Abstract
The electricity market is undergoing significant change with the increasing deployment of Variable Renewable Energy Sources (VRES) and the adoption of policies to electrify transport, heating and industry, which will continue to increase demands on all conventional power plants including nuclear. The increase in VRES also puts additional emphasis on services such as inertia and frequency response that only conventional plants, including nuclear, are readily able to meet. This study discusses what factors limit the ability of nuclear power plants to provide flexible response and how the UK nuclear power plants might be affected by the changes in future demand profiles. The study focuses on what impact there will be on current Pressurised Water Reactor (PWR) plants, though it also considers Small Modular Pressurised Water Reactor plants which might offer benefits with respect to improved power manoeuvrability. The main finding is that the most important attribute is the minimum power level for long-term operation, followed by the speed at which the plants can be brought online (that is, both start-up rate and ramp rate during power operation). With respect to both of these attributes, new build future PWR plants could potentially achieve large and rapid power changes by dumping part of the steam directly into the condenser, bypassing the steam turbine. Discussions with plant operators highlighted that there is currently limited demand for flexible operation in the UK from nuclear plants when other power plants are readily available to partake in flexible operation. The lack of any requirement for nuclear plants to operate flexibly means that the UK lags behind France, for example, which has much more experience in nonstationary operation of nuclear power plants. The paper also draws attention to the fact that with increasing VRES, there will be fewer plants able to provide rotational inertia and therefore more emphasis on the role the remaining plants (which include nuclear) can play in maintaining grid stability.
Highlights
There are a number of changes simultaneously taking place in electricity supply systems, which include: the increasing deployment of Variable Renewable Energy Sources (VRES), such as wind and solar energy; and the desire to electrify more of the current demand, including heat and transport [1]
The emphasis in this study is on Pressurised Water Reactors (PWRs) given that they make up the majority of existing Light Water Reactors (LWRs) systems deployed to date [5]
Whilst this study focuses on current PWR plants, it considers Small Modular Pressurised Water Reactor (SM-PWR) plants which might offer benefits with respect to improved power manoeuvrability
Summary
There are a number of changes simultaneously taking place in electricity supply systems, which include: the increasing deployment of Variable Renewable Energy Sources (VRES), such as wind and solar energy; and the desire to electrify more of the current demand, including heat (domestic, commercial and industry) and transport (mainly via the deployment of electric vehicles) [1]. We provide a detailed summary of the current power manoeuvrability characteristics of NPPs, along with a comparison to other conventional plants, focusing on: ramp rates, minimum power levels and restart times. This is followed by a discussion on the reactor physics considerations when operating plants in a flexible manner and other mechanisms, principally fatigue, that limit flexible operation in NPPs. we consider alternative means to provide large rapid power changes in NPPs. Whilst this study focuses on current PWR plants, it considers Small Modular Pressurised Water Reactor (SM-PWR) plants which might offer benefits with respect to improved power manoeuvrability.
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