中国科学院重庆绿色智能技术研究院机构知识库

Changes in the P-wave and S-wave velocities (V-p and V-s, respectively) and their ratio at different gas saturations in carbonate rock were investigated experimentally in this study. The results showed the following: (I) Both the P-wave velocity and V-p/V-s tended to decrease as the gas saturation increased, while the S-wave velocity marginally decreased or remained constant. These measured results were in agreement with the theoretical calculations of the Gassmann fluid substitution equation. (2) The acoustic velocity was related to the acoustic frequency. Most rock samples showed the tendency of V-p (1000 kHz) < V-p (50 kHz) < V-p (250 kHz) and V-s (1000 kHz) < V-s (50 kHz) < V-s (250 kHz). The primary distribution domain of V-p/V-s also varied with different frequencies and generally showed that V-p/V-s when S-g = 0% was larger than that when S-g = 100%. (3) Considering fully saturated rock as the water zone, it was found that V-p/V-s decreases from its initial value as the gas pressure increases; a sharper decline, indicating a transition from the water zone to the gas zone, was also found. Additionally, the integrated use of a cross-plot analysis of V-p/V-s vs. P-wave impedance was used to more accurately identify the gas zone in carbonate rock. This study provides some helpful references for gas-zone identification in carbonate rock using acoustic logging data in practical applications. (C) 2015 Elsevier B.V. All rights reserved.