Multi-scale and multi-component digital core construction and elastic property simulation*

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Abstract The conventional digital core models are usually small in size and have difficulty in representing the complex structures of heterogeneous rocks; Therefore, the parameters of simulated rock physics are diffi cult to be referenced. In this study, we propose a feasible simulation method for obtaining multi-scale and multi-component digital cores based on three types of sandstone samples. In the proposed method, the plug and subplug samples are scanned via micro-computed tomography at diff erent resolutions. Furthermore, the images are precisely registered using the proposed hybrid image registration method. In case of high-resolution images, the traditional segmentation method is used to segment the cores into pores and minerals. Subsequently, we established the relations between the gray values and the porosity/ mineral content in case of the low-resolution images based on the registered domains and the relation curves were applied to the segmentation of the low-resolution images. The core images constitute the multi-scale and multi-component digital core models after segmentation. Further, the elastic properties of the three samples were simulated at both fine and coarse scales based on the multi-scale and multi-component digital core models, and four component models were considered. The results show that the multi-scale and multi-component digital core models can overcome the representative limits of the conventional digital core models and accurately characterize pores and minerals at diff erent scales. The numerical results of the elastic modulus are more representative at large scales, and considerably reliable results can be obtained by appropriately considering the minerals.

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Key words： elastic properties digital core multi-scale multi-component

Received: 2018-06-02; Published: 2020-09-04

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This work was supported by the National Natural Science Foundation of China Research (Nos. 41574122 and 41374124) and National Science and Technology major Project (No. 2016ZX05006002-004).

Corresponding Authors: Sun Jian-Meng (Email: sunjm@upc.edu.cn)
E-mail: sunjm@upc.edu.cn

About author: Cui Li-kai received his bachelor degree in physics from Binzhou University in 2009. In 2012, he obtained a master’s degree in theoretical physics from Qufu Normal University. He is currently a doctoral candidate majoring in Geological Resource and Geological Engineering at the School of Geosciences of China University of Petroleum. His research interests include well logging interpretation, digital rock modeling, and numerical simulations.

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. Multi-scale and multi-component digital core construction and elastic property simulation*[J]. APPLIED GEOPHYSICS, 2020, 17(1): 26-36.

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