A nuclear power reactor generates 4.0 x 109 W of power. In one year (365.25 days), what is the change in the mass of the nuclear fuel due to the energy being taken from the reactor?
nuclear power reactor generates 4.0 x 109 W
one year (365.25 days),
4.0 * 10^9 W = 4.0 * 10^9 J/s
4.0* 10^9 J/s * 60 s/min * 60 min/hr * 24 hr/day * 365.25 days/year
=1.26*10^17 J
change in energy = change in mass * speed of light^2
1.26*10^17 J = change in mass * (3*10^8)^2
change in mass = 1.4 kg
A nuclear power reactor generates 4.0 x 109 W of power. In one year (365.25 days),...
A nuclear power plant produces an average of 3.2x10^3 MW of power during a year of operation. Find the corresponding change in mass of reactor fuel, assuming all of the energy released by the fuel can be converted directly to electrical energy. (In a practical reactor, only a relatively small fraction of the energy can be converted to electricity.)
Nuclear power stations in Canada use a type of reactor inventea in Can a Canada Deuterium Uranium (CANDU) reactor. A typical CANDU fuel bu mass of 23 kg. A A mada called bundle has a (a) Calculate the amount of electrical energy produced by a single CANDU fuel bundh assuming that the entire bundle is converted to electrical energy. [ans:2.1x 10 undle (b) An average Canadian home uses 3.6 x 1010 J of energy per day. Determine the number of...
5. A nuclear power plant produces an average of 2.10 x 103 MW of power during a year of operation. Find the corresponding change in mass of reactor tuel, assuming all of the energy released by the uel can be converted directly to electrical energy, in a pracnea reactor, on a reative sına acaon the energy can be converted to electricity.) kg
For example , if a nuclear fission reactor produces an average power of 1.0 GW over the year (10^9 W), what mass of U-235 has undergone fission in that time? Use the stat that on average 200 MeV energy is released per fission reaction. Please not that on average a mole of uranium (containing 6.023 × 1023 nuclei) has a mass of 235.043930 g
A 1000 MWe nuclear reactor (5% U-235 fuel) has been operating at 100% power for 10 continuous days. On day 10, reactor power is brought down to 100MWe to load follow the power grid. After holding at 100MWe for 24 hours, the reactor starts to lose power. Despite additional removal of control rods, the reactor power continues to drop. a) What is causing the reactor to lose power? b) What steps can be done to correct this issue in the...
We consider a nuclear reactor of power output P=1000 Megawatt (1000 million watts) electric, functioning with Plutonium. It is fueled, initially, with 1000 kg of Plutonium. The nuclear material in question is made of Plutonium nuclei, each consisting in 94 protons and 239-94=145 neutrons, which is denominated by the symbol 94Pu239. For thermodynamical reasons, only 1/3rd of the nuclear energy in the form of heat produced by the reactor, can be converted into electricity. How much mass deficit Δm should...
a) (15 p) We consider a nuclear reactor of power output P-1000 Megawatt (1000 million watts) electric, functioning with Plutonium. It is fueled, initially, with 1000 kg of Plutonium. The nuclear material in question is made of Plutonium nuclei, each 239 consisting in 94 protons and 239-94-145 neutrons, which is denominated by the symbol 94 Pu For thermodynamical reasons, only 1/3 of the nuclear energy in the form of heat produced by the reactor, can be converted into electricity. How...
We consider a nuclear reactor of power output P=1000 Megawatt (1000 million watts) electric, functioning with Plutonium. It is fueled, initially, with 1000 kg of Plutonium. The nuclear material in question is made of Plutonium nuclei, each consisting in 94 protons and 239-94=145 neutrons, which is denominated by the symbol 94Pu239. For thermodynamical reasons, only 1/3rd of the nuclear energy in the form of heat produced by the reactor, can be converted into electricity. How much mass deficit Δm should...
please solve
QUESTION 1 239 a) (15 p) We consider a nuclear reactor of power output P-1000 Megawott (1000 million watts) electric functioning with Plutonium. It is fueled, initially, with 1000 kg of Plutonium. The nuclear material in question is made of Plutonium nuclei, each consisting in 94 protons and 239-94-145 neutrons, which is rd denominated by the symbol 94 Pu For thermodynamical reasons, only 1/3 of the nuclear energy in the form of heat produced by the reactor, can...
QUESTION 1 a) (15 p) We consider a nuclear reactor of power output P=1000 Megawatt (1000 million watts) electric functioning with Plutonium. It is fueled, initially, with 1000 kg of Plutonium. The nuclear material in question is made of Plutonium nuclei, each consisting in 94 protons and 239.94-145 neutrons, which is 239 rd denominated by the symbol Pu For thermodynamical reasons, only 13 of the nuclear energy in the form of heat produced by the reactor, can be converted into...