The Influence of Polymers and Nanomaterials on the Kinetics, Flow Characteristics and Surface Interactions of Hydrate/Ice Forming Systems

聚合物和纳米材料对水合物/冰形成系统的动力学、流动特性和表面相互作用的影响

• 批准号: RGPIN-2018-05035
• 负责人: Servio, Phillip
• 金额: $ 2.4万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=747187
• 关键词: Influence; Polymers; Nanomaterials; Kinetics; Flow

Water is one of the most unique compounds in nature that is not only essential for life but also plays a significant role in many processes related to energy and safety. Water can exist in many solid forms when it is exposed to the proper conditions and components but two of the most important are: Gas Hydrate and Ice. Naturally occurring gas hydrates hold enormous amounts of stored energy that exceed conventional carbon reserves and mostly contain natural gas, the cleanest of all fossil fuels. Hence, they are being considered as a new/alternative method to sustain our ever increasing energy demands and preserve our quality of life. Carbon dioxide is also a major component in the emissions of thermal power plants, which contributes to global warming. The gas storage properties of hydrates position it as a potential candidate for capturing and sequestering carbon dioxide in order to lower its emissions and abide by the 2016 Paris Agreement, which Canada and 167 other nations agreed to. Complications arising from gas hydrate formation can also pose a significant threat to machinery and equipment in oil and gas processes. Its formation has even led to the loss of life and environmental devastation, as evidenced by the infamous British Petroleum oil spill of 2010. Similarly, ice accretion can cause catastrophic devastation such as the 1998 ice storm that hit Eastern Canada and the Northeastern U.S. Ice that forms on modern infrastructure such as aircrafts, ships, offshore oil platforms, wind turbines, telecommunications and power transmission lines jeopardizes their integrity and poses a significant safety hazard to operators and civilians alike. For these reasons, it is important to study both these phase change processes in order to provide information that is essential for the design of safe, economical, and environmentally responsible processes and facilities to deal with gas hydrate and ice formation. In order to accomplish this, a better understanding of the following is required. 1) Kinetics: Inhibition of gas hydrate formation via water-soluble polymers tailored using block copolymer self-assembly. 2) Rheology: Investigation of the effects of nanofluids and water-soluble polymers on the flow of water as it transitions to either gas hydrate or ice. 3) Surface interactions: Design and testing of hydrate-phobic and icephobic coatings comprised of polymer, nanomaterial and biomimetic surfaces. These three targeted areas will allow us to garner a better understanding of hydrate and ice and how to possibly exploit them by controlling and manipulating their interactions. The outcome of this work has the potential to place Canada at the forefront of technologies related to: 1) De-crystallizing techniques that preclude hydrate and ice accretion, 2) Natural gas recovery from in situ gas hydrate formations and 3) Storage and transportation of methane and carbon dioxide in gas hydrate form.

水是自然界中最独特的化合物之一，不仅对生命至关重要，而且在许多与能源和安全相关的过程中发挥着重要作用。当水暴露在适当的条件和成分下时，它可以以许多固体形式存在，但最重要的两种是：气体水合物和冰。天然气水合物储存了大量的能量，超过了传统的碳储量，其中大部分含有天然气，这是所有化石燃料中最清洁的。因此，它们被认为是一种新的/替代的方法，以维持我们不断增长的能源需求和保持我们的生活质量。二氧化碳也是火力发电厂排放的主要成分，导致全球变暖。水合物的储气特性使其成为捕获和封存二氧化碳的潜在候选者，以降低其排放并遵守加拿大和其他167个国家同意的2016年巴黎协定。天然气水合物形成过程中产生的复杂问题也会对石油和天然气加工过程中的机械和设备构成重大威胁。它的形成甚至导致生命损失和环境破坏，2010年臭名昭著的英国石油公司漏油事件就是证明。类似地，积冰可能造成灾难性的破坏，例如1998年袭击加拿大东部和美国东北部的冰风暴。在飞机、船舶、海上石油平台、风力涡轮机、电信和输电线路等现代基础设施上形成的冰危及其完整性，并对运营商和平民构成重大安全隐患。由于这些原因，重要的是要研究这两个相变过程，以提供信息，是必不可少的设计安全，经济，环保的过程和设施，以处理气体水合物和冰的形成。为了做到这一点，需要更好地理解以下内容。1)动力学：通过使用嵌段共聚物自组装定制的水溶性聚合物抑制气体水合物形成。2)流变学：研究纳米流体和水溶性聚合物在水转变为气体水合物或冰时对水流动的影响。3)表面相互作用：由聚合物、纳米材料和仿生表面组成的憎水和憎冰涂层的设计和测试。这三个目标领域将使我们能够更好地了解水合物和冰，以及如何通过控制和操纵它们的相互作用来利用它们。这项工作的成果有可能使加拿大处于以下技术的前沿：（1）防止水化物和积冰的去结晶技术，（2）从天然气水化物地层中回收天然气，（3）以天然气水化物形式储存和运输甲烷和二氧化碳。