自从二次采收机制、水驱或气体驱替出现以来，石油工业就遇到了各种问题，这些问题导致驱替过程中碳氢化合物流体的驱替效率低下。该行业在纠正这些不良清扫效率问题方面的成功率也非常低。本系列的前三篇文章旨在增强我们识别、表征、解决和评估应用于一致性或扫除效率问题的解决方案性能的能力。这种流程结构将使我们能够讨论在解决一致性问题时应产生更高成功率的关键要素。本系列的第 1 部分重点关注候选人选择和问题澄清或问题理解，这是图 1 的前两个要素。

概述

图 1 所示的流程轮用于确定大多数生产工程公司在解决一致性或解决效率问题时所采取的步骤。这为我们讨论解决这些问题的各个要素提供了基础。我工作过的公司选择将其称为“一致性工程”。让我们将一致性工程定义为：利用储层和井眼信息来了解洪水性能，然后利用这种了解来调整洪水的各个方面的过程。从而提高石油采收率。

这就是本系列文章将用于一致性工程的工作定义。我想我们都同意这包括各种各样的清扫效率问题。这些范围从深层油藏驱替流体控制问题到近井筒控制问题以及这些要素的每种组合。这包括控制注入器或生产井处的置换流体的问题。

我们还可以用它来理解和描述人为洪水与自然过程的关系。强含水层驱动具有与水驱相同的驱替机制。它们与压力源等元素有显着差异，压力源对于含水层驱动来说是广泛的，对于模式洪水来说是非常具体的点压力源。此外，强含水层驱动利用重力分离来提高驱动效率，而模式注水可能会遭受重力欠流。这是外围注水可以成为非常有效的二次采油工艺的原因之一。我们还考虑天然气上限扩张驱动石油驱替的领域。在一些油田，气顶由气体回注支持。普拉德霍湾（Prudhoe Bay）就是一个典型的例子，那里没有天然气市场，因此天然气回注到气顶和气顶扩张成为该油田强有力的恢复机制。

在本JPT文章系列中，我们将把任何洪水过程（无论是自然洪水还是诱导洪水）视为洪水管理基础知识的一部分。

候选人遴选

在候选选择步骤中，根据您的置换液，常见的说法是我们遇到“水或气体问题”。该说法是不正确的。我们所遇到的是问题的症状，那就是过量的水或气体。我们不知道我们的问题是什么。事实上，我们甚至不知道这种液体是否表明存在问题。我们需要改变我们的观点，认识到在任何洪水或驱替过程中，都会有大量驱替液到达我们的生产井。我们的关键问题是驱替液的高产量是否先于驱油过程中此阶段的预期采收效率。一些行业成员喜欢将其称为“好水”与“淡水”。但是，由于我们要考虑所有洪水或驱替过程，我建议我们使用术语“高效驱替液”和“ “低效驱替液。”我们的候选选择或识别过程应侧重于寻找驱替过程的驱替效率低于预期的井或模式。如果这种情况发生在洪水或水井的早期，通常很容易识别。在我们应对数十年洪水的情况下，这是一项更加艰巨的任务。排液量的快速变化是一种常见症状，但问题的具体性质仍不清楚。一旦确定了候选者，我们的注意力就应该集中在其他症状上。

问题澄清

对这项工作有帮助的一件事是利用对洪水的一些基本理解将信息和知识组织成一个简单的结构。乍一看这似乎非常简单，但专注于基础知识可以帮助避免迷失在巨大的信息森林中。在整个洪水管理和一致性控制过程中，它有助于保持对两个非常基本问题的关注：

1. 流体如何流过储液器以及为什么？

2. 过去和现在的井筒如何与储层相互作用？

这些基本问题应该成为每个油藏和生产工程师的基本关注点。这些问题说得很简单，但它们包含了我们需要理解的所有关键原则。要有效地回答这些问题需要多学科培训、大量数据、大量努力、团队合作和时间。

本文重点关注基本信息元素，因为要全面理解这些内容需要跨多个学科的多本书。以下部分旨在帮助我们划分可用的信息。下面讨论的每个信息部分都需要多年的培训和经验才能熟练掌握，并且每个常规部分的许多小节都有专家。提供这种结构仍然很有价值，以便我们可以独立讨论每个部分。这种简单化的观点是我对如何分解回答上述两个基本问题所需的信息的偏好。

储层和井眼特征。利用所有可用的发现、初级钻井、地球物理、地质和完井信息来生成储层和每个单独井眼的综合描述的过程。但请注意，这些描述不是静态的。随着额外数据的提供，它们将继续得到增强或改进。

储层和井筒监测。利用在油田生命周期中捕获的所有物理数据来对储层和各个井筒中发生的变化产生及时敏感的了解的过程。

储层和井筒测试。识别重要物理信息的过程，这些信息是更好地了解储层和/或井筒中发生的物理条件或变化所需的，并执行测试以评估这些关键物理参数。这些关键参数的例行或定期测试通常被纳入监测计划中。

储层和井眼建模。获取有关储层和/或井眼的部分或全部可用数据并将该信息纳入某些数学、数值或推理模型的过程，该模型旨在计算或描述或潜在地预测发生在某些部分或全部的物理过程储层或井筒的。

整合信息和由此产生的假设。关于组织储层和井眼信息的部分故意简短，因为无法公正地对待每个部分和小节中包含的所有信息。如果您在您的学位、学科或公司内接受过良好的技术培训，那么您已经花费了大量时间来学习这些信息中的许多非常复杂的细节。

不常见的讨论是如何处理空白点。在澄清问题的过程中，我们经常面临信息缺失或有限的情况，这迫使我们做出假设。这些假设可以很简单，例如“我们有良好的初级水泥工作”或“套管只有 2 年的历史，因此我们不可能有套管孔”，或者涵盖范围广泛，如： “所有岩心、测井、地震和其他储层描述数据都表明不存在天然断层或裂缝。”在许多情况下，这些基本的简化假设可能成为制定无效解决方案的关键部分。

决定您能否成功解决洪水或一致性问题的最重要因素是对您要解决的问题有一个全面的了解。过去对失败的一致性解决方案的研究表明，70% 到 80% 的失败都是因为我们误解了问题的某些方面。这包括简单的项目，例如不检查套管完整性或确认管道后面不存在水泥通道。这些故障都是对问题的误解，导致机械插头无法实现隔离。我经常听到有人告诉我，他们使用了某种产品，但该产品不起作用。我的经验表明，我们才是不工作的人。产品和技术通常会失败，因为它们被应用到了错误的问题上，或者它们被应用到了它们从未设计用来控制的问题的某个方面。因此，当我们无法正确描述和理解问题的各个方面时，结果就是技术应用失败，解决方案失败。

我们未能全面了解问题的主要原因是评估其所有重要方面往往太困难。这种困难和我们回避困难的人性使我们走捷径。这些捷径通常会导致假设，而这些往往会导致简单而快速的解决方案，但失败率非常高。我们必须认识到，每次我们假设，而这个假设是错误的，我们就降低了成功的潜力。当我们考虑每个一致性问题的性质时，我建议仔细查看您所做的所有假设可以帮助您避免许多失败。例如，您是否假设管道后面有良好的隔离？您了解储层深处各层之间的流动障碍的程度吗？这些流动屏障是否受到诱导裂缝或天然裂缝的破坏？您是否考虑过所有井眼渗透的历史方面？这些渗透物在哪里？它们是否在生产间隔内被适当地废弃以进行隔离？

用有限数量的假设产生全面的理解需要勤奋、经验、大量信息，并愿意花时间生成问题的完整历史及其发展过程。在大多数情况下，这不能由一个人完成，而是需要一个团队来评估潜在问题的多个方面。消除假设并不是一件容易的事。评估这些问题的团队需要一位经验丰富的领导者，他将保持勤奋并且不接受不必要的假设。这位领导者必须知道如何以及何时在问题的关键方面寻求具有成本效益的答案，特别是那些与我们可能认为是潜在解决方案相关的问题。

该问题的两个关键方面是什么？一是问题流程的基本性质。问题流路是充满液体的 VSC（空隙空间导管）吗？或者问题是流过渗透性岩石吗？问题的第二个关键方面是了解问题的控制点在哪里。在这种情况下，选项是靠近井眼或远离井眼的储层深处。为了帮助理解一致性问题的这两个关键方面，我们提供了“一致性问题矩阵”，矩阵上放置了各种一致性问题类型（图 2）。

此图表中并未列出所有一致性问题，但如果您考虑问题流程的这两个主要元素，我们应该能够将任何类型的一致性问题放在此矩阵上。请仔细研究并考虑该矩阵，因为这将是第 2 部分的关键要素。

在 6 月 JPT 上发表的第 2 部分中，对问题和问题矩阵进行了更深入的讨论。讨论了井眼干预解决方案以及如何将这些解决方案叠加到一致性问题矩阵之上。

编者注：David Smith 将于5 月 23 日至 24 日在德克萨斯州加尔维斯顿举行的采出水全生命周期管理 SPE 研讨会上发表“一致性工程基础知识” 。

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David Smith， SPE，目前是 Oilfield Conformance Consulting LLC 的总裁兼首席顾问，也是密苏里科技大学 (MS&T) 的兼职教授。在从事目前的工作之前，Smith 曾担任康菲石油公司或西方石油公司的全球一致性工程顾问大约 20 年。在此之前，他是 Halliburton 水管理一致性项目经理，并在 ARCO 中担任过与剖面修改和扫掠改进相关的多个职位。Smith 已成为 SPE 的活跃会员超过 45 年。他是 2014 年塔尔萨 SPE EOR/IOR 会议的技术项目主席、SPE EOR/IOR TIG（技术兴趣小组）的前联合主席，以及 2019 年至 2020 年 SPE 杰出讲师。史密斯拥有太平洋路德大学地质学学士学位和斯坦福大学石油工程硕士学位。

Since the advent of secondary recovery mechanisms, waterflooding or gas displacement, the oil industry has suffered from a variety of problems that yield inefficient displacement of hydrocarbon fluids during flooding. The industry has also suffered from a very low success rate at correcting these poor sweep efficiency problems. The first three articles in this series are designed to enhance our ability to identify, characterize, solve, and evaluate performance of solutions applied to conformance or sweep efficiency problems. This process structure will allow us to discuss key elements that should generate a higher success rate in solving conformance problems. Part 1 of this series focuses on candidate selection and problem clarification or problem understanding which are the first two elements of Fig 1.

Overview

The process wheel shown in Fig. 1 is used to identify the steps most production engineering companies take as they work through their conformance or sweep efficiency problems. This provides a basis by which we can discuss the various elements of solving these problems. The companies I have worked for chose to call this “conformance engineering.” Let’s define conformance engineering as: The process of utilizing reservoir and wellbore information to understand the flood performance and then use that understanding to adjust aspects of the flood which results in improved oil recovery.

That is the working definition this series of articles will use for conformance engineering. I think we can all agree that this includes a large variety of sweep efficiency problems. These range from deep reservoir displacement fluid control issues to near-wellbore control issues and every combination of these elements. This includes issues for controlling displacing fluids at the injector or the producer.

We can also use this to understand and characterize human-induced floods vs. natural processes. Strong water aquifer drives have the same displacement mechanisms as waterflooding. They have significant differences to elements like the pressure source, which is broad for aquifer drive and a very specific point source of pressure for pattern floods. In addition, a strong aquifer drive utilizes gravity segregation to enhance the efficiency of the drive where a pattern waterflood can suffer from gravity underrun. This is one of the reasons a peripheral waterflood can be a very effective secondary recovery process. We also consider fields where natural gas cap expansion drives oil displacement. In some fields, the gas cap is supported by gas reinjection. Prudhoe Bay is a prime example where there is no market for natural gas, so gas reinjection into the gas cap and gas cap expansion becomes a strong recovery mechanism for this field.

For the sake of this JPT article series we will consider any flood process whether natural or induced to be part of flood management basics.

Candidate Selection

In the candidate selection step, and depending on your displacing fluid, a common statement is we have a “water or gas problem.” That statement is incorrect. What we have is a symptom of the problem and that is excess water or gas. We do not know what our problem is. In fact, we don’t even know if that fluid indicates a problem. We need to change our perspective and recognize that during any flood or displacement process, a time will come when large quantities of displacing fluid will reach our production wells. Our key question is whether this high production volume of displacing fluid precedes the expected recovery efficiency for this stage in the flood process. Some industry members like to call this “good water” vs. “bad water.” However, since we want to consider all flood or displacement processes, I suggest we use the terms “efficient displacement fluid” and “inefficient displacement fluid.” Our candidate selection or identification process should focus on finding wells, or patterns where the displacement process has a lower displacement efficiency than expected. If this occurs early in the life of a flood or well, it is often very easy to identify. In situations where we are dealing with a multidecade flood, this is a more difficult task. Rapid changes in the displacing fluid production volume is a common symptom, but the specific nature of the problem is still unknown. Once the candidates are identified, our attention should then focus on other symptoms.

Problem Clarification

One thing that helps in this effort is to organize the information and knowledge into a simple structure utilizing some basic understandings about the flood. This may seem very simplistic at first but staying focused on the basics can help to avoid getting lost in the massive forest of information. Throughout the entire flood management and conformance control process it helps to maintain focus on two very basic questions:

1. How is fluid moving through the reservoir and why?

2. How does the wellbore, both past and present, interact with the reservoir?

These basic questions should be a fundamental focus for every reservoir and production engineer. These questions are stated very simply, but they contain all key principles of what we need to understand. To answer those questions effectively takes multidisciplined training, large quantities of data, massive effort, teamwork, and time.

This article focuses on the basic information elements since a comprehensive understanding of these items would take multiple books across multiple disciplines. The following sections are designed to help us compartmentalize the information we have available. Each section of information discussed below takes years of training and experience to become proficient, and many subsections of each general section have experts within them. There is still value in providing this structure so that we can discuss each section independently. This simplistic view is my preference on how to break down the information you will need to answer the two basic questions above.

Reservoir and Wellbore Characterization. The process of taking all available discovery, primary drilling, geophysical, geological, and completion information to generate a comprehensive description of both the reservoir and each individual wellbore. Note however these descriptions are not static. They continue to be enhanced or improved as additional data is provided.

Reservoir and Wellbore Monitoring. The process of utilizing all physical data that is captured over the life of the field to generate a time-sensitive understanding of the changes taking place in the reservoir and in individual wellbores.

Reservoir and Wellbore Testing. The process of identifying important physical information that is needed to gain a better understanding of physical conditions or changes that have taken place in the reservoir and/or the wellbore and executing a test to evaluate those key physical parameters. Routine or regular testing of these critical parameters are often incorporated into the monitoring program.

Reservoir and Wellbore Modeling. The process of taking some or all available data on the reservoir and/or the wellbore and incorporating that information into some mathematical, numerical, or inference model that is designed to calculate or describe or potentially predict the physical processes taking place in some portion or all of the reservoir or wellbore.

Integrating Information and the Resulting Assumptions. The sections on organizing reservoir and wellbore information are intentionally brief, because there is no way to do justice to all the information that is contained within each section and subsection. If you have had good technical training in your degree, discipline, or within your company, you have already spent considerable time learning very intricate details on much of this information.

What is not commonly discussed is what to do with the blank spots. In the process of clarifying our problems, we are often faced with missing or limited information, which forces us to make assumptions. These assumptions can be as simple as, “We have a good primary cement job,” or “The casing is only 2 years old, so there is no way we can have a casing hole,” or as encompassing as, “All core, log, seismic, and other reservoir description data indicated there are no natural faults or fractures.” In many cases, these basic simplifying assumptions can become the critical piece to formulating an ineffective solution.

The single greatest factor in determining your success at solving your flood or conformance problems is developing a comprehensive understanding of the problem you are trying to solve. Past studies on failed conformance solutions have shown that 70–80% of the times we fail, we fail because we misunderstand some aspect of the problem. This includes simple items like not checking the casing integrity or confirming no cement channel exists behind pipe. These failures are both examples of misunderstanding the problem which can prevent a mechanical plug from achieving isolation. I have often heard someone tell me that they have used a given product and that the product did not work. My experience indicates that we are the ones who do not work. Products and technology generally fail because they have been applied to the wrong problem or they are applied to an aspect of the problem they were never designed to control. Thus, when we fail to properly characterize and understand all aspects of the problem, the result is a failed application of the technology, and a failed solution.

The primary reason we fail to gain a comprehensive understanding of the problem is that it is often too difficult to evaluate all its important aspects. This difficulty and our human nature to avoid difficulty causes us to take shortcuts. These shortcuts usually result in assumptions, and those often result in simple and quick solutions that have a very high failure rate. What we must realize is that every time we assume, and that assumption is wrong, we have just lowered our potential for success. As we consider the nature of each conformance problem, I suggest that taking a careful look at all the assumptions you are making can help you to avoid many failures. For example, are you assuming good isolation behind pipe? Do you understand the extent of the flow barriers between layers deeper in the reservoir? Have those flow barriers been compromised by induced or natural fractures? Have you considered the historical aspect of all wellbore penetrations? Where are these penetrations and were they properly abandoned for isolation within the producing interval?

Generating a comprehensive understanding with a limited number of assumptions requires diligence, experience, vast quantities of information, and a willingness to spend the time generating a complete history of the problem and how it developed. In most cases this cannot be done by a single individual but requires a team of people to evaluate the many aspects of the potential problem. Elimination of assumptions is not an easy thing to do. The team evaluating these problems requires an experienced leader who will remain diligent and not accept unnecessary assumptions. This leader must know how and when to push for cost-effective answers on the critical aspects of the problem, especially those that relate to what we might consider as a potential solution.

What are two of the key critical aspects of the problem? One is the basic nature of the problem flow path. Is the problem flow path a fluid filled VSC (void space conduit)? Or is the problem flow through permeable rock? The second critical aspect of the problem is understanding where the control exists for the problem. In this case the options are near the wellbore or deep in the reservoir away from the wellbore. To help understand these two critical aspects of conformance problems, a “Conformance Problem Matrix” has been provided with a variety of conformance problem types placed onto the matrix (Fig. 2).

Not every conformance problem is presented in this chart, but if you consider these two major elements of the problem flow, we should be able to place any type of conformance problem on this matrix. Please study and consider this matrix carefully since this will be a key element of Part 2.

In Part 2, published in the June JPT, provides a more in-depth discussion on the problems and the problem matrix. Wellbore intervention solutions and how to overlay these solutions on top of the conformance problem matrix are discussed.

Editor's note: David Smith will be presenting "Basics of Conformance Engineering" at the SPE Worshop on Full Life Cycle Mangement of Produced Water, 23–24 May, in Galveston, Texas.

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David Smith, SPE, is currently the president and principal advisor for Oilfield Conformance Consulting LLC and an adjunct professor for Missouri University of Science and Technology (MS&T). Prior to his current efforts and for approximately 20 years, Smith was the global conformance engineering advisor for either ConocoPhillips or Occidental Petroleum. Prior to that he was a project manager in conformance water management for Halliburton and held several positions within ARCO that were associated with profile modification and sweep improvement. Smith has been an active SPE member for more than 45 years. He was the technical program chairman for the 2014 SPE EOR/IOR Conference in Tulsa, a past co-chairman of the SPE EOR/IOR TIG (Technical Interest Group), and an SPE Distinguished Lecturer in 2019–2020. Smith holds a bachelor’s degree in geology from Pacific Lutheran University and an MS in petroleum engineering from Stanford University.