What Can We Learn from Analysis of Field Asphaltenes Deposits? Enhancing Product Development Through Knowledge-Based Field-to-Lab-to-Field Approach

J. I. Aguiar, Claudia Mazzeo, R. Garan, A. Punase, Syed Razavi, A. Mahmoudkhani
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引用次数: 2

Abstract

Recent studies revealed that solids from lab-generated deposits often exhibit compositional differences from those of field deposits, pointing to a more complex fouling process in field operations. The objective of this work was to understand and apply knowledge from field deposit characteristics in order to design and conduct laboratory experiments which yield solid deposits with comparable compositional fingerprints. This approach allows a more objective and reliable product development and recommendation strategy to be adopted for increased success in the field applications. First, oil and deposit samples from an offshore field was characterized. Second, samples of the asphaltenes extracted from oil (AEO) and from the deposit (AED) were characterized based on solubility using an Accelerated Solubility Test (AST). A customized Asphaltene Dynamic Deposition Loop (ADDL) was used in this study to simulate the precipitation and deposition of asphaltenes from the crude oil. Crude oil used in the tests was from the same well where the deposits were collected. ADDL tests were conducted at high temperature and pressure and the composition of the collected deposit from this test was compared with the deposits from the field. At last, Light Scattering Technique (LST) was applied to screen asphaltene inhibitors (AI). Four candidate chemistries were tested on LST. To confirm the efficiency, the high performer was tested on ADDL under dynamic conditions. Deposits collected from the ADDL were characterized and results showed a high degree of similarity to the field deposit. AI1 was evaluated by ADDL and it decreased the deposition in the filters by 60% and 84% at 1000 ppm. This product was selected to be tested in the field and a plant trial is ongoing.
野外沥青质沉积分析有何启示?通过以知识为基础的领域到实验室到领域的方法加强产品开发
最近的研究表明,实验室生成的沉积物中的固体成分往往与现场沉积物中的固体成分不同,这表明在现场作业中存在更复杂的结垢过程。这项工作的目的是了解和应用实地沉积物特征的知识,以便设计和开展实验室实验,以产生具有可比成分指纹的固体沉积物。这种方法允许采用更客观和可靠的产品开发和推荐策略,以提高现场应用的成功率。首先,对海上油田的石油和沉积物样品进行了表征。其次,利用加速溶解度试验(AST)对从石油(AEO)和沉积物(AED)中提取的沥青质样品进行溶解度表征。在这项研究中,使用了一个定制的沥青质动态沉积环路(ADDL)来模拟原油中沥青质的沉淀和沉积。试验中使用的原油来自收集沉积物的同一口井。在高温高压下进行了ADDL试验,并将该试验收集的沉积物组成与现场沉积物进行了比较。最后,应用光散射技术(LST)筛选沥青烯抑制剂。在LST上测试了四种候选化学物质。为了验证其有效性,在动态条件下在ADDL上进行了高性能测试。对从ADDL收集的矿床进行了特征分析,结果显示与野外矿床高度相似。用ADDL对AI1进行了评价,在1000ppm时,AI1可使滤池中的沉积分别减少60%和84%。该产品已被选中进行田间试验,目前正在进行植物试验。
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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