Competitiveness of Small-Medium, New Generation Reactors: A Comparative Study on Capital and O&amp;M Costs

Carelli, Mario D.; Mycoff, Clark W.; Garrone, Paola; Locatelli, Giorgio; Mancini, Mauro; Ricotti, Marco Enrico; Trianni, Andrea; Trucco, Paolo

doi:10.1115/icone16-48931

Cited by 16 publications

(15 citation statements)

References 5 publications

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“…The average share of debt for large reactor projects is 65%. This value for SMRs is approximately 50% (Carelli 2008;INL 2012). The maximum share of debt for large reactors and SMRs are approximately 93% and 69% respectively (Carelli 2008).…”

Section: Weighted Average Cost Of Capitalmentioning

confidence: 94%

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Small modular reactor: First-of-a-Kind (FOAK) and Nth-of-a-Kind (NOAK) Economic Analysis

Boldon¹,

Sabharwall²

2014

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Small modular reactors (SMRs) refer to any reactor design in which the electricity generated is less than 300 MWe. Often medium-sized reactors with power less than 700 MWe are also grouped into this category. Internationally, the development of a variety of designs for SMRs is booming with many designs approaching maturity and even in or nearing the licensing stage. It is for this reason that a generalized yet comprehensive economic model for first-of-a-kind (FOAK) through nth-of-a-kind (NOAK) SMRs based upon rated power, plant configuration, and the fiscal environment was developed. In the model, a particular project's feasibility is assessed with regards to market conditions and by commonly utilized capital budgeting techniques, such as the net present value (NPV), internal rate of return (IRR), Payback, and more importantly, the levelized cost of energy (LCOE) for comparison to other energy production technologies. Finally, a sensitivity analysis was performed to determine the effects of changing debt, equity, interest rate, and conditions on the LCOE. The economic model is primarily applied to the near future water-cooled SMR designs in the United States. Other gas-cooled and liquid metal-cooled SMR designs have been briefly outlined in terms of how the economic model would change.

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Section: Weighted Average Cost Of Capitalmentioning

confidence: 94%

“…This value for SMRs is approximately 50% (Carelli 2008;INL 2012). The maximum share of debt for large reactors and SMRs are approximately 93% and 69% respectively (Carelli 2008). In this economic model, the cases are performed at the average SMR debt share.…”

Section: Weighted Average Cost Of Capitalmentioning

confidence: 94%

Small modular reactor: First-of-a-Kind (FOAK) and Nth-of-a-Kind (NOAK) Economic Analysis

Boldon¹,

Sabharwall²

2014

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“…Obviously if "economies of scale" is the unique driver for the cost estimation SMR are not competitive respect to LR. However many recent references [6][7][8] point out as this is true as long as the comparison considers the specific cost [$/kWe] of 1 LR respect 1 SMR. On the other hand, when the comparison is carried out considering the same power installed in the site (1340 MWe equivalent to 1 LR or 4 SMR) the result changes.…”

Section: Polimi Open Model and Research Questionsmentioning

confidence: 99%

Impact of the External Factors in the Nuclear Field: A Comparison Between Small Medium Reactors vs. Large Reactors

Mancini

Locatelli

Tammaro

2009

Volume 3: Thermal Hydraulics; Current Advanced Reactors: Plant Design, Construction, Workforce and Public Acceptance

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Several improvements have been made in the nuclear energy sector during the last decade leading to new design for advanced nuclear power plants. Literature presents several studies about the economics of these new Power Plants, however the economic analysis of these plants usually considers only the classical accounts related to Construction, Operation & Maintenance, Fuel and Decommissioning. Beside these accounts there are many factors, from now on named External Factors (e.g. social acceptability, enhanced safety, emergency planning zone reduction, etc.) able to heavily determine the profitability of the investment. This paper presents the differential impact of these External Factors on nuclear technology with different sizes. According to the classification currently in use in the IAEA, small reactors are those with electric generation power lower than 300 MW, while medium sized reactors are those with electric power between 300 and 700 MW [1]. We define “Small Medium Reactors” (SMR) reactors with an electrical output smaller than 700 MW (usually 335 MWe) and as “Large reactors”, (LR) reactors with an equivalent electric power greater than 700 MW. (usually 1340 MWe) Starting from the international literature point of view, the paper provides a list of external factors distinguished in economically quantifiable or not. Two different approaches have been used for their assessment: a monetary ranking and a strategic one. Then, using a Quality Function Deployment approach, a multi-attribute model is introduced to obtain a weight for every external factor, dividing their impacts into three sustainability dimensions (economic, environmental and social). The results show that the new SMR perform better than LR thanks to the smaller size which allows an enhancement of the safety level (which affects the public opinion) and a greater flexibility in the market.

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“…Carelli et al (2007Carelli et al ( , 2010 analyse specific factors, such as grid characteristics, construction time, financial exposition, modularisation and learning, which distinguish SMRs from LRs in the evaluation of capital cost. Once these factors are considered, the capital cost is comparable between the two technologies (Boarin et al, 2012;Carelli et al, 2008). Locatelli and Mancini (2011b) discuss the effects of 'non-financial parameters', such as electric grid vulnerability, public acceptance, risk associated with the project and others, on the evaluation of the best reactor size for an investment in the nuclear sector.…”

Section: The Case For Small Modular Reactorsmentioning

confidence: 99%

“…Several papers have discussed the competiveness of SMRs against large reactors (LRs) and how SMRs might balance the 'diseconomy of scale' with the 'economy of multiples' (Boarin et al, 2012Carelli et al, 2008;Locatelli and Mancini, 2012a;. Carelli et al (2007Carelli et al ( , 2010 analyse specific factors, such as grid characteristics, construction time, financial exposition, modularisation and learning, which distinguish SMRs from LRs in the evaluation of capital cost.…”

Section: The Case For Small Modular Reactorsmentioning

confidence: 99%

Appraisal of small modular nuclear reactors with ‘real options’ valuation

Locatelli

Pecoraro

Meroni³

et al. 2017

Proceedings of the Institution of Civil Engineers - Energy

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2 3 4Small modular nuclear reactors have the advantage of flexibility in deployment and shorter construction time compared with large reactors. Investment appraisals in the energy sector are traditionally based on discounted cash flow, but this tends to underestimate the value of management flexibility during the decision-making process. The 'real options' valuation method can better support an investment appraisal. This paper, leveraging the real options approach, gives an account of two key strategic aspects to support the decision-making process in building small modular reactors: the time to market with the relative stage-gate process and the effect of a new plant on the existing portfolio. This paper assesses small modular reactors against other base-load power plants and, once applied to the UK scenario, it shows the superior performance of small modular reactors.differential coefficient' of a linear exercise threshold dp differential price dz differential Wiener process e Euler's number E expected ECTC t expected cost to complete the construction at time t ECTC threshold expected cost to complete the construction threshold ECTD t expected cost to complete the design at time t ECTD threshold expected cost to complete the design threshold G* gas price triggering the investment G 0 gas price at the time now G t gas price at time t I is the investment rate K remaining cost,'multiplication factor' of a linear exercise threshold P* price triggering the investment P 0 price at the time now P LB lower bound price P lim price limit P SR sharpe ratio price

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Competitiveness of Small-Medium, New Generation Reactors: A Comparative Study on Capital and O&M Costs

Cited by 16 publications

References 5 publications

Small modular reactor: First-of-a-Kind (FOAK) and Nth-of-a-Kind (NOAK) Economic Analysis

Small modular reactor: First-of-a-Kind (FOAK) and Nth-of-a-Kind (NOAK) Economic Analysis

Impact of the External Factors in the Nuclear Field: A Comparison Between Small Medium Reactors vs. Large Reactors

Appraisal of small modular nuclear reactors with ‘real options’ valuation

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