Investigation of Near-Field Temperature Distribution in Buried Dense Phase CO2 Pipelines

Babafemi Olugunwa, J. Race, A. Yurtseven, T. Tezdogan
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Abstract

Buried pipelines transporting dense phase Carbon dioxide CO2 are crucial to carbon reduction and climate change mitigating technologies such as Carbon Capture and Storage (CCS) and Carbon Capture Utilization and Storage (CCUS). One of the major challenges for optimum pipeline operating conditions is to avoid phase change of the compressed CO2 and maintain temperature and pressure above the critical point throughout the pipeline route. A suitable pipe-soil heat transfer model during design can mitigate this challenge. However, variations in annual ambient temperatures, ground temperature at pipeline burial depth and soil temperature profile behaviors with seasonal climatic conditions especially during winter and summer periods also affect the heat transfer process between the soil burial medium and the CO2 pipeline. Assuming steady state, this paper investigates the nearfield temperature distribution up to 3m lateral distance away from a buried dense phase CO2 pipeline by numerical simulation with a two-dimensional pipe-soil heat transfer model at a burial depth of 2.3m to pipe center using a finite volume computational code. Results show that thermal parameters such as thermal conductivity and the soil temperature profile influence the heat exchange between pipe walls and porous soil medium. Consequently, this study shows that the near-field temperature distribution and effect of heat around a buried CO2 pipeline diminishes with distance and burial depth further away within the immediate vicinity of the pipeline.
埋地致密相CO2管道近场温度分布研究
输送致密相二氧化碳的埋地管道对于碳捕集与封存(CCS)和碳捕集利用与封存(CCUS)等碳减排和减缓气候变化技术至关重要。优化管道运行条件的主要挑战之一是避免压缩CO2的相变,并在整个管道路线中保持温度和压力高于临界点。在设计中采用合适的管道-土壤传热模型可以缓解这一挑战。然而,年环境温度、管道埋深处地温以及土壤温度剖面随季节气候条件的变化,尤其是冬夏两季,也会影响土壤埋埋介质与CO2管道之间的换热过程。在稳态条件下,采用有限体积计算程序,建立埋深为2.3m的管道-土壤二维传热模型,对埋深为2.3m的致密相CO2管道近场温度分布进行了数值模拟。结果表明,导热系数和土壤温度分布等热参数对多孔土壤介质与管壁之间的热交换有影响。因此,本研究表明,埋地CO2管道附近的近场温度分布和热量效应随着距离和埋深的增加而减小。
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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