russ_watters said:Note that due to the lower temperature of steam pluss losses due to the extra piping, and heat exchanger, the thermodynamic efficiency of a nucler plant is lower than a most other types of steam engines.
gmax137 said:Well that's true enough. The plant's thermo efficiency is a measure of the electrical power provided as a fraction of the thermal power produced in 'burning' the fuel. Other measures of 'efficiency' might try to quantify the 'amount' or 'value' of the fuel being burned to produce a unit of electric power. A 1000 MWe nuclear station, with its lowly 34% thermodynamic efficiency, burns up about 100 tons of fuel in 2 years. The super efficient coal station, is burning over 200 tons an hour to produce the same electrical output. Over the same two years that would be 3.5 million tons of coal used up compared to 100 tons of uranium oxide.
And remember, the uranium isn't really useful for anything else, other than WMD.
So the statement that "the thermodynamic efficiency is lower" is true, but it isn't very meaningful in the context of comparing different power stations.
QuantumPion said:LWR's don't burn 100 tons of fuel in 2 years. 100 tons is along the lines of the total uranium loading of the core, most of which is U-238. If the uranium started at 5% enrichment, after 2 years you would have used up ~5 tons of U-235 (plus ~3 tons of Pu on top of that by conversion).
QuantumPion said:LWR's don't burn 100 tons of fuel in 2 years. 100 tons is along the lines of the total uranium loading of the core, most of which is U-238. If the uranium started at 5% enrichment, after 2 years you would have used up ~5 tons of U-235 (plus ~3 tons of Pu on top of that by conversion).
Nuclear energy is harnessed through a process called nuclear fission, where atoms of uranium are split apart in a controlled chain reaction. This process releases a large amount of heat, which is used to create steam that turns turbines and generates electricity.
The source of nuclear energy is the nucleus of an atom. Specifically, the energy comes from the strong forces that hold the nucleus together. When these forces are disrupted through nuclear fission, a tremendous amount of energy is released.
Nuclear energy is considered non-renewable because it relies on finite resources, such as uranium, which must be mined and processed. However, some experts argue that with advanced technology, nuclear energy could be considered renewable, as there is a virtually unlimited supply of uranium in the Earth's crust.
Nuclear energy is a reliable and efficient source of electricity, producing large amounts of energy without emitting greenhouse gases. It also has a relatively small physical footprint, making it suitable for densely populated areas. Additionally, nuclear power plants can operate for long periods of time, providing a stable source of electricity.
The main risks associated with nuclear energy are the potential for accidents and the disposal of radioactive waste. While modern nuclear power plants have safety measures in place to prevent accidents, the consequences of a major accident can be catastrophic. Additionally, the long-term storage of radioactive waste is a major concern and requires careful management to prevent harm to humans and the environment.