Your search keyword '"Low-field NMR"' showing total 2 results

1. Experimental investigation of the effects of long-period cyclic pulse loading of pulsating hydraulic fracturing on coal damage.

Author

Yu, Xu, Chen, Aikun, Hong, Lei, Zhai, Cheng, Regenauer-Lieb, Klaus, Sang, Shuxun, Xu, Jizhao, and Jing, Yu

Subjects

*HYDRAULIC fracturing, *CYCLIC loads, *COAL, *FATIGUE cracks, *COALBED methane, *ENERGY consumption

Abstract

• Fatigue effect of the PHF is dependent on the time scale of pulsating loading. • Coal porosity increases with the increased pulsating pressure based on the LF-NMR. • A larger pulsating pressure leads to a lower cracking pressure. • The PHF creates more cracks and higher porosity than the HF according to CT images. Coalbed methane recovery can largely ease the crisis of annually increasing energy consumption of China. Low permeability and porosity of deep coal reservoirs mainly cause the low gas production rate. Pulsating hydraulic fracturing (PHF) is an alternative tool to improve the reservoir permeability and stimulate the gas productivity. However, little has been done to directly observe the fatigue damage in coal created by the pulsating loading. Because the fatigue damage is primarily governed by the time-length of PHF period. Therefore, the effect of long period pulsating loading of PHF on coal damage has been investigated in this work. Results show that long-period pulsating loading of PHF can cause significant damage in coal. The low-field NMR data indicates coal porosity increases with the increase of maximum pulsating pressure. Pulsating pressure also plays an important role in the cracking pressure. A larger pulsating pressure leads to a lower cracking pressure. Comparison of PHF and HF damaged coal investigated by the X-ray CT indicates the PHF creates more fractures and higher porosity than conventional hydraulic fracturing. The increase ratios of the coal porosity by HF and PHF are 40 %–60 % and 80 %–100 %, respectively. This paper provides a better understanding the mechanism of the coal damage by the PHF under long-period pulsating loading which is of great importance for optimizing PHF technique and generating connected fracture networks. [ABSTRACT FROM AUTHOR]

Published

2024

2. Distribution Model of Fluid Components and Quantitative Calculation of Movable Oil in Inter-Salt Shale Using 2D NMR.

Author

Yan, Weichao, Sun, Fujing, Sun, Jianmeng, Golsanami, Naser, and Torres, José A.

Subjects

*SHALE oils, *OIL shales, *GAS condensate reservoirs, *NUCLEAR magnetic resonance, *GAS reservoirs, *PROBLEM solving, *DRILL core analysis

Abstract

Some inter-salt shale reservoirs have high oil saturations but the soluble salts in their complex lithology pose considerable challenges to their production. Low-field nuclear magnetic resonance (NMR) has been widely used in evaluating physical properties, fluid characteristics, and fluid saturation of conventional oil and gas reservoirs as well as common shale reservoirs. However, the fluid distribution analysis and fluid saturation calculations in inter-salt shale based on NMR results have not been investigated because of existing technical difficulties. Herein, to explore the fluid distribution patterns and movable oil saturation of the inter-salt shale, a specific experimental scheme was designed which is based on the joint adaptation of multi-state saturation, multi-temperature heating, and NMR measurements. This novel approach was applied to the inter-salt shale core samples from the Qianjiang Sag of the Jianghan Basin in China. The experiments were conducted using two sets of inter-salt shale samples, namely cylindrical and powder samples. Additionally, by comparing the one-dimensional (1D) and two-dimensional (2D) NMR results of these samples in oil-saturated and octamethylcyclotetrasiloxane-saturated states, the distributions of free movable oil and water were obtained. Meanwhile, the distributions of the free residual oil, adsorbed oil, and kerogen in the samples were obtained by comparing the 2D NMR T1-T2 maps of the original samples with the sample heated to five different temperatures of 80, 200, 350, 450, and 600 °C. This research puts forward a 2D NMR identification graph for fluid components in the inter-salt shale reservoirs. Our experimental scheme effectively solves the problems of fluid composition distribution and movable oil saturation calculation in the study area, which is of notable importance for subsequent exploration and production practices. [ABSTRACT FROM AUTHOR]

Published

2021