Economics (Sustainability Assessment)

The value of indicator IN1.1, i.e. costs of energy (C_N and C_A) of competing energy supply options to be deployed, is determined using a discounted cost (LUEC) model, taking into account all relevant cost determinants for both the NES and the competing energy technology.
C_N is, in principle, the LUEC for a complete NES, excluding FOAK cost but including external costs and credits if they are fully included in the price setting mechanism, and using contingency allowances and a discount rate that reflects the economic decision making investment environment. In practice, a technology user would compare the cost of electricity from the NPP, which would include an allowance for the back end costs for waste management and decommissioning for the NPP, with that of the alternative energy source. Costs of other components of the NES, including costs for decommissioning and managing wastes from these components, would be reflected in the cost of fuel.
C_A is the LUEC for the (strongest) competitor A (for power generation investment), excluding FOAK cost but including external costs and credits if they are fully included in the price setting mechanism, and using contingency allowances and the same discount rate as applied for calculating C_N . Further, the competing alternative energy source is to be available for the same application in the same time frame and geographic region/jurisdiction. This is an important limitation since an NPP is usually operated at high load factors, primarily for meeting base load demand. So, usually, the competing alternative will be a fossil fuelled plant, e.g., coal, oil or a combined cycle gas turbine plant or, in some jurisdictions, a hydro plant. Further, the cost comparison should be based on costs for the relevant region/market and the time frame for the deployment of the NES.
Acceptance limit AL1.1

• AL1.1 is defined as:
  

${\displaystyle C_{N}\leq k\cdot C_{A}}$
This means that the discounted energy cost (LUEC) of a NES to be deployed or developed should be comparable, within a factor of k, to the LUEC of an available system with a competing energy source. As mentioned above, the LUEC of a NES and of a given competing energy source can be calculated using the NEST tool). Again, the case of deployment and development are distinguished. First, the case of deployment will be considered.

• Acceptance limit AL2.1: Figures of merit for investing in a NES are comparable with or better than those for competing energy technologies.

Investors can look at a variety of financial indicators when evaluating investments. The financial indicators used in a given region will reflect the investment climate and requirements of a given country or region, including the source(s) of investment funds. In some countries or regions implementation of a NES will require private sector investment, e.g. in deregulated electricity markets, while in other countries or regions installment of a NES may require government investment or guarantees, e.g. in countries embarking on a nuclear power programme.
Private sector investors will be attracted by a competitive IRR, provided the IRR is commensurate with their judgment of associated risks. However, the NPV of cash flows may be more suitable for government investors than private sector investors because this financial figure may facilitate taking into account other benefits such as security of energy supply and technology development. The ROI may be attractive as an indicator that is complementary to the IRR.
In the end, the acceptance limit is that the values of the financial indicators chosen, for a given NES, be attractive compared with investments in competing energy technologies. To be attractive, the values for the NES must be at least comparable to values for competitive energy sources and preferably better.
For indicator IN2.1, three items of financial figures of merit, namely, IRR, ROI and the NPV of cash flows are recommended as evaluation parameters (EP2.1.1 to EP2.1.3), with corresponding acceptance limits, as discussed below.
IRR, ROI and NPV can be calculated using the NEST tool.

For final assessment of acceptance limit AL2.1:
Acceptance limit AL2.1: Data for investing in a NES are comparable with or better than those for competing energy technologies.
The acceptance limit AL2.1 of CR2.1 is met if the financial figures of merit selected by the assessor meet their corresponding limit.

The total investment consists of the overnight capital, the interest during construction (the size of which depends on construction and commissioning times), contingency allowances, owners cost and (if not considered in the O&M cost) the capital needed for (foreseen) back fitting and decommissioning. It can be calculated using the NEST tool.
This indicator has been formulated in a general sense to cover investments in the different facilities of a NES, such as one or more NPPs, fuel cycle facilities and waste management facilities. For simplicity, it is recommended that an initial assessment focus on the investment needed for an NPP, since this is the energy machine and has to be made if a given country is to benefit from the energy produced by nuclear power. Of course, in a given country, there may be interest in investing in front end fuel cycle facilities, such as mines or fuel manufacturing facilities, but in general the investment in an NPP is more challenging. And, if this investment is made and nuclear power becomes/continues as part of a balanced portfolio of generating plants, the revenue from the NPPs can be used to finance the associated waste management activities and facilities. And investments in front end facilities can be evaluated taking into account the status of nuclear power in the country and worldwide. Consequently, in the discussion below only the issue of investing in the NPP is considered.
FOAK costs, together with R&D costs, would in general not be explicitly included in this indicator because such costs are different from simple electricity oriented fundraising mechanisms and are more related to R&D investment policies used by governments and/or private investors. FOAK and R&D costs born by the developer would be expected to be reflected in prices quoted by a vendor/developer, and so such costs would be implicitly included.
But should a company (utility) consider the purchase of a FOAK reactor, requiring significant FOAK investment by the purchaser, the company would have to take this investment into account in one way or another. It might simply accept the cost and include it in its analyses. But, generally, such a company would be expected to negotiate for some additional benefit. For example, it could negotiate with the supplier to secure price reductions for future orders, or even to share in the profit from future sales of the reactor to other utilities. In such cases, FOAK investment might be analysed using different variables/parameters. Nonetheless, the total investment required for the project would need to be raised and so in this circumstance the additional FOAK investment would need to be included.

• Acceptance limit AL2.2:

${\displaystyle Investment_{N}<Investment_{LIMIT}}$
Investment_LIMIT is the maximum level of capital that could be raised by a potential investor in the market climate. To meet this limit the investment needed for installing an NPP investmentN must be equal or lower than the maximum capital that can be raised by a potential investor.
The limit is strongly dependent on the investment environment in which an NPP is to be deployed, above all on the nature of the organization making the investment — a private sector commercial enterprise operating in a deregulated market, a private sector enterprise operating in a regulated market, or a State owned company.
In case a private company (utility) is planning to install an NPP, the maximum investment it can raise for this purpose (making a sound business case) will depend on the total size of the national electricity market, the utility’s share of the total market, and its profit margin. A simplified example how to determine the maximum reasonable investment of a private investor is available in the NEST tool.
The source of funds — whether the utility obtains funds from external investors (see Refs [9, 10]), or are drawn from the utility’s own capital reserves (equity) or some combination of the two sources will influence this limit. For example, if only reserves are used the size of the reserves will establish an upper limit, taking into account that the utility would probably not want to draw down all its reserves. If external investors are involved they would want to be assured that the utility’s cash flows will be sufficient to pay back the investment while also covering all other costs to which that the utility is exposed, including total operating and maintenance costs, payback of earlier investments etc.
As noted in Section 3.3 the IAEA offers support to Member States on how to determine the economic viability of investing in an expansion of an energy system or in a single power plant. The Excel based tool to be offered is called FINPLAN [4], which helps to analyse the impact of a planned investment on the financial health of a utility planning to invest. In case a government is planning to install a NES, the investment limit could be defined by the budget available for the national nuclear power programme. A variety of additional factors could influence the available budget, including the following:

1. A State oriented approach might establish a limit for any given project at some fraction of the total investment budget to be used in the energy sector.
2. The limit could be influenced by issues related to the currencies that are required for debt servicing.

In effect, the acceptance limit for deployment of the first few NPPs in a country is that the total investment required should be compatible with the ability to raise the necessary capital in the country at the time of committing to construction of the NPP. And for the deployment of additional units of the same basic type of NPP, the acceptance limit is that the total investment required is compatible with the ability to raise the necessary capital in the country at the time of committing to construction of the additional units, taking into account actual performance and costs for nuclear power in the country.
In case of an investment into a planned (or ongoing) development of a NES (or component thereof), the investment limit could be defined by the available budget of the organization involved.

Regulatory and technical uncertainties represent a project cost and schedule risk and a risk that the plant will not operate with the load factor assumed in the financial analysis. Regulatory uncertainties are linked to technical maturity, and so in the INPRO methodology the two are considered together. Broadly speaking, two different situations can be identified deciding whether to invest in technology development and deciding whether to invest in technology deployment.
When investing in technology deployment, there is a requirement that the technology’s maturity and safety have been adequately demonstrated in the development programme and licensing process as part of the technology adoption process.
In the case of technology development, a judgment is required that once development is complete the technology can be licensed in the country of origin. Thus, early in the development process, and before significant investment has been made, there is a requirement that the development team start a dialogue with the regulator to identify issues of concern and to establish a process and plan for addressing these issues during development so that sufficient information would be available to license an FOAK plant.

• Acceptance limit AL3.1: Technical development and status of licensing.

As shown below, AL3.1 of CR3.1 is split into four different parts depending on the situation, i.e. it is adapted to the situation in a country planning to install its first NPP, add a new NPP to an existing NES, and install a FOAK (AL3.1.1, AL3.1.2, and AL3.1.3, respectively), and for the case that a technology developer is planning to develop a NES (AL3.1.4).

• Acceptance limit AL3.1.1: For deployment of the first few NPPs in a country: Plants of the same basic design have been constructed and operated.
• Acceptance limit AL3.1.2: For deployment of additional units of the same basic type of NPP: Plants of the same basic design have been licensed, constructed and operated in the country and there are no outstanding technical or licensing issues which impact negatively on plant performance.
• Acceptance limit AL3.1.3: For deployment of a FOAK plant in a country with experience operating NPPs: Design is licensable in the country of origin.

The acceptance limits AL3.1.1 (first NPP), AL3.1.2 (follow-up units) and AL3.1.3 (FOAK) are discussed together below.
In the case of technology deployment, regulatory risk is minimized if the plant under consideration is similar to a plant that has already been licensed and operated, preferably in the country in which the plant is to be deployed. For a country deciding whether to deploy its first NPP, this is not possible. Then, the regulatory risk is minimized if plants of the same design have been licensed and operated in the country of origin. Thus, a country adopting its first nuclear power plant would generally want a plant that is similar to plants already operating in the country of origin, i.e. proven technology.
In the case of an innovative design (an advanced design which incorporates radical conceptual changes in comparison with existing practice), construction and operation of a prototype or a FOAK plant will provide confidence that technical uncertainties affecting safety have been addressed and lay the foundation for the licensing of additional plants, in the country of origin and also for deployment outside the country of origin. Thus, for a country adopting its first NPP, the minimum requirement is that similar plants have been licensed and operated. These arguments also apply to a country that has experience with operating NPPs but is considering a new type of plant. Once a utility has had experience with a given type of plant and is considering the deployment of additional units of the same basic type, an assessor should still determine whether or not there are outstanding technical or regulatory issues that might impact negatively on project performance (retrofits, schedule delays, etc.) and/or plant operational performance. If there are such issues they should be taken into account in the project schedule and plant load factors used in the financial analyses.
In some rare situations, a country may wish to consider investing in a FOAK plant that has been developed in another country, for example because of its superior economic performance. In this case, the minimum requirement is that the country deploying the plant have domestic experience with licensing and operating other NPPs, and that the supplier of the FOAK plant provide evidence from the regulatory authority of the country of origin that the FOAK plant could be licensed for operation in the country of origin.
In all cases, but particularly when considering an FOAK plant, it is important to clarify the expectations of the regulatory authority in the adopting country and to come to an informed judgment that these can be met before making a final commitment.
Evidence that a plant has been/can be licensed in the country of origin is a necessary condition, but does not remove completely the risk associated with the regulatory process. Thus, the purchaser may seek evidence that the supplier understands the regulatory requirements to be met in the country of deployment and that the supplier has a plan to manage this regulatory process and its attendant risks. In general, regulatory problems lead to project delays and hence cost overruns. So, regulatory risks to the customer can be offset in contractual arrangements, for example by imposing penalties for late project completion.

• In the following, the fourth acceptance limit AL3.1.4 (Technology development) is discussed.

Acceptance limit AL3.1.4: For technology development: Plan to address regulatory issues and the costs included in development proposal. Throughout the development process the development team needs to keep in mind that prospective customers will want evidence that the regulatory authority in the developer’s country would be prepared to license an FOAK plant. Usually, the FOAK plant would be constructed in the developer’s country and the development team should assume that this will happen. Thus, the team needs to have a plan for ensuring that regulatory issues are identified and addressed, as discussed above. In fact, resolving regulatory issues often play a major role in defining the overall development plan. Thus, an economic assessor looking at investment in development needs assurances from the development proponent that such issues have been identified, a plan has been developed to address them, and that the cost of the necessary development work has been estimated and has been included in the estimate of total development costs. Hence, once development has proceeded to the point of committing to FOAK plant, all major technical issues should be resolved and there should be no unresolved technical issues that would prevent a construction license being issued.

When considering indicator IN3.2, the following should be noted: Project delays lead to cost overruns, particularly in project management and engineering support costs and in IDC. The greatest impact of project delays, particularly on IDC, arises during construction and commissioning. Thus, the time taken to construct new facilities and to bring them into operation (and so to start generating revenue) should be as short as practicable and specific targets can and should be set as development objectives.
In assessing the time taken to design, construct and commission an NPP, it needs to be recognized that front end design work, environmental assessment, and licensing applications, while potentially lengthy, represent a relatively small investment compared with the investment required to procure, construct, install, staff and commission new facilities. Commissioning comes at the end of the process when the majority of investment funds have been expended and when the rate at which interest during construction accumulates is largest so it is important to minimize the duration of commissioning.

• Acceptance limit AL3.2: Construction and commissioning times.

As shown below, the acceptance limit AL3.2 of CR3.2 can be divided into four different categories depending on the situation, i.e. it is adapted to the situation in a country planning to install its first NPP, additional units and a FOAK (AL3.2.1, AL3.2.2 and AL3.2.3, respectively) and for the case that a technology developer is planning to develop a NES (AL3.2.4).

• Acceptance limit AL3.2.1: For deployment of the first few NPPs in a country. Construction schedule times used in financial analyses have been met in previous construction projects for plants of the same basic design.
  
• Acceptance limit AL3.2.2: For deployment of additional units of the same basic type of NPP. Construction schedule times used in the financial analysis are based on actual construction schedules achieved in previous projects in the country.
  

The financial risk associated with potential project delays is minimized if the financial analyses are based on a schedule that is similar to that which has been achieved in past construction projects for plants of the same basic design. Thus, when investing in a first NPP, the project times used should reflect actual performance by the supplier with constructing a plant of the same basic design and should include contingency. Next, the acceptance limit AL3.2.3 (FOAK) is presented.

• Acceptance limit AL3.2.3: For deployment of a FOAK plant in a country with experience operating NPPs. A convincing argument exists that the construction schedule is realistic and consistent with experience with previous NPP construction projects carried out by the supplier and includes adequate contingency.

For an FOAK plant, it will not be possible to use past experience with a plant of the same design. In this case the supplier needs to present an argument that the schedule used is realistic. This argument must include a discussion of previous experience, by the supplier, with constructing NPPs of a comparable complexity. Reductions in the duration of the project schedule, when compared with past experience, should be justified. Schedule risks should be identified and their financial consequences should be estimated when performing a sensitivity analysis (see criterion CR3.3).
Finally, the Acceptance limit AL3.2.4 (development) is discussed below.

• Acceptance limit AL3.2.4: For technology development. Schedules are analysed to demonstrate that scheduled times are realistic, taking into account experience with previous NPP construction projects.

For technology development, a goal should be to reduce construction times to the lowest practical values using advanced construction techniques. Different plant designs may have different project execution times. Recent construction times for reactor projects have been as short as 52 months (first concrete to criticality) and commissioning periods from first criticality to full power have been as short as two to three months for repeat projects. Thus, a construction period of 48 months is judged to be an achievable target, for repeat reactor projects, within the near future. In due course, with innovation, use of in-shop modular construction, and for repeat plants, construction periods as short as 36 months might be achievable.

Indicator IN3.3: A sensitivity analysis of important input parameters for calculating costs and financial figures of merit has been performed.
For relative costs based on LUEC, the sensitivity of the ratio C_N/C_A should be studied for changes in the discount rate, overnight capital costs, construction time, and plant lifetime assumed in the calculation, and fuel costs, changes in the cost of fuel the nuclear plant and for the alternative competing technology. Here it may be noted that the high capital cost of nuclear makes its LUEC sensitive to the discount rate, while the LUEC for fossil fuel plants tends to be relatively more sensitive to fuel costs.
The sensitivity of the relevant financial figures of merit IRR, ROI and NPV — should be determined for changes in overnight capital costs, capacity factor, construction schedule, plant lifetime, availability of plant, fuel costs, and NPV, and additionally for changes in the discount rate.
For the critical input parameters, a range of possible values has to be specified. The range of variation of the parameters affecting the values of the economic indicators should not be unrealistically large to avoid being overly cautious, but should also not be unduly restrained. In the case of a design under development, it is evident that the higher the maturity of a design the lower the uncertainty of its economic input parameters. Thus, it is expected that the range of possible input values will be larger for an innovative design compared with an evolutionary design. If, in addition to the range of possible values, the corresponding probability is also available, one carry out a probabilistic analysis producing a distribution of LUEC, IRR, etc. Such an analysis would provide additional insights to the user. The aim of such a sensitivity study is to understand how changes in modelling assumptions impact the economic analyses, to obtain a good understanding of the relative importance of various factors and associated risks.
The INPRO methodology is an assessment method and does not include analysis per se. Nonetheless, the INPRO assessor needs the result of such analyses. The result of the sensitivity analysis is a case in point. In this case the assessment team might perform the analysis itself using the NEST tool, or it could seek to obtain the information from the designer/developer of the NPP, or from other experts, e.g. the IAEA.
The results of such a sensitivity analysis should be presented so that the sensitivities of LUEC and the relevant financial data to changes in the values of the parameters of interest are clear. For most if not all projects, various risk contingencies are included in the project cost and schedule estimates. Such a sensitive study can be used to test the adequacy of such contingencies and/or to see the impact on economic parameters. For example, how does a delay in the project schedule of the NPP impact the cost of C_N relative to C_A?

• Acceptance limit AL3.3: Sensitivity to changes

Acceptance limit AL3.3: Sensitivity to changes in selected parameters is acceptable to the investor AL3.3 is met if the results of such a sensitivity analysis are available to the assessor and if the sensitivity to changes in selected parameters is acceptable to the investor. Acceptable sensitivity means that the overall result of the economic assessment is not reversed, e.g. that a small increase in construction time does not make nuclear power non-competitive against an alternative energy source.

• Acceptance limit AL3.4: Commitment sufficient to enable a return on investment

In assessing the risk of investment in nuclear energy systems the ‘political climate’ or environment in a country should be considered to determine whether there is political support for nuclear power, and whether such support is likely to be sustained. Information on the political climate is needed for an assessment based on the INPRO methodology area of infrastructure.
The issue of the political climate is presented in the area of economics primarily to ensure that an assessment in the area of infrastructure has been carried out and that this assessment has established that the political climate is favourable. Thus, if this issue has been addressed AL3.4 is met.
If such an assessment has not been done, the assessor in the area of economics should conclude that the investor is faced with an unknown and important risk that needs to be addressed by the proponent of the project. It is not the responsibility of an economic assessor to judge the political climate but rather to ascertain that the issue has been addressed.