金属纳米颗粒与聚合物阻垢剂复合增强阻垢技术的研究进展

P. Guraieb, R. Tomson, I. Littlehales
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引用次数: 2

摘要

由于聚合物阻垢剂在岩石表面的吸附性能较差,当泵入储层时,聚合物阻垢剂用于控制井下无机垢的挤压处理,效果不佳。然而,聚合物抑制剂比磷酸盐具有更高的温度稳定性,并且对水中升高的阳离子成分具有更高的耐受性。因此,开发了一种由金属纳米颗粒与聚合物阻垢剂偶联组成的新化学物质,以提高挤压寿命。近年来,纳米颗粒在油田中的应用有所增加;这一进展表明,纳米颗粒可以增加储层中阻垢剂的表面积和保留率。选择金属纳米颗粒是因为它们具有低环境毒性,并且在注入和反排过程中对地层的损害很小。研究人员开发了一种快速高效的合成方法,将纳米颗粒与聚合物抑制剂偶联,产生一种新的化学反应,希望能在多种岩石渗透率和成分中具有优异的挤压性能。在陆地二叠纪温度压力和盐水成分条件下,以及模拟海上常规油田条件下,对完整岩心进行了岩心驱油实验(结果将单独报道)。实验结果将显示,与传统的吸附式聚合物阻垢剂相比,新产品的挤压寿命更长,同时也将深入了解纳米颗粒/阻垢剂通过增加吸附和延长阻垢剂释放来延长挤压寿命的机制。根据所需的最小阻垢剂浓度,开发的产品能够显着增加聚合物阻垢剂的挤压寿命,最长可达10倍。缓蚀剂在岩石中的滞留量显著增加,而释放量在较长时间内控制在最低有效浓度以上。理论上的解释是,这是一种金属-抑制剂键,该产品专有,允许抑制剂持续释放到溶液中,而不会从岩石中释放出来。传统的挤压回流具有Freundlich等温线,该产品也遵循类似的回流曲线,但在处理回流开始时不会出现高浓度释放。这些结果表明,纳米颗粒可以用于油田中,以增强现有的阻垢剂,并创造出可以提高性能的新组合产品。纳米颗粒在油田中的应用是一个不断发展的课题,在油田化学的多个领域有很大的发展空间。该研究展示了纳米颗粒的应用,以提高聚合物阻垢剂的性能,同时保持产品的成本效益,对环境负责。
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Development of Scale Squeeze Enhancement Technology via Application of Metal Nanoparticles Coupled with Polymer Scale Inhibitors
Polymeric scale inhibitors used for scale squeeze treatments to control downhole inorganic scale don't perform well when pumped into the reservoir due to the poor adsorption properties on the rock surface. However polymeric inhibitors are more temperature stable than phosphonates and have higher tolerance to elevated cation compositions in the water. Therefore, a new chemistry composed of metal nanoparticles coupled with a polymeric scale inhibitor was developed to improve the squeeze life. The use of nanoparticles in the oilfield has increased in recent years; this development shows how nanoparticles can be used to increased surface area and retention of scale inhibitor in the reservoir. Metal nanoparticles were selected because of their low environmental toxicity and low formation damage potential during injection and flowback. A fast and efficient synthesis method was developed to create a novel chemistry that couples nanoparticles with polymeric inhibitors to produce a product that it was hoped would have excellent squeeze properties in multiple rock permeabilities and compositions. Core flood experiments were conducted on intact core under onshore Permian conditions of temperature pressure and brine composition as well as conditions simulating an offshore conventional field (results will be reported separately). The experimental results will be presented to show the extended squeeze lifetime of the new product in comparison to a traditional polymeric scale inhibitor retained by adsorption and also will give insight into the mechanisms by which the nanoparticle/scale inhibitor enhances squeeze life, both by increased adsorption as well as prolonging release of scale inhibitor. The product developed is able to significantly increase the squeeze life of polymeric scale inhibitors by up to 10x depending on the minimum inhibitor concentration required. The retention of the inhibitor into the rock is significantly increased, while the release is controlled at above minimum effective concentration for extended periods. The theoretic explanation for this is a metal-inhibitor bond, proprietary to the product that allows for continuous release of inhibitor into the solution, without release from the rock. Traditional squeeze returns have a Freundlich isotherm, this product also follows a similar return curve, however does not suffer from the high concentration release at the beginning of the treatment flowback. These results show that nanoparticles can be used in the oilfield to enhance existing scale inhibitors as well as create new combination products that can improve performance. Use on nanoparticles in the oilfield is an evolving topic that has significant room to grow and expand into multiple areas of oilfield chemistry. This study showcases the application of nanoparticles to enhance performance of polymeric scale inhibitors for squeeze application while maintaining a cost effective product that is environmental responsible.
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