RU2724206C1 - Autonomous space power plant - Google Patents

Abstract

FIELD: power engineering.SUBSTANCE: invention relates to power systems based on direct conversion of thermal energy to electric power and can be used, in particular, for power supply of lunar base. Proposed plant comprises two closed circuits of liquid metal heat carrier (LMHC). Hot LMHC circuit includes at least one solar collector connected by LMHC pipelines with in-series installed heat exchanger of hot junction of thermoelectric converter (TEC) and circulating pump. Heat removal circuit includes cold junction heat exchanger TEC connected by LMHC pipelines with cooler-radiator and circulating pump. Electrical outputs of TEC are connected to accumulators and power consumers.EFFECT: stable power supply of equipment and personnel in extreme conditions of external environment, in particular, on lunar base.1 cl, 1 dwg

Description

Technical field

The invention relates to space power systems (IES), based on the direct conversion of thermal energy into electrical energy, to provide the lunar base with electricity.

State of the art

Known "Autonomous orbital power plant" (US Application 20100264656), which receives and directs solar radiation as an energy source for heating the working fluid of a Rankin engine used to power an electric energy generator, and creates a pseudogravitational environment in which there is a floating force. Due to the use of reflectors and alignment of the power plant with a source of solar radiation, the low temperature of outer space is used as a heat sink to condense the vapor back into the liquid phase. The working fluid (for example, water) is under pressure and is heated to an increased evaporation point, and the expansion of superheated steam is captured by rotation of the power plant in microgravity. Steam is used to turn the generator electric turbine and the casing turbine against rotation. The steam is cooled by conductive heat transfer to a coolant (e.g. liquid ammonia), which emits excess heat to outer space, and returns the working fluid to the liquid phase for recirculation.

The disadvantage of this power plant is the low reliability resulting from the use of machine-based energy conversion.

The well-known "Space power plant with machine-based energy conversion" (RF Patent IZ No. 2586797) which relates to objects of power engineering. In a space power plant, a mixer is installed in the pipeline between the heat source and the turbine, connected by an additional pipeline, including an inductor controlled by an electric drive, with a pipeline between the compressor output and the input of the heat transfer path of the heat exchanger-recuperator. The invention allows to improve the resource characteristics of a power plant by reducing its operating time at a maximum temperature of the working fluid at the turbine inlet while reducing energy consumption.

The disadvantage of this power plant is its low reliability as a result of the use of machine energy conversion.

The well-known "Space solar energy system for thermochemical processing and production of electricity" (US Application 20080283109), which receives energy from an energy beam using satellites that intercept the energy of the sun using solar panels, form an energy beam and transmit it to the lunar or terrestrial surface, or to the rectenna receiving system (https://altenergiya.ru/sun/rektenna-altemativa-solnechnym-panelyam.html), concentrators, thermochemical systems, systems for the production of fuels and other chemicals.

The disadvantage of this energy system is the low reliability of the system due to the complexity of the implementation of the systems of reception and transmission of the energy beam.

Known nuclear power plant "BUK" (NPP) (https://helpiks.org/6-77727.html), designed to power the load placed outside the atmosphere of the earth which consists of a nuclear reactor, a pipeline of liquid metal circuit, radiation protection, compensation tank liquid metal circuit, refrigerator-emitter, electromagnetic pump of conductive type, thermoelectric generator, power frame design. The energy in it is generated due to the temperature difference between the hot and cold junction of the thermoelectric generator, which is obtained as a result of heating the thermoelectric generator from the hot junction from the reactor and cooling the thermoelectric generator from the cold junction using a liquid metal coolant. The excess heat resulting from cooling is carried out by radiation into outer space using a refrigerator-emitter.

The disadvantages of this power plant are:

1. Thermal energy is generated using a fast neutron nuclear reactor, the radiation from which is dangerous for inhabited lunar stations and for equipment.

2. To neutralize the negative effects of radiation, protection is used, which significantly complicates the design and creates problems with delivery outside the earth's atmosphere.

3. It has a limited resource due to the non-renewability of the energy used to heat the thermoelectric generator.

4. The lack of an energy storage system, which limits the load parameters, namely, does not allow the use of dynamic load, compensate for reactive power and inrush currents.

Disclosure of invention

The technical problem to which the claimed invention is directed is to provide the necessary power and energy of an autonomous life support system for equipment and personnel in extreme environmental conditions of the lunar base, as well as the stability of its operation.

For this, an autonomous space power plant is proposed that contains a closed loop of a hot liquid metal coolant, including at least one solar collector connected by pipelines to a liquid metal coolant with a thermoelectric converter hot junction heat exchanger and a circulation pump in series, a closed heat removal circuit including a cold heat exchanger junction of the thermoelectric converter, connected by pipelines with a liquid metal coolant with a fridge-emitter and a circulation pump, while the hot junction heat exchanger of the thermoelectric converter and the cold junction heat exchanger of the thermoelectric converter are adjacent to the thermoelectric generator, the electrical outputs of which are connected to energy storage devices and consumers.

In addition, an electrochemical storage battery, or a mechanical storage system, or supercapacitors can be used as energy storage devices.

In the installation, a solar collector is used as an energy source, in which the liquid metal coolant is heated from the energy of the sun and sent through a closed liquid metal circuit pipe to the hot junction heat exchanger of the thermoelectric converter, from where it is directed back to the solar collector by means of a circulation pump. In this case, the thermoelectric generator generates energy due to the temperature difference, which is ensured by the circulation of the liquid metal coolant in a closed loop of heat removal. The energy generated by the thermoelectric generator is directed to the consumer of electricity and to the auxiliary load, which can serve as an electrochemical storage battery, a mechanical storage system, etc.

Brief Description of the Drawings

The invention is illustrated by the figure.

The figure shows a diagram of an autonomous space power plant, where the numbers indicate:

1. Solar collector

2. The pipeline hot liquid metal circuit

3. Hot Junction Thermoelectric Converter Heat Exchanger

4. The circulation pump

5. Pipeline for hot liquid metal circuit

6. Thermoelectric Converter

7. Thermoelectric converter cold junction heat exchanger

8. The pipeline of the cold liquid metal circuit

9. Refrigerator - emitter

10. The pipeline of the cold liquid metal circuit

11. Circulation pump

12. Energy storage

13. Electricity consumer

Implementation and implementation examples

A closed circulation circuit with hot liquid metal coolant includes: a solar collector 1, through a pipe 2 connected to a heat exchanger 3, which is connected to a pipe 5, a circulation pump 4 and to a solar collector 1. The heat exchanger 3 is connected to the thermoelectric converter 6 from the hot junction side.

The thermoelectric transducer 6 is connected to the heat exchanger 7 from the cold junction. The heat exchanger 7 through a pipe 8 is connected to a refrigerator-emitter 9, which is connected through a pipe 10 with a circulation pump 11 and a heat exchanger 7, forming a closed circulation circuit for heat removal. The thermoelectric converter 6 is connected via conductive lines with the energy storage 12 and the consumer 13.

During a lunar day, the energy of the sun heats the liquid metal coolant, which is located in the solar collector 1, to the required temperature, then the coolant passes through the pipeline of the hot liquid metal circuit 2 to the heat exchanger of the hot junction of the thermoelectric converter 3, passing through the heat exchanger from top to bottom, the liquid metal coolant enters the pipeline 5, then, through the circulation pump 4, it flows back into the solar collector 1 for heating. The hot junction heat exchanger of the thermoelectric converter 3 tightly adheres to the hot junction of the thermoelectric converter 6 producing its heating. On the cold junction side of the thermoelectric converter 6, the cold junction heat exchanger of the thermoelectric converter 7 is tightly fitted, in which the liquid metal coolant is located, which, in turn, enters the refrigerator-emitter 9 through the pipe 8, from where it enters the cold junction through the pipe 10 and the circulation pump 11 thermoelectric converter 7, carrying out its cooling. In the thermoelectric converter 6, due to the formed temperature difference, electricity is generated, which is transmitted through the conductive lines to the load-consumer 13. During the period when the generated energy is more than necessary for the load, the excess energy is directed to the drive 12, which can be used as classic batteries , supercapacitors or mechanical energy storage systems. The flow and temperature sensors are located in the pipelines 5 and 10, as well as at the inputs of the exits of the heat exchangers 3 and 7, and the refrigerator-emitter 9 is not shown in the figure. Eutectic is used as a heat carrier.

Thus, an autonomous space power plant produces the energy necessary for the functioning of the lunar station during a lunar day, and its excess accumulates for work during a moonlit night, which is necessary for the stable and reliable operation of the lunar station.

Claims (2)

1. An autonomous space power plant containing a closed loop of a hot liquid metal coolant, comprising at least one solar collector connected by pipelines to a liquid metal coolant with a thermoelectric converter hot junction heat exchanger and an electromagnetic pump connected in series, a closed heat dissipation circuit including a cold junction thermoelectric converter heat exchanger connected by pipelines with a liquid metal coolant with a refrigerator-emitter and a circulation pump, while the hot-junction heat exchanger of the thermoelectric converter and the cold-junction heat exchanger of the thermoelectric converter are adjacent to the thermoelectric generator, the electrical outputs of which are connected to the energy storage device and consumer. 2. Installation according to claim 1, characterized in that the electrochemical storage battery, or the mechanical storage system, or supercapacitors can be used as energy storage devices.

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