一种新型的大探测深度脉冲中子测量和增强储层饱和度评价系统

Y. Eltaher, G. Schmid
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引用次数: 0

摘要

尽管碳/氧(CO)测井在油田开发和油藏管理中具有重要价值和重要性,但它通常会带来与井筒测井环境和/或测量物理相关的重大挑战。浅探测深度被认为是与脉冲中子(PN)测量性质有关的最大挑战。这可能意味着测量和计算含水饱和度的高度不确定性,影响对储层流体饱和度的真实评估,特别是在具有挑战性的测井环境中。本文介绍并证明了一种增加PN测量研究深度的创新方法。目前,所有PN测井工具都使用电脉冲中子发生器(PNG),或“粒子加速器”或Minitron,以14 MeV的中子探测井下地层,并在浅探测深度(DOI)记录返回的伽马射线信号,通常在7英寸的C/O测量范围内,12英寸的sigma测量范围内。在这种新方法中,我们引入了通过增加PNG发射的中子的能级来增加被测伽马射线的DOI的想法。为了证明这一概念,利用蒙特卡罗n粒子(MCNP)对脉冲中子测井工具进行了计算机建模和仿真研究,以确定中子能量高于14 MeV的DOI。该研究涉及井眼流体和地层流体的五种不同组合。每个都涉及24个MCNP计算的“块”。每个区块内的24个计算代表了3种中子能量(14、20、40兆电子伏)、两种伽马射线谱类型(非弹性、俘获)和4种探测器的24种可能组合。数据模拟表明,所有被测探测器的DOI都随着能量的增加而大幅上升。其中,与俘获测量相比,非弹性测量中DOI随中子能量增加的增强更为显著。当然,探测器越深(离源越远)DOI越好,尽管这可能会损害测量的精度。然而,随着最近技术的进步,主要是PNG(产生更多的中子种群)和GR探测器技术(更高更快的计数率),这将提高测量的精度,使我们能够在更深的探测器上获得准确和精确的测量。这种专利的创新方法将大大减少并可能消除使用PN测井监测油藏饱和度不确定性的主要原因之一,即测量的调查深度较浅。与目前的行业标准相比,拥有能够产生更高能级中子的PNG将允许对储层进行更深入、更准确和更具代表性的评估。
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A Novel System for Large Depth-of-Investigation Pulsed Neutron Measurements and Enhanced Reservoir Saturation Evaluation
Despite its value and importance to oilfield development and reservoir management, carbon/oxygen (CO) logs are commonly associated with significant challenges that are either related to the wellbore logging environment and/or the physics of the measurement. Shallow depth of investigation is considered the greatest challenge related to the nature of the pulsed-neutron (PN) measurement. It can imply a high degree of uncertainty on the measurement and consequently the calculated water saturation, affecting the true assessment of the reservoir fluids’ saturations, especially in challenging logging environments. In this paper we introduce and prove an innovative approach to increase the depth of investigation of the PN measurement. Currently, all PN logging tools use an electric pulsed neutron generator (PNG), or "particle accelerator" or Minitron, to probe downhole formations with 14 MeV neutrons and record the returning gamma ray signal at a shallow depth of investigation (DOI), which is generally in the range of 7 inches for C/O measurement and 12 inches for sigma measurement. In this new approach, we introduce the idea of increasing DOI of the measured gamma rays through increasing the energy level of the neutrons emitted by a PNG. To prove the concept, a computer modeling and simulation study was conducted using Monte Carlo N-Particle (MCNP) for a pulsed-neutron logging tool to determine DOI for neutron energies higher than 14 MeV. The study involved five different combinations of borehole and formation fluids. Each involved a "block" of 24 MCNP calculations. The 24 calculations inside each block represented the 24 possible combinations of 3 neutron energies (14, 20, 40 MeV), two gamma ray spectral types (inelastic, capture), and four detectors. Data simulation shows that the DOI rises substantially with energy for all tested detectors. Where the enhancement in DOI with the increase in neutron energy is more prolific in case of the inelastic measurement compared to the capture measurement. And of course the deeper the detector (further from the source) the better the DOI, although this can compromise the precision of the measurement. Yet with the recent technology advancements mainly in PNG (producing more neutron population) and GR detector technology (higher and faster count rates), this shall enhance the precision of the measurement and enable us to acquire both accurate and precise measurements at deeper detectors. This patented, innovative approach shall significantly reduce and possibly eliminate one of the main reasons behind the uncertainty of reservoir saturation monitoring using PN logs, which is shallow depth of investigation of the measurement. Having a PNG that can produce neutrons at higher energy levels compared to current industry standard shall allow a deeper, more accurate and a representative evaluation of the reservoir.
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