Abstract
With extensive research being undertaken into small modular reactor design concepts, this has brought new challenges to the industry. One key challenge is to be able to compete with large scale nuclear power plants economically. In this article, a novel approach is applied to reduce the overall dependence on fixed burnable poisons during high reactivity periods within a high temperature graphite moderated reactor. To reduce the excess activity, we aim to harden the flux spectrum across the core by removing part of the central moderation column, thus breeding more plutonium, in a later period the flux spectrum is softened again to utilise this plutonium again. This provides a neutron storage effect within the 238U and the resulting breeding of Plutonium. Due to the small size and the annular design of the high temperature reactor, the central reflector is key to the thermalization process. By removing a large proportion of the central reflector, the fuel within the proximity of the central reflector are less likely to receive neutrons within the thermal energy range. In addition to this, the fuel at the extremities of the core have a higher chance of fission due to the higher number of neutrons reaching them. This works as a method of balancing the power distribution between the central and outside fuel pins. During points of low reactivity, such as the end of the fuel cycle, the central reflector can be reinserted and the additionally bred plutonium and U235 at the centre of the core will encounter a higher probability of fission due to more thermal neutrons within this region. By removing the central reflector, this provided a 320 pcm reactivity drop for the duration of the fuel cycle. The plutonium buildup provided additional fissile material up until the central reflector was reinserted. The described method created a two-fold benefit. The overall full power days within the core was increased by ~31 days due to the additional fissile material within the core and secondly the highest loaded power pins saw a 30% power reduction during the removal of the central reflector column.
Highlights
The global energy landscape is transforming at a dramatic rate due to legislation promoting the reduction of carbon dependent sources in favour of low carbon or green alternatives
This shift towards nuclear energy has placed the UK in a strong position for future nuclear development, with reputable companies such as Rolls-Royce, Nu-Scale and Westinghouse [5,6,7] all showing interest in proving small modular reactor (SMR) designs for the UK. These companies offer mainly similar technology in their light water reactor (LWR) designs, which are very similar to the traditional reactors already operating globally
IV very high temperature reactor, so advances in this field could be used in. The basis for this technology in their light water reactor (LWR) designs, which are very similar to the traditional reactors already operating globally
Summary
The global energy landscape is transforming at a dramatic rate due to legislation promoting the reduction of carbon dependent sources in favour of low carbon or green alternatives. This shift towards nuclear energy has placed the UK in a strong position for future nuclear development, with reputable companies such as Rolls-Royce, Nu-Scale and Westinghouse [5,6,7] all showing interest in proving SMR designs for the UK. These companies offer mainly similar technology in their light water reactor (LWR) designs, which are very similar to the traditional reactors already operating globally.
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