RU2129740C1 - Space-based nuclear power plant - Google Patents

Abstract

FIELD: nuclear power engineering. SUBSTANCE: power plant has nuclear power reactor with core incorporating tubular fuel elements and heat insulation placed in metal can, modular thermionic generator in the form of stack of thermionic converter modules with high-temperature heat pipe whose evaporation zone is located in reactor core. Condensation zone of heat pipe accommodates thermionic converters with shaped intermediate-temperature heat pipes transmitting heat to radiating cooler built up of finned intermediate-temperature heat pipes. Some portion of core heat insulation is made of set of pyrographite crucibles inserted in each other and joined together by means of carbon pins so that low heat-conductivity axis is perpendicular to external surface of heat insulation. Condensation zone of high-temperature heat pipes is located in channels of fuel elements with guaranteed clearance of 2 to 5 mm; emitters of thermionic converters are joined with external wall of high- temperature heat pipe in condensation zone; their collectors are joined with shaped intermediate-temperature heat pipe without electric insulation. Electrode-to-electrode electric insulation on thermionic converters is, essentially, shunt made of stack of metal sleeves coaxial with electrodes of thermionic converters and bellows, all welded together; collectors and emitters of converters are made in the form of fitted-in taper bushings; spacer bushings made of emitter material are installed between emitter current lead and collector; bearings are pinned to bushings. EFFECT: enlarged service life and improved performance characteristics of space-based nuclear power plant. 1 dwg

Description

 The present invention relates to nuclear energy, in particular to space nuclear power plants.

 There are known designs of space nuclear power plants with a capacity of 120-500 kW [1, 2, 3] with a system for direct conversion of heat into electricity — thermionic converters — taken out of the core of a nuclear reactor.

 These power plants have the same layout solution, the composition of the blocks and a single circuit diagram, where the heat generated in the nuclear reactor is transported outside it by high-temperature heat pipes to the emitters of tube thermionic converters, from which the unconverted heat is discharged by radiation from the refrigerator emitter.

 The closest technical solution to the proposed invention is the design [4] of a space nuclear power plant, the principle thermal circuit of which is to transfer heat from a nuclear reactor to a remote modular thermionic emission generator and from it to the refrigerator-emitter through heat pipes. The layout solution consists in the sequential arrangement along the axis of the power plant of its main components - a nuclear reactor, thermionic generator, radiation protection, radiator refrigerator - in the volume of a truncated cone.

 The disadvantage of this design is the limited resource due to the use of brazed metal-ceramic assemblies as an electrode, contact of dissimilar materials in the high-temperature zone and the use of ceramic spacers, a decrease in the electrical parameters of the generator in comparison with the capabilities of the thermionic conversion method, while reducing the overall dimensions of the power plant due to the use thermally conductive electrical insulation, as well as due to insufficient Mechanical Protection strength.

 The present invention solves the technical problem of increasing the resource and operating parameters of a space nuclear power plant.

 The stated technical problem is solved in that in a space nuclear power plant containing a nuclear reactor with an active zone and thermal insulation, placed in a metal casing, a modular thermionic emission generator in the form of a package of thermionic converters with a high-temperature heat pipe, the evaporation zone of which is immersed in the reactor core, and in the condensation zone a thermionic converter with a shaped medium temperature heat pipe is installed to transfer heat to the refrigerator -radiator, a modular fridge-emitter of finned medium temperature heat pipes, consisting of sections equal to the number of modules in the thermionic generator, while the core insulation part is made as a set of pyrographite or carbon crucible pins inserted into each other and bonded to each other by carbon pins composite material so that the axis of low thermal conductivity of the material (axis "C") is perpendicular to the outer surface of the insulation, the evaporation zone is high thermal pipes are placed in the channels of the core with a guaranteed (2-5 mm) gap, the emitters of the thermionic converters are aligned with the outer wall of the high-temperature heat pipe in the condensation zone, and their collectors are combined with a shaped medium-temperature heat pipe without case heat-conducting electrical insulation, interelectrode electrical insulation of thermoelectric made in the form of a shunt, consisting of a package of thin-walled metal thermionic converters inserted coaxially with the electrodes of all cups and bellows welded together, the emitter and collector are made in the form of tapered bushings ground to each other with a gap of 0.1-0.5 mm, spacer bushings with bearings made of material of the emitter current lead based on electrically insulated are installed between the emitter current output and the collector (coating) the surface of the current lead, and the bearings are fastened to the bushings using pins.

 Since it is intended to use refractory nuclear fuel (uranium dicarbide), the present invention adopts the concept of maintaining the core in a compact state (without expansion) in emergency situations until it falls to Earth from an orbit of an artificial Earth satellite.

 This embodiment of the invention allows to ensure the indestructibility of the core of a nuclear reactor in various critical situations due to the aforementioned thermal insulation made of pyrographic crucibles, since this provides thermal protection from aerodynamic heat flows, while the thickness of the thermal insulation and the length of the external crucible are selected from the calculation of allowable heat leakage during installation operation and ensuring permissible overheating of the fuel elements, the ablation of the mass of pyrographite during aerodynamic drag, and also dissipation of residual heat without fuel melting (pyrographite thickness in the range of 12-20 mm). Placing the evaporation zone of the heat pipe in the central channels of the fuel elements with a given gap allows you to remove fission fragments and gas separation products from the gap due to the presence of space vacuum and to exclude thermochemical reactions of materials of the high temperature pipe and the core.

 The combination of the emitter of the thermionic converter with the outer wall of the heat pipe in the condensation zone, and the collector of the thermionic converter with the shaped heat pipe-heat pipe leads to the fact that the high-temperature heat pipe has the potential of the emitter, and the shaped heat pipe and the section of the heat pipe of the emitter have a collector potential, while section of the heat pipe of the emitter is a conductor for transferring energy from the generator section to the electrical unit, fixing the design of the module to sexually-elements is performed using standard insulating materials without providing a vacuum density. The absence of a case emitter and collector heat-conducting electrical insulation reduces thermal resistance to heat flow through thermionic converters. At a fixed temperature of a high-temperature heat pipe, determined by the permissible core temperature, this leads, in comparison with the prototype, to an increase in the emitter temperature and, as a result, to an increase in electric power and efficiency. Collector thermal resistance at the optimal collector temperature increases the temperature of the emitter, thereby increasing the overall dimensions of the power plant. The implementation of the shunt in the above manner allows the welding of the tips to the emitter current output and the collector to obtain a sealed volume filled with cesium vapor, and to exclude the ceramic-metal assembly of interelectrode electrical insulation. The implementation of the emitter and the collector in the form of tapered bushings ground to each other ensures automatic preservation during operation of the interelectrode gap of the required size for the axial movement of the collector relative to the emitter, taking into account the deformation of the bellows with fixing their position.

 All this allows to increase the output characteristics, reliability and resource of the installation as a whole by increasing the reliability and resource of thermal insulation and improving the parameters of thermionic converters.

 The invention is illustrated by the diagram shown in the drawing, which shows a structural diagram of a space nuclear power plant, consisting of coaxially located within a truncated cone of a nuclear reactor 1, a modular thermionic electric generator 2, radiation protection 3 and a modular refrigerator-radiator with heat pipes 4, the number modules of the electric generator is equal to the number of modules of the refrigerator-emitter. The composition of the nuclear reactor includes a high-temperature core 5 with holes and thermal insulation in the form of a casing 6, consisting of a package of pyrographite crucibles inserted into each other, fastened with pins 7. Heat-absorbing sensors (evaporation zone) are installed in the openings of the core with a gap (2-5 mm) the ends of high-temperature heat pipes 8. In the heat removal zone (condensation zone), these heat pipes have conical bulges and their outer surfaces are emitters of thermionic converters of modules 9. Number of modules corresponds to the number of heat pipes. The all-metal, all-welded module includes, in addition to the emitter, an end collector 10, emitter current leads 11, welded through a metal shunt in the form of a package of thin-walled metal cups and bellows 12 coaxially arranged with electrodes, with a collector 10. Conical electrodes have cages 13 with bearings 14, fastened together by pins 15. The bearings are supported on the surface of the emitter current leads coated with electrical insulation 16. The electrode gap is set by axial displacement of the collector 10 in relation ju to the emitter 9 with fixation in a given position. With a taper of 1:30, a working clearance is formed when the collector is axially displaced by 4 mm.

 Power installation works as follows.

 The heat released in the active zone 5 is transmitted by radiation to the heat-absorbing surfaces (evaporation zone) of the high-temperature heat pipes 8, and is transferred along their axis to the heat-removing (condensation zone) surfaces that are emitters 9 of the thermionic converters of the electric generator 2. This heat heats up the structure even during operation The temperatures of the electrodes are used to generate electricity. The unconverted part of the heat is supplied to the refrigerator-emitter 4 and discharged into space. The presence of a heat-insulating casing 6 provides indestructibility of the core in various emergency situations, in particular during unauthorized descent from the orbit of an artificial Earth satellite.

In support of the proposed design, we tested the model of the energy module, consisting of a high-temperature molybdenum heat pipe with lithium and a cylindrical thermionic converter in which heat was supplied to the emitter at 1500 ^o C. The model worked 4000 hours before the scheduled shutdown [5]. At present, life tests of the end thermionic converter with a high-temperature lithium heat pipe at a temperature of 1500 ^o C are underway. A resource of 2500 hours has been reached, tests are ongoing.

 It should be noted that the proposed scheme of the power plant and thermionic converters is cheaper and more technologically advanced in comparison with the known designs, it allows separate processing of its elements, consisting of low-material modules, requires a limited amount of bench devices.

Sources of information
1. AIAA Paper 76-1041. EV Pawlik, WM Phillips. A Nuclear Electric Propulsion Vehicle for Planetary Exploration. TM Hsieh and WM Phillips. An Imporved Thermionic Power Conversion Systems for Space Propulsion - Proc. 13th IECEC, 1978, 1917-1922.

 2. W. M. Phillips, M. C. Ectabrook, T. M. Hsieh. Proc. 11th Intersoc. Energy Conversion Engineering Conf, 1976, 1487-1493. Per. - Nuclear thermionic power plant (NTB - I sg - 34).

 3. D. R. Koenig, W.A. Renken, E.M. Salmi. Heat Pipe Reactor for Space Applications. AIAA Paper 77-491, 7 pp. W.M. Phillips, M.C. Estabrook, T.M. Hsieh. Proc. 11th Intersociety Energy Conversion Engineering Conference, pp. 1483-1493 (769256).

 4. J.E. Mondt, C. Stapfer, T.M. Hsieh. Nuclear Power Source for Electric Propulsion. AIAA Paper 79-2088. (prototype).

 5. Evtikhin V.A., Lyam A.L. et al. Creation and testing of a demo module. NTO MK / 1192 NPO "Red Star", 1986.

Claims (1)

 A space nuclear power plant containing a nuclear reactor with a high-temperature core and thermal insulation housed in a metal casing, a modular thermionic emission generator in the form of a package of modules of thermionic converters with a high-temperature heat pipe, the evaporation zone of which is immersed in the reactor core, and a thermionic converter is installed in the condensation zone with shaped medium temperature heat pipe for heat transfer to the refrigerator-emitter, refrigerator a holder made of finned medium temperature heat pipes, their number being equal to the number of modules, characterized in that the core insulation is made in the form of a set of pyrographite or carbon composite material crucible pins fixed together by carbon pins so that the axis of low thermal conductivity is perpendicular to the outer surface of the insulation, the evaporation zone of high-temperature heat pipes is placed in the channels of the active zone with a guaranteed 2 - 5 mm gap, emitters t thermionic converters are combined with the outer wall of the high-temperature heat pipe in the condensation zone, and the collectors are combined with the shaped medium-temperature heat pipe without case heat-conducting electrical insulation, the interelectrode electrical insulation of thermionic converters is made in the form of a shunt, consisting of a package of thermoelectric thermoelectrics inserted into the coaxial metal electrodes and thermoelectric electrodes welded together, emitter and collector thermionic converters The plugs are made in the form of tapered bushings ground to each other with a clearance of 0.1 - 0.2 mm, spacer bushings with bearings made of the material of the emitter current collector are installed between the emitter current output and the collector, resting on the electrically insulated surface of the current lead, the bearings are fastened to the bushings using pins.