King’s Speech Debate
Full Debate: Read Full DebateViscount Hanworth
Main Page: Viscount Hanworth (Labour - Excepted Hereditary)Department Debates - View all Viscount Hanworth's debates with the Department for Science, Innovation & Technology
(1 year ago)
Lords ChamberMy Lords, I will talk about nuclear technology. The Government must sustain the nuclear industry by ensuring that a sufficient number of nuclear power plants are built to maintain the supply of our electricity. They must also support the development of innovative nuclear technologies to assist in the decarbonisation of our industries.
The privatisation of the electricity industry appeared to validate the opinion of the Conservatives that private industry could be relied on to maintain the nation’s energy infrastructure. With the benefit of newly exploited North Sea gas, the private electricity companies began to replace existing coal-fired power stations with combined- cycle gas turbine plant. These could be constructed rapidly and demanded much smaller capital investments than the plants that they replaced.
At a later date, the same companies began to respond to the Government’s incentives to construct offshore electricity-generating wind farms. The Government’s incentives have been far less successful in inducing the electricity companies to invest in nuclear power plants. The problem here has been the size of the necessary capital investments and the long duration of the construction period that precedes the generation of any revenues.
In the view of some commentators, most of the nation’s requirements for electricity could be met by wind and solar power, which appear much cheaper to deploy than nuclear power. It is claimed that as much as 70% of demand can be satisfied in this way. However, these are intermittent sources of power: often the sun does not shine and the wind does not blow, and then no electricity can be generated by these means. At such times, the deficit is currently being met by gas-powered electricity. This is an effective recourse only when the so-called renewable sources of power generate less than 30%, on average, of the total supply of electricity.
Moreover, gas is a fossil fuel that emits carbon dioxide. In the absence of a means to capture its emissions, gas cannot continue to be exploited for this purpose if we are to meet the objective of decarbonising the economy. If the demand for electricity is to be met at all times and if we are to depend solely on the renewable resources of wind and solar power, there has to be a means to store the energy. It is widely believed that the most appropriate means of achieving this is to use any available surpluses of electricity to generate hydrogen via a process of electrolysis. The hydrogen would be used to power fuel cells and turbines to generate electricity and would find other industrial uses.
However, to accommodate the intermittence of the renewable sources of power, if they were to become the dominant sources, would require major capital investments in technologies that have yet to be realised. Large amounts of hydrogen would have to be stored over a long period to meet the eventuality of a prolonged dearth of wind and solar power. When the costs of constructing and maintaining the necessary infrastructure are added to the costs of the renewable sources of power, they no longer appear cheap. Projects to establish such facilities, if they were to be undertaken by the private sector, would encounter the very difficulties that have beset the projects to build nuclear power stations. They would require large amounts of capital and the financial returns would be deferred for far too long.
Nuclear power, which is capable of generating a constant supply of electricity, suffers from none of the problems of intermittence that affect the so-called renewable sources of power. It should be relied on in future to satisfy most of the demand for electricity. Nuclear power is a mature technology which has been exploited for almost 70 years. However, in deploying it today, we should exploit some new technologies. There are three distinct purposes that can be served by nuclear power plants, and they demand different kinds of nuclear reactors.
First, we need nuclear power stations that contribute electricity to the grid. Various reactors are on offer for this role, mainly pressurised water reactors. At one end of the spectrum are the EPRs, rated at 3,300 megawatts of electrical power, which are to be deployed in the mega power stations of Hinkley Point C and Sizewell C. At the other end is the small modular reactor of Rolls-Royce rated at about 470 megawatts of electrical power. We should persist with Hinkley Point C and Sizewell C, but they should be succeeded by a fleet of SMRs from Rolls-Royce, which should be distributed widely throughout the country. Pressurised water reactors are described as third-generation reactors. In due course, they should give way to a fourth generation of reactors, some of the leading examples of which are currently under development in this country.
The second purpose, which is to power industrial processes, can be served by much smaller reactors. The British MoltexFLEX molten salt reactor, which is simple and robust, can fulfil this role. It was originally proposed as a marine reactor and it will generate 50 megawatts of thermal power. Another reactor that could serve this purpose, which is rated at 100 megawatts of thermal power, is being developed jointly by Copenhagen Atomics and UK Atomics. The fuel of this reactor is thorium, which is described as fertile as opposed to fissile. Once the reaction is under way, thorium generates fissile uranium and creates very little waste.
The third purpose that can be served by the new generation of reactors is consuming the existing stocks of plutonium. The newcleo reactor, which can be described as a lead-cooled fast reactor, has this capability. Alternative versions will generate 50 or 200 megawatts of electrical power. This is a project with British, French and Italian backing. The newcleo reactor can also consume MOX fuel that is a mixture of uranium and plutonium, which is generated from the waste of conventional pressurised water reactors. A variant of the Moltex reactor, which is of interest to the Canadians, also has this capability. It is described as a waste burner and will generate 300 megawatts of electrical power.
These are all fourth-generation reactors endowed with passive safety. Their proponents are keen to describe them as British projects, but each is of interest to at least one other country. I fear that, unless our Government undertake active sponsorship of these projects, their ownership and intellectual capital will be ceded to those other countries. Financial subventions are required that seem modest in comparison with the money wasted by purchasing unusable personal protective equipment during the Covid pandemic.
Sites must be designated where the prototype fourth-generation reactors can be located. Alternatively, a technology park could be created to host these reactors. If the necessary support were immediately forthcoming, these reactors could be up and running by 2030, which could be some time before the completion of the Sizewell C power station. However, if the necessary support is not forthcoming, the projects are liable to emigrate to other countries, and we would be in the position of importing the products of technologies that originated in this country.