Techno-economic assessment of CO 2 quality effect on its storage and transport: CO 2 QUEST

Porter, R.; Mahgerefteh, H; Brown, Solomon; Martynov, Sergey; Collard, Alexander; Woolley, Robert; Fairweather, Michael; Falle, S. A. E. G.; Wareing, C. J.; Nikolaidis, Ilias K.; Boulougouris, Georgios C.; Peristeras, Loukas D.; Tsangaris, Dimitrios M.; Economou, Ioannis G.; Salvador, Carlos Henrique; Zanganeh, Kourosh E.; Wigston, Andrew; Najafali, John N.; Shafeen, Ahmed; Beigzadeh, Ashkan; Farret, Régis; Gombert, Philippe; Hebrard, Jérôme; Proust, Christophe; Ceroni, A; Flauw, Yann; Zhang, Yong Chun; Chen, Shaoyun; Yu, Jianliang; Talemi, Reza; Bensabat, Jacob; Wolf, Jan Lennard; Rebscher, Dorothee; Niemi, Auli; Jung, Byung Mun; Dowell, Niall Mac; Shah, Nilay; Kolster, Clea; Mechleri, Evgenia; Krevor, Samuel

doi:10.1016/j.ijggc.2016.08.011

Cited by 29 publications

(13 citation statements)

References 41 publications

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“… Even though high purity CO2 (>95%) is normally targeted after CO2 capture, different types and levels of impurities may be present in the CO2 to be transported and stored. Although these impurities may only be present in small amounts, several studies have shown that the potential associated impurities can have a significant impact on design and cost of CO2 conditioning, transport, and storage [116,117,134,135]. However, this impact will however depend on the types and levels of impurities present in the CO2 stream and thus the combination of industrial plant, CO2 capture technology considered and targeted CO2 specifications for storage or use [136].…”

Section: Flue-gas Treatment Requirementsmentioning

confidence: 99%

Towards improved guidelines for cost evaluation of carbon capture and storage

Roussanaly

Rubin

Spek

et al. 2021

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Understanding the costs of carbon capture and storage (CCS) is essential to understand the role for and potential of CCS technology in addressing climate change, for guidance in research activities aiming to reduce the cost and improve the performance of promising new CCS technologies in different applications. In practice, however, there are many challenges in establishing reliable cost estimates for CCS technologies. To help identify and overcome these challenges, a group of experts from industry, government, academia and other organisations came together in 2011 to form the CCS Cost Network (which came under the aegis of IEAGHG in 2017 [1]). Following discussions at the first CCS Cost Network workshop [1], several members of the workshop steering committee formed a task force to focus on the basic structure of CCS cost estimates. That effort produced a White Paper entitled, "Toward a Common Method of Cost Estimation for CCS at Fossil Fuel Power Plants" [2]. This white paper aimed at overcoming identified pitfalls in CCS cost evaluations for fossil fuel power plants arising from the different methodologies used by various organisations. Towards this aim, the white paper established a common costing methodology and nomenclature, as well as guidelines for CCS cost reporting to improve the clarity and consistency of cost estimates for greenhouse gas mitigation measures. While that work laid the foundation for establishing a common costing methodology for CCS, several important cost issues still remained to be addressed. Building on that earlier work and the interest from additional organisations, the current white paper is an effort to draw up a complementary set of CCS costing guidelines in three complementary areas where further guidelines and better practices are needed, and where efforts are underway to address those topics. This effort is a collaboration among researchers at several industrial research institutes (Electric

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Section: Flue-gas Treatment Requirementsmentioning

confidence: 99%

Towards improved guidelines for cost evaluation of carbon capture and storage

Roussanaly

Rubin

Spek

et al. 2021

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“…Further, to be a low-cost and easily deployed tracer, CH 4 must be present in the captured CO 2 stream, thereby avoiding the cost and potential environmental risks associated with adding a tracer. CH 4 is a common constituent of pre-combustion CO 2 capture from coal or biomass; CO 2 streams from these sources typically contain ~100 ppmv CO 2 Porter et al, 2016(Porter et al, 2016. However, depending on the specifics of the capture process itself, the CH 4 may be present in <1 ppmv concentrations (Porter et al, 2015).…”

Section: Accepted Manuscriptmentioning

confidence: 99%

An experimental investigation into quantifying CO2 leakage in aqueous environments using chemical tracers

et al. 2019

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Chemical tracers can be an effective means of detecting, attributing and quantifying any leaks to the surface from geological CO 2 stores. CO 2 release experiments have found it difficult to ascertain the fate, or quantify the volume of CO 2 without the application of tracers. However, a significant proportion of global CO 2 storage capacity is located offshore, and the marine environment poses constraints that could limit the success of using tracers. These constraints include uncertainties in the behaviour of tracers in marine sediments and the water column and sampling challenges. However, to date there have been few experimental investigations to address these uncertainties. Here, we used a benchtop experimental setup to explore how effectively methane, a common constituent of captured CO 2 and of reservoir fluids, can aid the quantitation of CO 2 leakage in aqueous environments. The experiment simulated gas leakage into sediments that mimic the seabed, and we measured the partitioning of co-released gases under different environmental conditions and injection rates. We find that the style of seepage and the fate of the CO 2 are affected by the presence of a sand layer and the injection rate. We discuss the implications for leak monitoring approaches, including how tracers may be used to quantify the leak rates and fate of CO 2 in aqueous environments. Our work contributes to ongoing efforts to develop robust offshore monitoring system that will assure operators, regulatory bodies and the public of CO 2 storage integrity.

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“…Pipeline-based transport has traditionally been regarded as the preferred means of transport due to its low cost of transport for large capacities and low-to-medium-distances. As a result, many research efforts have focused on a wide range of aspects of pipelinerelated infrastructures: Fundamentals [13], safety [14,15], design and cost [16][17][18][19], the impact of impurities [20,21], and network deployment [11,22,23]. However, the past decade has seen a growing interest in tank-based transport of CO 2 and in the use of ships in particular.…”

Section: Introductionmentioning

confidence: 99%

“…Seo et al [39] have shown that transport pressures above 20 barg are not cost-competitive, but their study lead to estimates similar to the pressure range of key interest (7-15 barg) to be conclusive. Furthermore, the effect of potential impurities in the CO 2 stream after capture on design and costs of CO 2 shipping has received very little consideration, although several studies [21,39] have shown significant impact in the case of pipeline-based transport. In the present study, we thus focus on an in-depth techno-economic comparison of the two most relevant transport pressures (7 and 15 barg) [25,[40][41][42] taking into account the many parameters that can affect such a comparison, including annual transport volumes, transport distance, the impact of impurities, purity requirements, key uncertainties, etc.…”

Section: Introductionmentioning

confidence: 99%

“…Since the presence of impurities in the CO 2 stream after capture, and possible purity constraints after liquefaction, have been shown to have an impact on CO 2 transport design and costs [20,21,43], five scenarios (5 to 9) seek to understand the impact of these effects on the comparison between shipping pressures. The first three scenarios (5 to 7) investigate the impact of different types and levels of impurities presented in Table 1.…”

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confidence: 99%

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At what Pressure Shall CO2 Be Transported by Ship? An in-Depth Cost Comparison of 7 and 15 Barg Shipping

et al. 2021

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The pipeline has historically been the preferred means to transport CO2 due to its low cost for short distances and opportunities for economies of scale. However, interest in vessel-based transport of CO2 is growing. While most of the literature has assumed that CO2 shipping would take place at low pressure (at 7 barg and −46 °C), the issue of identifying best transport conditions, in terms of pressure, temperature, and gas composition, is becoming more relevant as ship-based carbon capture and storage chains move towards implementation. This study focuses on an in-depth comparison of the two primary and relevant transport pressures, 7 and 15 barg, for annual volumes up to 20 MtCO2/year and transport distances up to 2000 km. We also address the impact of a number of key factors on optimal transport conditions, including (a) transport between harbours versus transport to an offshore site, (b) CO2 pressure prior to conditioning, (c) the presence of impurities and of purity constraints, and (d) maximum feasible ship capacities for the 7 and 15 barg options. Overall, we have found that 7 barg shipping is the most cost-efficient option for the combinations of distance and annual volume where transport by ship is the cost-optimal means of transport. Furthermore, 7 barg shipping can enable significant cost reductions (beyond 30%) compared to 15 barg shipping for a wide range of annual volume capacities.

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Techno-economic assessment of CO 2 quality effect on its storage and transport: CO 2 QUEST

Cited by 29 publications

References 41 publications

Towards improved guidelines for cost evaluation of carbon capture and storage

Towards improved guidelines for cost evaluation of carbon capture and storage

An experimental investigation into quantifying CO2 leakage in aqueous environments using chemical tracers

At what Pressure Shall CO2 Be Transported by Ship? An in-Depth Cost Comparison of 7 and 15 Barg Shipping

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