颠覆性技术的综合导致了油藏监测可流动传感器的设计,通过载体浮力被动回收

Ting Chen, R. Shenoy, Indranil Roy, Jing Zhou
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引用次数: 1

摘要

在不使用电缆(生产测井)或钢丝绳,不使用泥浆脉冲、电磁或声波遥测,也不使用预安装或永久安装的井下传感器的情况下,测量井筒参数并在地面提供结果的技术差距仍然是一个有待弥补的领域。我们能够设计出轻质、高强度、高活性(可溶解)或耐腐蚀的纳米结构合金和智能微机电系统(MEMS)设备,使浮力传感器具有薄(毫米)壁,能够承受20,000 psi或更大的压差。这些传感器可以测量并记录客户所需的全套井筒参数(例如,压力、温度、深度、套管接箍、穿过射孔或井筒的流量、含水率、溶解O2等)。这些装置要么嵌套在不受盐度影响的水反应性合金外壳中,以帮助泵入深度,要么由可溶解合金的下沉器称重。这些装置在井筒内自由流动,因此它们可以在特定时间内放置在井下所需的深度,之后外壳溶解或下沉器重量下降,释放内部压力表。现在的浮力装置与产出的液体一起流回地面,在那里它们通过声音或感应信号表明自己的存在。我们公司的成立是为了利用材料科学和传感器领域的颠覆性创新,以及这些技术的合成,为深水领域和多级增产(MSS)市场提供卓越的性能产品。在本文中,我们将讨论我们的两个关键发明。首先,开发用于油藏监测的微型、独立、电池供电、自由流动的传感器设备,通过载体浮力被动回收。这种改变游戏规则的方法的一个子集是,“测量MSS期间的原位压力、温度和后续生产”。其次,我们提出了一种评估油田合金敏感性的机制,特别是在生产区的油藏流体中。这包括一个可回收的传感器装置,用于评估生产或关井过程中目标区域的环境对材料的影响,可以部署在从生产区域到泡点,再到地面分离器的任何地方。它使测试不需要在地面的模拟高压灭菌器环境中进行,而是在井下感兴趣的区域进行。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Synthesis of Disruptive Technologies Leads to Design of Flowable Sensors for Reservoir Monitoring, Passively Retrievable Through Carrier Buoyancy
Technology gaps in measuring wellbore parameters and providing the results at surface without using wireline (Production Logging) or slick-line, without using mud-pulse, electromagnetic or acoustic telemetry, or pre-installed or permanently installed downhole sensors remain an area to be bridged. Our ability to engineer light-weight, high-strength, highly-reactive (dissolvable) or corrosion-resistant, nanostructured-alloys and intelligent micro-electromechanical system (MEMS) devices have enabled design of buoyant sensors having thin (millimetric) wall, capable of withstanding 20,000 psi or more differential pressure. These sensors measure and record a complete set of the client’s required wellbore parameters (e.g., Pressure, Temperature, Depth, Casing collars, Flow-rate across perforations or in wellbore, Water cut, Dissolved O2, etc.). These devices are deployed, either nested in an outer shell of salinity independent water reactive alloy to abet pump down to depth or weighed down by a sinker of dissolvable alloy. These devices are free-flowing within a wellbore so that they can be placed downhole to required depth for a specific time, after which the outer shell dissolves or the sinker weight falls, releasing the inner gauge. The now buoyant device flows back to surface with produced fluids where they make their presence known by sonic or inductive signaling. Our company was founded to take advantage of these disruptive innovations in materials science and sensors and synthesis of these technologies to provide superior performance products for both deep-water domains and the multistage stimulation (MSS) market. In this article we address two of our key inventions. First, the development of miniature, self-contained, battery powered, free-flowing sensor devices for reservoir monitoring, passively retrievable through carrier buoyancy. A subset of this game changing approach, to economize operations is, "Measuring in- situ pressure, temperature, and subsequent production during MSS". Second, we present a mechanism to assess susceptibility of oilfield alloys, especially in live reservoir fluids at the production zone. This encompasses a retrievable sensor device to assess environmental effects on materials at target zone in wellbore during production or shut in, can be deployed anywhere from production zone to bubble point, to surface separator. It facilitates testing not in a simulated autoclave environment at surface, but downhole, at the zone of interest.
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