Magnetically controlled self-sealing pressure-preserved coring technology

IF 6 1区工程技术 Q2 ENERGY & FUELS

Petroleum Science Pub Date : 2024-10-01 DOI:10.1016/j.petsci.2024.05.003

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Abstract

Pressure-preserved coring is an effective means to develop deep resources. However, due to the complexity of existing pressure-preserved technology, the average success rate of pressure-preserved coring is low. In response, a novel in situ magnetically controlled self-sealing pressure-preserved coring technology for deep reserves has been proposed and validated. This innovative technology distinguishes itself from conventional methods by employing noncontact forces to replace traditional pre-tensioning mechanisms, thereby enhancing the mechanical design of pressure-preserved coring equipment and significantly boosting the fault tolerance of the technology. Here, we report on the design, theoretical calculations, experimental validation, and industrial testing of this technology. Through theoretical and simulation calculations, the self-sealing composite magnetic field of the pressure controller was optimized. The initial pre-tensioning force of the optimal magnetic field was 13.05 N. The reliability of the magnetically controlled self-sealing pressure-preserved coring technology was verified using a self-developed self-sealing pressure performance testing platform, confirming the accuracy of the composite magnetic field calculation theory. Subsequently, a magnetically controlled self-triggering pressure-preserved coring device was designed. Field pressure-preserved coring was then conducted, preliminarily verifying the technology's effective self-sealing performance in industrial applications. Furthermore, the technology was analyzed and verified to be adaptable to complex reservoir environments with pressures up to 30 MPa, temperatures up to 80 °C, and pH values ranging from 1 to 14. These research results provide technical support for multidirectional pressure-preserved coring, thus paving a new technical route for deep energy exploration through coring.

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磁控自密封压力保留取芯技术

压力保留岩心取样是开发深层资源的有效手段。然而，由于现有压力保留技术的复杂性，压力保留岩心取样的平均成功率较低。为此，我们提出并验证了一种用于深层储量的新型原位磁控自密封压力保留岩心取样技术。这项创新技术有别于传统方法，它采用非接触式力来取代传统的预张力机制，从而增强了压力保留岩心取样设备的机械设计，并显著提高了该技术的容错能力。在此，我们报告了该技术的设计、理论计算、实验验证和工业测试。通过理论和仿真计算，对压力控制器的自密封复合磁场进行了优化。利用自主研发的自密封压力性能测试平台，验证了磁控自密封压力保芯技术的可靠性，证实了复合磁场计算理论的准确性。随后，设计了磁控自触发保压取心装置。然后进行了现场保压取心，初步验证了该技术在工业应用中的有效自密封性能。此外，还分析并验证了该技术可适应压力高达 30 兆帕、温度高达 80 °C、pH 值介于 1 到 14 之间的复杂储层环境。这些研究成果为多向保压岩心取样提供了技术支持，从而为通过岩心取样进行深层能源勘探开辟了一条新的技术路线。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Petroleum Science 地学-地球化学与地球物理

CiteScore

7.70

自引率

16.10%

发文量

311

审稿时长

63 days

期刊介绍： Petroleum Science is the only English journal in China on petroleum science and technology that is intended for professionals engaged in petroleum science research and technical applications all over the world, as well as the managerial personnel of oil companies. It covers petroleum geology, petroleum geophysics, petroleum engineering, petrochemistry & chemical engineering, petroleum mechanics, and economic management. It aims to introduce the latest results in oil industry research in China, promote cooperation in petroleum science research between China and the rest of the world, and build a bridge for scientific communication between China and the world.