Patent Number: 039869253
Section: claims

1. Power plant including nuclear reactor means, comprising: a plurality of similarly constructed units, each unit including a portion of the nuclear reactor, including nuclear fuel elements for developing thermal energy for the unit, each unit further having an individual, closed loop circulation path for liquidous alkaline metal as working and cooling liquid, passing through the reactor portion of the respective unit in heat exchanging relation therewith, there being a separate circulation path of alkaline metal in each unit, and a separate MHD-generator included in the respective circulation path for and of each unit accordingly, the alkaline metal passing through and serving as working fluid for the respective MHD-generator;  the units of the plurality disposed in a bundle so as to be located in the vicinity to each other so that the several portions of the reactors are intercoupled through the neutron flux as established by each portion, the bundling providing inner units and outer units of the bundle;  circuit means connected to the MHD-generators of the units, for connecting the respective electrical outputs of the generators in parallel so that the individual units operate as load wherein the MHD-generator of a unit draws energy from the circuit means and pumps working fluid through the unit, or as power producing unit, the outer units normally operating as pumps; and  means defining an air circulation path coupled to the closed loop circulation paths for working fluid of the units of the plurality ahead of the respective returns thereof to the nuclear reactor, for extracting therefrom residual thermal energy.  causing alkaline metal to circulate in each circulation path in heat exchange relation with the respective reactor portion of the unit and as working fluid for and in the respective MHD-generator;  disposing the units in a bundle so as to be located in the vicinity to each other so that the several portions of the reactors are intercoupled through the neutron flux as established by each portion, the bundling providing inner units and outer units of the bundle;  electrically interconnecting electrical outputs of the MHD-generators of the units in parallel;  operating the inner units of the bundle as electrical power producing units; and  operating the outer units as pumps by drawing power from the inner units and causing the respective MHD-generator to pump the working fluid through the respective units.  a plurality of heat exchange fluid paths and circulations through the nuclear reactor, each path traversing different portions of the reactor;  a plurality of MHD-generators each included in one of the circulations and operating with the same heat exchange fluid of the respective circulation that traversed one of the portions of the reactor, the heat exchange fluid in each circulation by alkaline metal;  the different portions of the reactor having a common neutron flux distribution;  some of the MHD-generators operating as pumps at relatively low thermal energy production in the respectively associated nuclear reactor portion;  the remainder of the MHD-generators operating as electric power generators at relatively high thermal energy production in the respectively associated nuclear reactor portion; and  circuit means interconnecting the MHD-generators so that the ones operating as generators drive the ones operating as pumps, the remainder of electric power generated being usefull electric output. 2. Power plant as in claim 1, the units of the plurality each having elongated extension, the nuclear reactor portion being on one end of each unit, an air-alkaline heat exchanger disposed close to the other end of each unit, the units disposed parallel to each other, the nuclear reactor portions aligned parallel to a plane transverse to the elongated extension of the units. 3. Power plant as in claim 1, the units of the plurality stacked in a bundle, there being outer ones and inner ones, the plant including control means connected to the units for normally operating the inner units for production of power, the outer units as disposed around the inner units establishing power reserve units, normally operated as loads, the control means operating the later units also for production of power upon increase of power demand. 4. Power plant as in claim 1, there being a honeycomb support structure for the units of the plurality. 5. Power plant as in claim 1, the air circulation path including a compressor and a turbine coupled for driving the compressor, the compressor sustaining air circulation for heat exchange with the alkaline metal, the turbine receiving the heated air. 6. Power plant as in claim 1, each unit including a compressor, a turbine, and a heat exchanger, the heat exchanger having primary circulation that is included in the closed circulation of alkaline metal in the unit, having secondary circulation of air, circulated by the compressor and driving the turbine, the turbine driving the compressor. 7. Power plant as in claim 1, the air circulation path including all units of the plurality, there being a sea water desalination plant connected to receive the heated air from all units as principal heating source. 8. Power plant as in claim 1, including common control means, individually controlling the nuclear reactor portions in accordance with a particular program and in dependence upon demand for electrical power. 9. Power plant as in claim 1, the program causing the control means to operate some of the units for production of electrical energy, others of the units are operated as load, some of the latter units operated for production of energy upon increase of demand. 10. Method of generating electrical energy, comprising the steps of providing a plurality of similarly constructed units, each unit including a portion of the nuclear reactor, including nuclear fuel elements for developing thermal energy for the unit, each unit further having an individual, closed loop circulation path for a cooling and working fluid, and a separate MHD-generator in the respective circulation path for each unit; 11. A method as in claim 10, and including the step of changing the number of units operated as power producing units vs. the number of units operating as pumps. 12. Power plant including a nuclear reactor comprising: 13. Power plant as in claim 12, wherein the reactor is physically subdivided into portions, the portions being physically mounted together with the respective MHD-generator in a modular construction of similar units, each composed of a reactor portion, and MHD-generator of the plurality and the circulation of alkaline metal. 14. Power plant as in claim 12, and including an additional circulation common to all units and having air coupled in heat exchange relation to the alkaline circulations of the units prior to return thereof to the respective nuclear reactor portion.