Abstract: A microwave burning furnace including a housing constituted by a metal on which a microwave is to be irradiated, a metallic door provided in the housing, a burning chamber provided in the housing and surrounded by a material having a low microwave absorption characteristic and a high heat insulating property, and microwave generating means, wherein the burning chamber includes a heater element constituted by at least two types of heating materials having a heating material for a high temperature region which automatically generates a heat mainly in the high temperature region to have a burning temperature by an irradiation of a microwave and a heating material for a low temperature region which automatically generates a heat mainly in the low temperature region including an ordinary temperature.

Abstract: A sintering furnace for sintering an object to be sintered formed of ceramics, fine ceramic materials, etc. to produce a sintered object and a method therefor. An insulating wall (28) and an inner shell (25) define a sintering chamber (16) for sintering an object to be sintered (10). Thermal equilibrium is maintained between the inner shell (25) and the object to be sintered (10), and the object to be sintered (10) is completely pseudo-adiabatically isolated to achieve more uniform and small energy consuming sintering. The thickness of the insulating wall (28) increases gradually from an inlet (20) toward an outlet (21). The object to be sintered (10) is fed by a carriage provided in a sintering furnace from the inlet (20) to the outlet (21) in the sintering chamber (16). Thereby, a temperature distribution corresponding to a plurality of processes can be easily formed in one furnace to sinter continuously the object to be sintered (10) in the furnace.

Abstract: A gas flow from a gas reservoir is accelerated up to supersonic velocity beyond the throat of a Laval nozzle. The accelerated supersonic gas flow is introduced into a plasma generating preaccelerating system, and thereby converted into the plasma flow of the velocity close to the thermal's. Then, the primary plasma flow is introduced into an arcjet discharger, to be accelerated to super thermal velocity by the viscosity force, similar to a sonic wind.

Abstract: Current leads are used for connecting a power supply placed in a room-temature environment and a superconducting coil placed in an ultralow-temperature environment. The current leads includes a first current lead and a second current lead. The first current lead is made up of a room-temperature N-type thermoelectric semiconductor, a low-temperature N-type thermoelectric semiconductor, and a high-temperature superconductor. The second current lead is made up of a room-temperature P-type thermoelectric semiconductor, a low-temperature P-type thermoelectric semiconductor, and a high-temperature superconductor. At least one of the first and second current leads is formed of a functionally gradient material.

Abstract: A pellet carrier disc is movably held between two cooling blocks. The disc is vertically moved, setting its through hole into axial alignment with a first hole of the block. Deuterium gas is supplied into the through hole through the hole, and cooled and solidified, forming a deuterium cylinder. Then, the disc is moved, axially aligning the hole with a second hole of the block. A shaft is thrust into a first end of the deuterium cylinder through the hole, thereby forming a hole in the end of the cylinder. Next, the disc is moved, axially aligning the hole with a third hole of the block. Tritium gas is introduced into the hole of the cylinder through the hole, and cooled and solidified, forming a tritium core. Further, the disc is moved, axially aligning the hole with a fourth hole of the block. A shaft is moved through the hole, causing the second end portion of the deuterium cylinder to project from the hole. The second end portion of the cylinder is cut off.