Acoustic Device for Testing the All-Directional Anisotropic Characteristics of Rock Samples. Sensors 2022, 22, 9473. https://doi.org/10.3390/s22239473
Zhang K, Li S, Su Y, Tan B, Wu W, Xin S. Three-Dimensional Acoustic Device for Testing the All-Directional Anisotropic Characteristics of Rock Samples. Sensors. 2022; 22(23):9473. https://doi.org/10.3390/s22239473
Chicago/Turabian StyleZhang, Kai, Shengqing Li, Yuanda Su, Baohai Tan, Wenjie Wu, and Shoutao Xin. 2022. "Three-Dimensional Acoustic Device for Testing the All-Directional Anisotropic Characteristics of Rock Samples" Sensors 22, no. 23: 9473. https://doi.org/10.3390/s22239473
APA StyleZhang, K., Li, S., Su, Y., Tan, B., Wu, W., & Xin, S. (2022). Three-Dimensional Acoustic Device for Testing the All-Directional Anisotropic Characteristics of Rock Samples. Sensors, 22(23), 9473. https://doi.org/10.3390/s22239473