声学MEMS传感器:展望钻头和地压监测

A. Turolla, M. Zampato, S. Carminati, P. Ferrara
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摘要

本文介绍了声学微机电系统(以下简称asA-MEMS)的设计和实现,该系统工作在流体耦合模式下,适用于与钻井、井和油藏监测等井下应用相关的高温高压规范。展望了a - mems在油气行业的许多前沿应用。目前的工作涉及作者开发的“超前预测”/地压监测技术(以下简称asPPM)的案例研究。带有磁穿梭换能器的A-MEMS不像MWD商用声波工具中常用的压电装置那样受环境压力的影响,不受体积收缩/膨胀工作原理的影响。这种性能还通过嵌入一个环境压力补偿器来实现,该补偿器在整个工作带宽中进行调谐,即使在声波频率(高达5 kHz)的振荡运动中也能实现压力平衡。发射机声功率和接收机灵敏度在500 ~ 3500hz的带宽范围内进行了优化。在井下T-P条件下(200°C, 700bar),利用充油压力容器和一个特别的测量装置(包括力、位移、温度传感器、发射器(TX)驱动器、接收器(RX)锁定放大器和采集系统),已经建立了几个A - mems原型,并成功进行了测试。利用Stewart平台进行了典型钻井工况下的模态分析。冲击高达1000克和随机振动高达12克RMS在5 ÷400 Hz带宽已经过测试。A-MEMS性能已被证明与理论模型预测一致,并表现出对T P变化和应用结构应力的鲁棒性。在岩石力学实验室中,通过三轴压缩单元验证了PPM方法,实现了一个实验室规模的场景,即盖层位于渗透性岩石之上,承受所有感兴趣的压力。然而,在实验中使用的压电换能器在压力增加时,随着性能的降低,其失效/损坏率显著降低。这些观察结果证实并推动了A-MEMS技术在井下应用的发展。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Acoustic MEMS Transducers: Look Ahead of the Bit and Geopressure Monitoring
This paper describes the design and implementation of Acoustic Micro Electro Mechanical Systems (hereinafter referred to asA-MEMS)working in fluid-coupling mode for HP/HT specifications relevant to downhole applications such as drilling, well and reservoir monitoring. Many cutting edges applications ofA-MEMS in Oil & Gas industry are envisaged. The current work refers to the case study of a "Look Ahead of the Bit"/geopressure monitoring technique (hereinafter referred to asPPM) developed by the authors. A–MEMS with magnetic shuttle transducers have been designed so that they are not affected by environmental pressure like piezoelectric devices commonly used in MWD commercial sonic tools, which are impaired by volumetric shrinking/expansion working principle. This performance is also achieved by embedding an environmental pressure compensator tuned in the whole working bandwidth to grant pressure balance even with oscillatory motion at sonic frequencies (up to 5 kHz). Transmitter acoustic power and receiver sensitivity have been optimized in a bandwidth between 500 and 3500 Hz. A couple of A–MEMS prototypes have been built and successfully tested by using an oil filled pressure vessel at downhole T–P conditions (200 °C, 700bar) and an ad-hoc measurement setup including force, displacement, temperature sensors, transmitter (TX) driver, receiver (RX) lock-in amplifier and anacquisition system. Moreover, modal analysis at typical drilling conditions has been carried out by Stewart platform. Shock up to 1000 g and random vibrations up to 12 g RMS in 5 ÷400 Hz bandwidth have been tested. A–MEMS performance have turned out to be consistent with theoretical model predictions andhave exhibited robustness to T P variations and applied structural stress. PPM method has been validated through a triaxial compression cell in a rock mechanics laboratory, implementing a lab scale scenario with a cap rock located above a permeable rock, undergoing all geopressures of interest. However, piezo transducers used in the experiment underwent a significant failure/damage rate along with performance degrading at pressure increasing. These observations confirmed and motivated the need for A-MEMS technology development in downhole applications.
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