Abstract: A nuclear power plant (18) and its heat exhanger (26) are enclosed in an envelope (22) which is suspended above a bored shaft (14) from a support stem (30). When appropriate, the stem (30) can be melted by a furnace (34) to drop the envelope (22) to the bottom of the shaft (14). Sand (42) can then be dropped onto the envelope (22) through a drainage pipe (46). While the nuclear power plant (18) is operating and suspended in the shaft, spent fuel rods (70) are dropped into a sand blasting machine's hopper (130), mixed with sand and dropped into a bag (134) containing a small explosive device. The bag (134) is then dropped to the bottom of the shaft (14) and the explosive detonated to scatter the contents of the bag (134). Optionally, more sand or earth is then added to reduce heat and radiation to acceptable levels.
Abstract: A dry radioactive substance storage facility stores spent fuel assemblies from nuclear power plants. The facility comprises a structure having a storage room storing storage tubes containing spent fuel assemblies. An air inlet duct defining an air inlet passage through which air is supplied into the storage room and a stack defining an air discharge passage through which air from the storage room is discharged outside are connected to the storage room. Radiation shielding members are disposed on the side of the air inlet duct and on the side of the stack, respectively, in the storage room to intercept radiation propagating toward the air inlet passage and the air discharge passage.
Abstract: Nuclear devices are detonated periodically inside an underground cavity in which a working fluid absorbs most of the thermal energy released by the device detonation. The kinetic energy contained in the shock wave created within the working fluid is absorbed by shock absorbers located outside the inner wall of the cavity. This wall consists of adjacent plate segments that separate and recoil outwardly as do pieces of shells of fragmentation grenades. The shock wave kinetic energy is transferred to the segments that are constrained in their outwardly-directed flight by shock absorbers. The shock-absorbing system is solidly attached to the rock structure surrounding the cavity. The loading transmitted to the rock is of a much lower intensity than that which the plate segments sense, though of a much longer duration. The momentum trapped in the shock wave is thus absorbed by the rocks but in a manner such that the rock structure is not affected.
Abstract: Accelerated decay of radioactive materials is used for power production. In the method of this invention an alpha-emitting radioactive material is placed in a region. The region is selected so that when a negative potential is applied to the region, enhanced alpha decay of the radioactive material results. The energy of the alpha decay particles is captured and converted to thermal energy.
Abstract: A spherical underground cavity is filled with saturated steam or a mixture of saturated steam and coal dust in which a nuclear device is detonated to provide the source of energy. The energy thus released heats the saturated steam to produce superheated steam used to generate power. If coal dust is mixed with the saturated steam in the correct ratio, the rise in temperature caused by the nuclear explosion initiates a chemical reaction between the steam and the coal to produce carbon monoxide and hydrogen. The mixture of carbon monoxide and hydrogen can be used as fuel in an external power plant. The carbon monoxide and the hydrogen gases can also be separated for use as fuels or for industrial applications. The wall of the spherical underground cavity is isolated from the shock wave created by the nuclear explosion in the ambient saturated steam by a segmented steel shell. Each segments is supported by a shock absorbing mechanism attached to the rocks in which the cavity is embedded.