Reusing Existing Infrastructure for CO2 Transport: Risks and Opportunities

Day 4 Fri, March 25, 2022 Pub Date : 2022-03-18 DOI:10.4043/31457-ms

E. Luna-Ortiz

{"title":"Reusing Existing Infrastructure for CO2 Transport: Risks and Opportunities","authors":"E. Luna-Ortiz","doi":"10.4043/31457-ms","DOIUrl":null,"url":null,"abstract":"\n There is no doubt that greenhouse gas emissions, particularly CO2, needs to be reduced to mitigate the effects of climate change. While carbon management can be achieved through a number of technological and engineering approaches ranging from energy efficiency (i.e., highly energy integrated system and process intensification) to renewable energy (wind, solar, hydrogen), CO2 capture & storage (CCS) has been identified as having a key role in the energy transition.\n Captured anthropogenic CO2 can be permanently stored in saline aquifers and depleted reservoirs. Saline aquifers (normally unsuitable for industrial or human exploitation) offer the largest storage capacity; however, there is, usually, lack of geological characterization leading to high risks due to large uncertainty. On the other hand, depleted gas fields, close to economical life cessation, are deemed an excellent alternative as safe and long-term storage is already proven and immense geological characterisation has been gathered during production life. Moreover, there is great potential to repurpose the existing offshore infrastructure (pipelines, platforms, and wells) as to minimize capital expenditure and delaying decommissioning costs. Repurposing existing production systems can also be an efficient way to achieve rapid deployment of CCS at large scale.\n In this paper, we present the key engineering challenges, risks, and opportunities in the re-use of existing oil and gas offshore infrastructure for CO2 transport and injection. We highlight the complex operational constraints and interactions between different components of the transportation network. The design and operation of the transportation network is governed by the following drivers:\n Safe design Robust and flexible operation Minimize cost (or delay expenditure as long as possible) Minimize emissions of greenhouse gases associated to the operation of the transport network (i.e., energy efficiency) Start operation with minimum modifications","PeriodicalId":11217,"journal":{"name":"Day 4 Fri, March 25, 2022","volume":"155 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2022-03-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Day 4 Fri, March 25, 2022","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.4043/31457-ms","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 1

Abstract

There is no doubt that greenhouse gas emissions, particularly CO2, needs to be reduced to mitigate the effects of climate change. While carbon management can be achieved through a number of technological and engineering approaches ranging from energy efficiency (i.e., highly energy integrated system and process intensification) to renewable energy (wind, solar, hydrogen), CO2 capture & storage (CCS) has been identified as having a key role in the energy transition. Captured anthropogenic CO2 can be permanently stored in saline aquifers and depleted reservoirs. Saline aquifers (normally unsuitable for industrial or human exploitation) offer the largest storage capacity; however, there is, usually, lack of geological characterization leading to high risks due to large uncertainty. On the other hand, depleted gas fields, close to economical life cessation, are deemed an excellent alternative as safe and long-term storage is already proven and immense geological characterisation has been gathered during production life. Moreover, there is great potential to repurpose the existing offshore infrastructure (pipelines, platforms, and wells) as to minimize capital expenditure and delaying decommissioning costs. Repurposing existing production systems can also be an efficient way to achieve rapid deployment of CCS at large scale. In this paper, we present the key engineering challenges, risks, and opportunities in the re-use of existing oil and gas offshore infrastructure for CO2 transport and injection. We highlight the complex operational constraints and interactions between different components of the transportation network. The design and operation of the transportation network is governed by the following drivers: Safe design Robust and flexible operation Minimize cost (or delay expenditure as long as possible) Minimize emissions of greenhouse gases associated to the operation of the transport network (i.e., energy efficiency) Start operation with minimum modifications

查看原文本刊更多论文

再利用现有基础设施进行二氧化碳运输:风险与机遇

毫无疑问，需要减少温室气体的排放，特别是二氧化碳的排放，以减轻气候变化的影响。虽然碳管理可以通过一系列技术和工程方法实现，从能源效率(即高度能源集成系统和过程强化)到可再生能源(风能、太阳能、氢气)，二氧化碳捕获和储存(CCS)已被确定为在能源转型中发挥关键作用。人为捕获的二氧化碳可以永久储存在含盐含水层和枯竭的水库中。含盐含水层(通常不适合工业或人类开采)提供最大的储存能力;然而，由于地质特征缺乏，不确定性大，风险高。另一方面，接近经济寿命终止的枯竭气田被认为是一个很好的选择，因为已经证明了安全的长期储存，并且在生产寿命期间收集了大量的地质特征。此外，重新利用现有海上基础设施(管道、平台和油井)的潜力很大，可以最大限度地减少资本支出，并推迟退役成本。重新利用现有的生产系统也是实现大规模快速部署CCS的有效方法。在本文中，我们介绍了将现有油气海上基础设施用于二氧化碳运输和注入的关键工程挑战、风险和机遇。我们强调了复杂的操作约束和交通网络不同组成部分之间的相互作用。交通网络的设计和运行由以下驱动因素控制:安全设计稳健灵活的运行使成本最小化(或尽可能地延迟支出)使与交通网络运行相关的温室气体排放最小化(即能源效率)以最小的修改开始运行

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Day 4 Fri, March 25, 2022

自引率

0.00%

发文量