Active Cooling Method for Downhole Systems in High Temperature Environment

Wenkai Gao, L. Ke, Yinao Su, Limin Sheng, Cao Chong, Xiurong Dou, Lei. Zhang
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引用次数: 7

Abstract

With the further exploration of oil and gas, we have to search for new resources which buried in deep strata, and most of the deep and ultra-deep wells are categorized in high-pressure/high-temperature (HPHT) wells. The problem of high temperature and the challenge to the existing downhole equipments are becoming increasingly prominent, where the drilling depth is severely restricted. Most of the HPHT or ultra-HPHT wells with reservoir temperature about 175~220°C would be drilled with near-bit measurement and constructed. In such a temperature environment, the conventional measurement while drilling tools with common electronics will experience very high failure rates at these conditions. There are two ways to deal with the downhole electronics system in HPHT wells. One technique is called the passive cooling, which aims to improve the anti-temperature performance of the components and add thermal insulation materials to the circuit module. In this way, the cost of the instruments would be greatly increased, and the capacity for anti temperature could not be improved indefinitely, especially in HPHT or ultra-HPHT environment for lone period. The other solution is called the active cooling, which commit to the construction of a downhole refrigeration system. The cooling system power by bettery or downhole generator ensures clectronics cabin always under suitable temperature. According to a large number of research work by scholars worldwide, there are 2 main kinds of downhole active cooling techniques suitable for while-drilling environment. One is thermoelectric based regeneratiove cooling system, and the other technique is based on regenerative cryogenic refrigeration cycle. The thermodynamic cycle and working fluid are key concerns for the refrigeration. While reverse-Brayton cycle contains adiabatic compression, isobaric heat transfer, adiabatic expansion and isobaric heat transfer, so thermoacoustic coolers, stirling cryocoolers, and pulse tube refrigerators can all be suitable solution. The study from this work demonstrates the active cooling method for downhole systems using in high-temperature environment, and provides a baseline framework for design methods. The preliminary laboratory test and application showed the feasibility of the method.
高温环境下井下系统的主动冷却方法
随着油气勘探的深入,我们必须寻找埋藏在深层的新资源,而大多数深井和超深井都属于高压高温井。高温问题和对现有井下设备的挑战日益突出,严重制约了钻井深度。对于储层温度在175~220℃的高温高压或超高温井,大多采用近钻头测量钻进施工。在这样的温度环境下,使用普通电子设备的传统测量钻井工具在这些条件下的故障率非常高。高压高温井的井下电子系统有两种处理方法。一种技术被称为被动冷却,其目的是提高组件的抗温度性能,并在电路模块中添加隔热材料。这样不仅会大大增加仪器的成本,而且不能无限期地提高仪器的抗温能力,特别是在高温或超高温环境下的长期抗温能力。另一种解决方案被称为主动冷却,它致力于建造一个井下制冷系统。冷却系统采用蓄电池或井下发电机供电,保证电子舱室始终处于适宜的温度下。根据国内外学者的大量研究工作,适合随钻环境的井下主动冷却技术主要有两种。一种是基于热电的蓄热式制冷系统,另一种是基于蓄热式低温循环的制冷技术。热力学循环和工质是制冷系统的关键问题。而逆布雷顿循环包含绝热压缩、等压传热、绝热膨胀和等压传热,因此热声制冷机、斯特林制冷机和脉管制冷机都可以作为合适的解决方案。这项工作证明了高温环境下井下系统的主动冷却方法,并为设计方法提供了基准框架。初步的实验室试验和应用表明了该方法的可行性。
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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