The Joule–Thomson effect of (CO_(2)+H_(2)) binary system relevant to gas switching reforming with carbon capture and storage(CCS)

The Joule-Thomson effect is one of the important thermodynamic properties in the system relevant to gas switching reforming with carbon capture and storage(CCS). In this work, a set of apparatus was set up to determine the Joule-Thomson effect of binary mixtures(CO_(2)+ H_(2)). The accuracy of the apparatus was verified by comparing with the experimental data of carbon dioxide. The Joule-Thomson coefficients(μ_(JT)) for(CO_(2)+ H_(2)) binary mixtures with mole fractions of carbon dioxide(x_(CO_(2))= 0.1, 0.26, 0.5,0.86, 0.94) along six isotherms at various pressures were measured. Five equations of state EOSs(PR,SRK, PR, BWR and GERG-2008 equation) were used to calculate the μ_(JT)for both pure systems and binary systems, among which the GERG-2008 predicted best with a wide range of pressure and temperature.Moreover, the Joule-Thomson inversion curves(JTIC) were calculated with five equations of state. A comparison was made between experimental data and predicted data for the inversion curve of CO_(2). The investigated EOSs show a similar prediction of the low-temperature branch of the JTIC for both pure and binary systems, except for the BWRS equation of state. Among all the equations, SRK has the most similar result to GERG-2008 for predicting JTIC.

西南油气田CCUS/CCS发展现状、优势与挑战

中国石油西南油气田公司(以下简称西南油气田)是中国西南地区首个天然气年产量超400×10^(8) m^(3)的油气生产企业,其天然气新建产能、产量的增量分别占到全国增量的1/4和1/3,预计2030年天然气开发的碳排放量将突破500×10^(4) t。为解决天然气高质量上产过程中碳排放量刚性增长的问题,西南油气田主动围绕“天然气+CCUS”的战略规划,积极部署CCUS/CCS工作,以期打造“绿色能源西南模式”,助力实现“双碳”目标。为此,系统阐述了西南油气田在CCUS/CCS业务规划、标准体系、技术系列等方面的发展现状,梳理了其CCUS/CCS业务在资源、技术方面的优势,并分析了面临的技术成熟度不高、经济效益缺乏、社会接受度不高等挑战,最后作出了展望并有针对性地提出了下一步建议:①攻关形成具有气田特色的CCUS/CCS技术体系,打造气田CCUS/CCS原创技术策源地;②建立气田CCUS/CCS标准体系,推广应用气田CO_(2)驱气提高采收率(CCUS-EGR)和CO_(2)埋存技术;③依托西南油气田自有碳捕集、输送、驱气、封存等技术,进一步延伸拓展传统油气主营业务产业链,建立西南片区CCUS/CCS产业集群和碳库,助力中国石油成为CCUS/CCS产业链链长;④探索页岩气注CO_(2)及混合气体提高采收率技术,支撑在页岩气领域开辟新的CCUS方向。

海上CCS工程项目全流程技术进展与展望

分析了海上典型场景CCS全流程的技术进展,提出面临的挑战和对未来发展趋势的展望。海上CCS项目主要有两个典型场景,包括海上平台CO_(2)捕集直接回注和陆地排放源CO_(2)捕集后运输到海上进行离岸封存。海上平台CO_(2)捕集工艺以膜分离为主,同时配合多种工艺组合;陆地排放源主要有天然气处理终端和炼化企业,根据气源浓度选择捕集工艺,以化学吸收法为主,重点研究低成本的工艺。海上CO_(2)运输主要有船舶运输和管道运输,目前管道运输处在中试阶段,大型CO_(2)运输船正在设计建造中。海上封存场地主要包括咸水层和枯竭油气藏,咸水层封存重点研究盖层封闭性、长期稳定性以及海上监测技术。综合考虑技术和成本因素,海上CCS项目未来向集群项目发展,联合排放企业和封存企业共同开展CO_(2)利用及封存,技术上需要重点攻关海上平台CO_(2)高效低成本捕集工艺、海上CO_(2)运输大型装备以及海上封存监测过程中的难题。

Criteria for Selecting Carbon Subsurface and Ocean Storage Site in Developing Countries: A Review

Important first phases in the process of implementing CO2 subsurface and ocean storage projects include selecting of best possible location(s) for CO2 storage, and site selection evaluation. Sites must fulfill a number of criteria that boil down to the following basics: they must be able to accept the desired volume of CO2 at the rate at which it is supplied from the CO2 source(s);they must as well be safe and reliable;and must comply with regulatory and other societal requirements. They also must have at least public acceptance and be based on sound financial analysis. Site geology;hydrogeological, pressure, and geothermal regimes;land features;location, climate, access, etc. can all be refined from these basic criteria. In addition to aiding in site selection, site characterization is essential for other purposes, such as foreseeing the fate and impacts of the injected CO2, and informing subsequent phases of site development, including design, permitting, operation, monitoring, and eventual abandonment. According to data from the IEA, in 2022, emissions from Africa and Asias emerging markets and developing economies, excluding Chinas, increased by 4.2%, which is equivalent to 206 million tonnes of CO2 and were higher than those from developed economies. Coal-fired power generation was responsible for more than half of the rise in emissions that were recorded in the region. The difficulty of achieving sustainable socio-economic progress in the developing countries is entwined with the work of reducing CO2 emissions, which is a demanding project for the economy. Organisations from developing countries, such as Bangladesh, Cameroon, India, and Nigeria, have formed partnerships with organisations in other countries for lessons learned and investment within the climate change arena. The basaltic rocks, coal seams, depleted oil and gas reservoirs, soils, deep saline aquifers, and sedimentary basins that developing countries (Bangladesh, Cameroon, India, and Nigeria etc.) possess all contribute to the individual countrys significant geological sequestration potential. There are limited or no carbon capture and storage or clean development mechanism projects running in these countries at this time. The site selection and characterization procedure are not complete without an estimate of the storage capacity of a storage location. Estimating storage capacity relies on volumetric estimates because a site must accept the planned volume of CO2 during the active injection period. As more and more applications make use of site characterization, so too does the body of written material on the topic. As the science of CO2 storage develops, regulatory requirements are implemented, field experience grows, and the economics of CO2 capture and storage improve, so too will site selection and characterisation change.

The European Carbon dioxide Capture and Storage Laboratory Infrastructure(ECCSEL)

The transition to a non-emitting energy mix for power generation will take decades. This transition will need to be sustainable, e.g.economically affordable. Fossil fuels which are abundant have an important role to play in this respect, provided that Carbon Capture and Storage(CCS) is progressively implemented. CCS is the only way to reduce emissions from energy intensive industries.Thus, the need for upgraded and new CCS research facilities is widely recognised among stakeholders across Europe, as emphasised by the Zero Emissions Platform(ZEP) [1] and the European Energy Research Alliance on CCS(EERA-CCS) [2].The European Carbon Dioxide Capture and Storage Laboratory Infrastructure, ECCSEL, provides funders, operators and researchers with significant benefits by offering access to world-class research facilities that, in many cases, are unlikely for a single nation to support in isolation.This implies creation of synergy and the avoidance of duplication as well as streamlining of funding for research facilities.ECCSEL offers open access to its advanced laboratories for talented scientists and visiting researchers to conduct cutting-edge research.In the planning of ECCSEL, gap analyses were performed and CCS technologies have been reviewed to underpin and envisage the future experimental setup; 1) Making use of readily available facilities, 2) Modifying existing facilities, and 3) Planning and building entirely new advanced facilities.The investments required for the first ten years(2015-2025) are expected to be in the range of €80-120 miilion. These investments show the current level of ambition, as proposed during the preparatory phase(2011-2014).Entering the implementation phase in 2015, 9 European countries signed Letter of Intent(LoI) to join a ECCSEL legal entity: France, United Kingdom, Netherlands, Italy, Spain, Poland, Greece, Norway and Switzerland(active observer). As the EU ERIC-regulation [3] would offer the most suitable legal framework for ECCSEL, the host country, Norway, will apply for establishing ERIC as the ECCSEL Research Infrastructure(RI)legal entity in 2017. Until the ECCSEL ERIC is approved by the European Commission(probably by summer 2017), an interim MoU agreement for the implementation phase of ECCSEL RI has been signed by 13 research institutions and universities representing the 9 countries. A consortium of these partners were granted 3 million EURO from Horizon 2020 to boost implementation of ECCSEL from September 2015 and two years onwards.?2016, Institute of Process Engineering, Chinese Academy of Sciences. Publishing services by Elsevier B.V. on behalf of KeAi Communications Co., Ltd. This is an open access article under the CC BY-NC-ND license(http://creativecommons.org/licenses/by-nc-nd/4.0/).

欧洲能源复兴计划CCS示范项目实施进展与启示

碳捕集与封存(Carbon Capture and Storage,CCS)作为最有前景可有效深度减排的低碳技术之一,在世界范围内受到广泛推行,特别是欧洲,其作为全球CCS技术的先行者,一直在积极推进该项技术工业化进程。2009年,欧盟委员会(European Commission,EC)启动欧洲能源复兴计划(European Energy Programme for Recovery,EEPR),正式批准资助6个全流程CCS示范项目。这6个CCS示范项目囊括了当前所有可行的CO2工业捕集技术,运输方式以及封存方法,本文将对其基本情况和最近进展进行介绍,并重点对欧盟层面的CCS法律法规与此6个项目所在欧盟成员国的CCS技术与政策环境的交互影响进行比对和分析,以进一步系统评述欧洲能源复兴计划CCS示范项目带来的积极成果,包括达成减排目标和气候政策,建立欧洲CCS示范项目网络共享平台,获得CCS技术研发突破等,同时也详细列举了这些项目目前所面临的阻碍与困境,如相关法律政策缺乏执行力,融资困难,公众接受度低,技术成本高等。最后,试探讨欧盟能源复兴计划CCS全流程示范项目实施发展现状对我国未来CCS商业化走向的思索与启示。

地层倾角对CO_2地质封存的影响研究—以鄂尔多斯CCS工程为例

CO2地质储存是减少CO2向大气排放的有效手段。CO2在储层中的运移受地层的物理属性和空间展布形态的影响,本文以鄂尔多斯CO2地质封存示范场地石千峰组为研究对象,研究了地层产状倾斜对CO2地质储存的影响。结果表明,在定压注入时,地层倾角对CO2的空间分布、CO2的注入速率、CO2的空间运移距离、以及CO2的封存量等均呈现出规律性的影响;地层倾角越大,注入速率越小、横向运移距离越远,而其封存量小;地层倾角的增大不利于CO2地质封存。

基于CCS的MEA脱碳技术全球专利发展态势

以单乙醇胺(MEA)吸收法为主的脱碳技术被认为是较具可行性的CO2捕集技术。本文主要针对MEA脱碳技术开展专利分析,建立MEA技术专利分析方法,研究认为基于二氧化碳捕集、运输和封存(CCS)应用的MEA脱碳技术在近十年得到大幅增长,其中增长较快的国家有美国、中国、日本、澳大利亚等,中国和韩国在近3年尤其增长较快;各国MEA脱碳技术专利的侧重点和优势各不同,美国、日本、俄罗斯等国专利较为倾向烟气脱碳、装置、材料等实际应用,中国则倾向于MEA基础方法研究,该研究结果有望为我国MEA脱碳技术研发创新、专利申请与保护提供参考借鉴。

英国发展CCS战略及加强与中国合作的原因简析

详细介绍了英国CCS发展战略和具体实施举措,并从多个角度分析和探讨英国发展CCS及其积极推进与中国合作的原因。自20世纪90年代初以来,英国一直在积极推进CCS的发展,特别是随着《能源白皮书》、《能源法》等战略性文件的颁布,进一步奠定了发展CCS的政策基础,相继实施了竞标计划、示范项目等一系列措施。在实施过程中,除考虑自身能源结构和能源安全外,英国更多把发展CCS瞄准于未来全球煤电市场以及气候外交的战略上,中国元素成为其关注的重要因素之一。中国巨大的煤电市场以及在气候变化政治格局中的地位,成为英国促进与中国合作的重要原因。

实施CCS技术的火力发电厂场址选择

将碳捕集与封存(CCS)技术应用于碳排放密集的燃煤电站,是中国实现中长期减排目标的主要途径。在大规模应用CCS技术前,必须完成对实施CCS技术的大型火力发电厂场址选择。文章探讨了火力发电厂的选址标准及综合评价方法,并分析了在实施CCS下火力发电厂选址需要考虑的问题。通过对河北11个地市级行政区进行定性分析,发现张家口、邢台、邯郸可以优先考虑新建实施CO2捕集的大型火力发电厂,起到示范作用。

国外CCS政策法规体系的形成及对我国的启示

碳捕集和封存(Carbon Capture and Storage,CCS)是一种新的二氧化碳减排技术,是中国未来实现温室气体深度减排的重要战略选择。但作为一项新兴的减排技术,中国的CCS政策法规体系建设尚处于起步阶段。本文系统整理分析了欧盟、英国、美国、澳大利亚等国家和地区CCS领域的法规、政策和标准,在总结发达国家CCS立法以及政策、标准建立方面成功经验的基础上,针对CCS不同环节提出了对我国相应的政策法规建议,以期为我国CCS相关政策、法规的建立提供参考。

CO_2混合物热物性在CCS研究中的作用:实验数据、理论模型和典型应用

二氧化碳捕集与封存(CCS)各工艺过程的设计、运行都依赖于对CO_2及其混合物热物理性质的深入理解。同时,CCS的规模化发展和商业化进程,对CO_2混合物及其热物性的准确性提出了更高的要求。本文从实验数据、理论模型和典型应用3个方面综述了CO_2及其混合物热物性的发展现状,并尝试对发展趋势进行归纳。在实验研究方面,CO_2混合体系的研究进展视组分不同,差异较大,其中CO_2-N_2、CO_2-CH4、CO_2-H_2O和CO_2-H_2二元体系已形成较完善的物性数据库,而CO_2-NH_3、CO_2-NOx和CO_2-CO体系的物性数据还比较欠缺;在物性估算方面,面向CCS的物性估算模型研究自2008年开始活跃,基于不同理论构架,目前已逐步形成面向CCS的多元化的物性估算体系。物性研究在CCS中的应用主要体现在物性是支撑CCS过程研究的基础,其不准确性在过程模拟或计算中会被"放大",从而影响过程评估的准确性,本文从物性在循环构建和能效分析中的作用以及CO_2水合物的形成3个方面入手做了说明。文章最后对面向CCS的物性研究趋势进行了梳理,对分子模拟技术、通用性强的物性估算模型和物性在过程设计和循环分析中的角色进行了展望。

CCS监测技术发展现状分析

在实施CCS项目过程中,可靠精准的监测技术是不可或缺的,完备的监测方案将为CO2永久和安全性封存提供重要保障。本文介绍了CO2地质封存(CCS)的相关监测技术,并就国内外监测技术的发展现状进行了分析。以大气监测、地表监测、地层监测为重点,列出了已有监测方法并进行了分析。结合已有的示范或研究项目,对国内外典型的监测技术应用案例进行了分析,提出了我国CCS监测技术可能的发展方向。

国内外大型碳捕集与封存(CCS)项目建设综述

对2012年国内外大型碳捕集与封存(CO2Capture and Storage,CCS)项目的建设与立法方面的最新进展进行了分析,概述了已投入运行的、正在建设与规划中的大型CCS项目,介绍了我国CCS项目进展概况,并阐述了CCS发展存在的问题与障碍。

当前全球碳捕集与封存(CCS)技术进展及面临的主要问题

本文分析了当前全球碳捕集与封存(CCS)的最新技术进展及面临的主要问题,指出碳捕集与封存虽然被广泛认为是未来主要的碳减排技术,且当前全球的CCS示范和规划项目在不断增加,但是CCS项目仍面临诸如成本昂贵、使总能效下降、缺乏法律基础、公众难以接受等一系列问题。

我国CCS技术发展现状及问题分析

随着全球气候变化,减少温室气体排放在当今世界已经达成共识。CCS技术作为一种应对全球变暖的有效技术途径,其发展潜力巨大,但是也存在很多待解决问题。对CCS技术及CCS技术在我国的发展现状进行了介绍,对CCS技术在我国发展中存在的一系列问题进行了探讨。

基于能源与气候发展2050路径计算器的英国更多CCS和更多生物能源路径分析

介绍了英国能源与气候变化部公布的2050路径计算器及其4个路径,主要分析了第3个路径——更多碳捕获与收集(CCS)和更多生物能源,其中包括:提高将运输排放量转变为零的水平、降低家庭温度、更多地使用风能及增建生物发电站。最后指出了加速科技发展是实现低碳最好的方法,提出了生物发电厂技术和生物染料的共燃技术等是未来的研究方向。

Carbon capture and storage,geomechanics and induced seismic activity

Injection of large volumes of carbon dioxide(CO) for the purposes of greenhouse-gas emissions reduction has the potential to induce earthquakes.Operators of proposed projects must therefore take steps to reduce the risks posed by this induced seismicity.In this paper,we examine the causes of injection-induced seismicity(IIS),and how it should be monitored and modelled,and thereby mitigated.Many US case studies are found where fluids are injected into layers that are in close proximity to crystalline basement rocks.We investigate this issue further by comparing injection and seismicity in two areas where oilfield wastewater is injected in significant volumes:Oklahoma,where fluids are injected into a basal layer,and Saskatchewan,where fluids are injected into a much shallower layer.We suggest that the different induced seismicity responses in these two areas are at least in part due to these different injection depths.We go on to outline two different approaches for modelling IIS:a statistics based approach and a physical,numerical modelling based approach.Both modelling types have advantages and disadvantages,but share a need to be calibrated with good quality seismic monitoring data if they are to be used with any degree of reliability.We therefore encourage the use of seismic monitoring networks at all future carbon capture and storage(CCS) sites.

CCS技术:引领人类进入“低碳新时代”

对于大多数人来说，CCS技术（Carbon Captureand Storage，即二氧化碳捕集与封存）现在还是一个十分陌生的名词。但是，在未来的“低碳时代”。CCS技术将会广为人知。

Mapping Highly Cost-Effective Carbon Capture and Storage Opportunities in India

Carbon dioxide (CO2) is the primary anthropogenic greenhouse gas (GHG). India’s CO2 emissions are expected to increase 70% by 2025. Geologic carbon storage (GCS) offers a way to reduce CO2 emissions. Here we present the results of a search for the most cost-effective GCS opportunities in India. Source-Sink matching for large and concentrated CO2 sources near geological storage in India indicates one very high priority target, a fertilizer plant in the city of Narmadanagar in Bharuch District of Gujarat Province, India that is <20 km from old oil and gas fields in the Cambay Basin. Two pure CO2 sources are <20 km from deep saline aquifers and one