New geophysical memory-logging system for highly unstable and inclined scientific exploration drilling

IF 1.6 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Scientific Drilling Pub Date : 2021-04-26 DOI:10.5194/SD-29-39-2021

J. Kück, Marco Groh, Martin Töpfer, A. Jurczyk, U. Harms

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引用次数: 3

Abstract

Abstract. We established a cable-free memory-logging system for drill-string-deployed geophysical borehole measurements. For more than 20 years, various so-called “logging while tripping” (LWT) techniques have been available in the logging service industry. However, this method has rarely been used in scientific drilling, although it enables logging in deviated and unstable boreholes, such as in lacustrine sediment drilling projects. LWT operations have a far lower risk of damage or loss of downhole logging equipment compared with the common wireline logging. For this purpose, we developed, tested, and commissioned a modular memory-logging system that does not require drill string modifications, such as special collars, and can be deployed in standard wireline core drilling diameters (HQ, bit size of 96 mm, and PQ, bit size of 123 mm). The battery-powered, autonomous sondes register the profiles of the natural GR (gamma radiation) spectrum, sonic velocity, magnetic susceptibility, electric resistivity, temperature, and borehole inclination in high quality while they are pulled out along with the drill string. As a precise depth measurement carried out in the drill rig is just as important as the actual petrophysical downhole measurements, we developed depth-measuring devices providing a high accuracy of less than 0.1 m deviation from the wireline-determined depth. Moreover, the modular structure of the system facilitates sonde deployment in online mode for wireline measurements.

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高不稳定倾斜科学勘探钻井物探记忆测井新系统

摘要我们建立了一套无电缆记忆测井系统，用于钻柱部署的地球物理井眼测量。20多年来，在测井服务行业中出现了各种所谓的“随起下钻测井”(LWT)技术。然而，这种方法很少用于科学钻井，尽管它可以在斜度和不稳定的井眼中进行测井，例如在湖泊沉积物钻井项目中。与普通电缆测井相比，LWT作业的井下测井设备损坏或丢失的风险要低得多。为此，我们开发、测试并调试了一种模块化记忆测井系统，该系统不需要修改钻柱，例如特殊的钻铤，并且可以在标准电缆岩心钻井直径(HQ，钻头尺寸为96 mm, PQ，钻头尺寸为123 mm)中部署。当随钻柱一起被取出时，电池供电的自主探空仪可以高质量地记录自然GR(伽马辐射)谱、声速、磁化率、电阻率、温度和井眼倾角的剖面。由于在钻机上进行的精确深度测量与实际的井下岩石物理测量同样重要，因此我们开发了深度测量设备，其精度与电缆测量深度的偏差小于0.1 m。此外，该系统的模块化结构便于在在线模式下部署探空仪进行有线测量。

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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