RU2215244C1 - Off-line survival system - Google Patents

Abstract

FIELD: heating, water supply, and power supply systems. SUBSTANCE: system has free-of-charge energy source, device communicating with energy storage that converts its energy into electrical energy, and device converting stored energy into heat and electrical energy supplied to entities being serviced. Energy storage is made in the form of two heat storages one of them being low-temperature liquid storage and other one, high-temperature solid state storage. First storage communicates through liquid pipeline with house heating and hot-water supply system and second one incorporating heat engine of power generator drive that has heater and cooler communicates at least with housing power system. EFFECT: enhanced environmental friendliness and reduced cost of off-line ground- based power supply. 13 cl, 2 dwg

Description

 The invention relates to autonomous life support systems of terrestrial, mainly autonomous objects - residential buildings, industrial and public buildings, individual autonomous settlements, towns.

 The proposed AFL is designed to provide heat, hot water and electricity with a stabilized frequency and voltage to the above objects, mainly due to the use of easily accessible and widespread sources of free energy - wind and solar radiation.

 Well-known vortex power plants with devices for converting wind energy into electrical energy stored in electric batteries associated with devices for converting this energy into electricity with stabilized parameters, which can naturally be used for electricity and heat supply to buildings and other objects - analogue (1).

 The advantage of such wind turbines is their operability at the most frequently occurring low wind speeds of 4-8 m / s, while paddle wind turbines are effective at rarely occurring wind speeds of 10-20 m / s. At speeds below the specified limits, there are problems of electric conversion and the use of generated electricity into energy suitable for use by consumers, which reduces the possibility of full use of wind energy and the use of these plants for energy supply of ASL.

 An autonomous life support system for autonomous objects is also known, for example, the ASJ of the MIR space station, which contains solar panels and devices for converting the energy received into electricity with parameters sufficient to charge the batteries, which in turn are connected to devices for converting accumulated electricity into electricity with parameters necessary for the operation of the equipment of this autonomous facility and its heating and hot water systems - prototype (2).

 Common disadvantages of the analogue and the prototype are: the need to convert all the energy generated by gift sources into electrical energy with parameters suitable for charging electric batteries, the volume (capacity) of which becomes somewhat unacceptable with any high unevenness in energy supply or with the demand for high reliability of energy supply; the need for the subsequent conversion of the accumulated electric energy into heat energy used for heating and hot water supply; the need to convert a large part of the energy stored in the electric accumulators into electricity with a frequency, for example, 50 Hz and a voltage of 220/380 V in a three-phase power supply network, or to create and establish mass production of a new complex of electrical equipment for heating, cooking and facilitating domestic work, electric pumps, fans, electric elevators, etc., working on direct current with a voltage of 12 or 24 V; the need for regular maintenance of electric batteries; the need to ensure environmentally safe operation and regular replacement of electroaccumulators, for example, once every 2-3 years with subsequent disposal, which is a serious technical, environmental and economic problem, especially when creating a housing insurance housing for a large number of people. These shortcomings are especially evident when creating an AFL for already existing ground facilities, such as high-rise buildings, residential microdistricts, villages, etc., for which the required volume of electric accumulators and the need to completely replace all electrical equipment (for the case of switching to constant voltage) practically impossible to create environmentally friendly, reliable and cost-effective AFL.

 The purpose of this proposal is the creation of an AFL, which makes it possible to eliminate the indicated drawbacks and thereby provide a practical opportunity to implement ground-based environmentally safe autonomous equipment with low operational energy supply costs and any energy consumption required for life support and an uneven energy supply from wind turbines that is arbitrarily high in real living conditions and solar panels.

This problem is solved due to the fact that in an autonomous life support system containing at least one source of free energy, the converter of this energy into electrical energy communicated with the energy accumulator, and devices for converting battery energy into thermal and electrical energy supplied to the serviced objects, according to this proposal:
- the energy accumulator is made in the form of at least two thermal accumulators: one is a low-temperature liquid, the second is a high-temperature solid-state, the first battery being hydraulically connected to the heating and hot water supply systems of buildings, the second to the heat generator’s drive machine, which is connected with a heater and a refrigerator, at least with the power supply system of buildings;
- low-temperature and high-temperature heat accumulators are equipped with electric heaters in communication with the energy converter of the gift source;
- the refrigerator of the heat engine is connected in heat to a low-temperature heat accumulator, for example, is located in it, and its heater is connected in heat to a high-temperature heat accumulator, for example, a gas heat exchange circuit;
- a high-temperature heat accumulator is located inside the low-temperature heat accumulator;
- a free energy source is made at least in the form of a vortex wind power installation with an electric energy converter;
- the heat engine is made working according to the Rankine cycle, its heater is made in the form of a steam generator in communication with a high-temperature heat accumulator by means of a gas coolant circulation circuit, the refrigerator is made in the form of a steam condenser hydraulically in communication with a low-temperature heat accumulator by means of a liquid heat-transfer circuit or by immersion in a heat medium low temperature heat accumulator;
- all electric energy converters of free sources of energy are connected to a common distributor of this energy, made with the possibility of priority supply of a high-temperature heat accumulator and a gas coolant circulation loop;
- the heat engine is additionally kinematically communicated with pumps and gas blowers for the circulation of coolants in the circuits of the coolant;
- the heater of the heat engine is equipped with a backup fuel, for example gas burner, source of heat energy, the heat engine and the generator are equipped with a device for stabilizing the frequency and voltage in the power supply network of buildings and auxiliary ACL drives, made with the possibility of its connection to the backup power supply system;
- the electric generator of the heat engine is equipped with a device for its synchronization in frequency, phase and voltage with a backup power supply system, made, for example, in the form of a central power grid, with the possibility of transferring surplus generated electricity to it;
- a low-temperature heat generator is communicated through a heat meter with at least one heat system with the possibility of both transferring excess heat energy into it and receiving additional heat energy from it;
- the high-temperature heat accumulator and the electric generator of the heat engine are configured to transfer heat and electric energy to external high-temperature heat accumulators located, for example, on mobile machines;
- high-temperature and low-temperature heat accumulators are made with the possibility of adjustable heat transfer from the high-temperature heat accumulator directly to the low temperature by means of an additional heat exchange circuit.

 Figures 1 and 2 give examples of the performance of ACL in the form of structural layout schemes, where it is indicated: UE-output electricity from converters of free energy sources, VE-energy of converters of free sources, sent to consumers of ACL for charging high and low-temperature heat accumulators with heat, SE -electric energy with stabilized parameters, for example 50 Hz, 380 V, generated by ASG devices due to the heat of a high-temperature heat accumulator.

 The proposed AFL consists of sources of wind energy, for example, in the form of a blade 1 (see figure 1) and / or vortex 2 wind turbines, the latter of which are rationally placed on the roofs of buildings. Wind turbines 1 and 2 are equipped with converters of wind energy into electrical energy, for example, electric generators 4, which in this AHS can be of any type (direct and alternating current of any frequency and voltage). AJ can also be equipped with solar panels (boards) 5 that generate electricity. These energy sources are connected through a switchgear 6, which can contain at least one small-capacity electroaccumulator, to at least two heat accumulators: a high-temperature solid-state heat accumulator 7 (via a gas heat exchange circuit containing a gas blower 8 and a gas electric heater 9) and a low-temperature thermal liquid (water) battery 10 (by means of electric heaters 11, for example, shadow type), as well as other consumers of electricity, which do not require stable power parameters for their functioning, for example, to an electric heater 12. The low-temperature heat accumulator is hydraulically connected to the heating and hot water supply systems of buildings 3 by means of pipelines 14 and 14 * connected to the circulation pump 13 with the possibility of controlling the flow rate, for example, according to the return temperature pipeline 14 *.

 The high-temperature heat accumulator 7 is in communication with a heat engine, for example, a steam engine operating according to the Rankine cycle, by means of a steam heater 16, a condenser cooler 17 and a condensate feed pump 18. The condenser 17 is in heat communication with a low-temperature heat accumulator, for example, due to a heat exchange circuit or behind the account of its placement directly inside the heat accumulator 10, filled with liquid, for example water, circulating in the heat accumulator by means of the pressure of the circulation pump 19. Thermal machine Inna 15 leads a three-phase alternating current generator 20 stabilized in frequency and voltage (e.g., 50 Hz, 220/380 V). Frequency stabilization in this example implementation is carried out by adjusting the number of revolutions of the shaft of the machine 15, for example, by the steam cutoff regulator 21. If necessary, the generator 20 is synchronized in phase with the connected external power supply network 22 and the revolutions of the machine 15 (for example, a volumetric steam engine) are finely tuned of the regulator 23. Generator 20 is connected through an electric distributor 24 to the power supply system of buildings 3, as well as to electric motors of pumps 13, 18, 19, 25, gas blowers 8, 26 and other consumers. Pump 25 provides the water supply to buildings 3 and their hot water supply systems. The gas blower 26 circulates the hot gas through the heat accumulator 7 for supplying it to external consumers, for example, the heat accumulators of mobile machines (not shown), which are periodically connected to the sockets 27 for charging with heat through an additional electric heater 28, which stabilizes and raises the temperature of the gas supplied to the required value when combined charging warmly to their circulation circuit. The power supply of the heater 28 can be carried out as a stabilized power supply (SE inputs), and directly from the distribution device 6 (VE inputs). The gas blower 26 can also be used to charge the heat accumulator 7 itself with heat when power is supplied to the electric heater 28 from a switchgear 6 or to pump heat into the heat accumulator 7 from an external high-temperature battery, for example, a mobile type when connected to the connectors 27. Gas blower 8 when brought from device 6 (inputs VE) or distributor 24 (inputs SE) is used to charge the battery 7 and / or supply heat to the steam generator 16 (by setting adjustable resistances in the circulation circuit - see drawing).

 The shaft of the steam engine 15 can be additionally kinematically connected with water circulation pumps and gas blowers, including 13, 14, 18, 19, 8, 24 to increase the reliability and efficiency of the ASL.

 Structurally, the high-temperature battery 7 can be located inside the low-temperature heat accumulator 10, see FIG. 2, or directly adjacent to it, which reduces heat loss, improves the overall dimensions of the energy accumulator.

 In the embodiment of FIG. 2, the pump 8 is adjustable, and an additional condensate pump 8 * is installed at its inlet. The pump 13 is also made submersible. The heating system of buildings 3 is combined with the internal cavity of the heat accumulator, in which an additional heat exchanger 29 and a heat meter 30 are installed to provide controlled heat exchange with an additional external circuit through hydraulic connectors 31. This embodiment allows, on the one hand, to supply heat to the heat accumulator 10 from an external heat network or to transfer it to this the system has excess heat, keeping records of it.

 The heat engine 15 can be executed by a Stirling cycle or another external heating cycle, but in all cases its heater is located in the battery 7 or hydraulically connected to it by a heat exchange circuit, and its refrigerator is combined with a low temperature heat accumulator 10 by a common heat exchange circuit, i.e. essentially the refrigerator and the battery 10 are a single unit. This embodiment ensures the complete utilization of thermal energy lost due to the imperfection of the heat cycle of the heat engine, since all these losses are transferred to the heat of the low-temperature battery 10 and are subsequently useful for heating buildings 7.

 The described AFL works as follows.

 In the presence of wind, paddle and whirlwind wind turbines (the body of a whirlwind wind turbine is rationally covered with solar panels and / or coated with heat-absorbing sun rays to create additional traction that increases the speed of the wind flow supplied to the turbine) are optimal, respectively, at high and low wind speeds, as well as solar panels generate electrical energy supplied to switchgear 6 (UE inputs), which is transmitted to electric heaters - HE outputs, providing first of all, heating the high-temperature heat accumulator to a predetermined temperature, for example, according to the readings of the temperature sensor 32, see Fig. 1, connected to the information inputs 33 of the device 6 and to power the start-up process of the heat engine 15. Next, the device 6 connects its power outputs heating the low-temperature heat accumulator 10. In this case, the electric generator 20, driven by the machine 15, already generates an alternating current with stabilized parameters - outputs / inputs of the solar cells, which allows full chit power supply electric power supply of their own needs and buildings 3.

 The heat released in the condenser 17 also goes to heat the heat accumulator 10. When the pump 13 and 25 are turned on, heat and water supply to the buildings are provided with cold and hot water.

 In critical situations (prolonged absence of wind and sun), power and heat supply to buildings 3 can be ensured by burning fuel in a steam generator 16, for example, stored in gas cylinders 34. In this case, the heat generated by the condenser 17 is transferred to the heat exchanger 35 of the heat supply system due to their location in the general heat exchange section 36 of the battery 10. Heating of the heat supply system of buildings 3 is additionally carried out in an additional heat exchanger 37 due to the heat of the gases leaving the steam generator and combustion gas when the valve 38 is opened, the combustion process is controlled by controller 39 to couple the outlet temperature of the steam generator. Naturally, additional conventional fuel water heaters can be used to maintain the temperature in the heat supply system (pipelines 14 and 14 *).

 At the initial start-up of the AFL, the start of the gas blower 8 and the feed pump 18 can be carried out from an electric accumulator, for example, as part of a device 6 or due to an external electrical system 22, associated, for example, with a diesel power station.

 External heat consumption systems can be connected to a low-temperature battery 10 through hydraulic connectors 31, to a high-temperature battery 7 via hydro (gas) connectors 27, and an external power consumption system through the outputs of the electric distributor 24.

 In critical situations, the reverse process can also be carried out through these connectors - replenishment of the ACL with energy from external sources.

 The AFL data at their locations (deployment) can provide heat to the high-temperature heat accumulators of special vehicles charged with heat, for example, with a steam-powered transmission drive with steam generators supplied with heat from a high-temperature heat accumulator carried by a mobile machine and a backup fuel heat generator. Moreover, the heat meter 40 installed on the connectors 27 allows you to control and take into account the amount of heat released to the vehicle.

 For the purposes of the controlled transfer of heat from a high-temperature heat accumulator to a low-temperature one, for example, in cases of need to increase the heat energy output for heating, the high-temperature heat accumulator by an additional heat exchange circuit with a heat exchanger 41 (for example, located directly in the heat accumulator 10) can be connected in heat to the high-temperature heat accumulator 26 through a gas and an electric heater 28 with the ability to control heat transfer, for example, by an adjustable valve 42.

 In general, the proposed NLA practically makes it possible to provide the area of its deployment with heat and electric energy, including energy costs for transport communications in the NLA coverage area, with complete environmental safety of the environment and the human living area in areas where the capacities of these gift sources exceed those required for human energy costs.

 Since the operating costs for the construction, maintenance and repair of thermal batteries are relatively small compared to the costs for the construction and maintenance of a residential complex, this NLA can be widely used. It is important that with the introduction of an AFL, the costs of building residential facilities are also significantly reduced, since the costs of laying underground utilities for various purposes and connecting external power lines (electricity, heating) are sharply reduced.

 The most rational use of this AFL in the Far North, as well as for the livelihoods of autonomous, remote settlements, where the delivery of traditional fuel is difficult or costly.

Literature
1. Serebryakov R.A., Biryuk V.V. Whirlwind wind power installation. // Space rocket technology. Ser.XII, Samara, 2000, p. 48-73.

 2. Technical documentation for the MIR space station - prototype.

Claims (13)

 1. Autonomous life support system (LSS) of buildings and other objects, containing at least one source of free energy, a converter of this energy into electrical energy in communication with the energy accumulator, and a device for converting battery energy into thermal and electrical energy supplied to the serviced objects, characterized in that the energy accumulator is made in the form of at least two thermal accumulators: one is a low-temperature liquid, the second is a high-temperature solid-state, and the first kkumulyator fluidly communicates with the heating and hot water supply system of buildings, the second - a heater and a refrigerator comprising a heat engine drives an electric generator, reported at least a building's electrical system.  2. ASG according to claim 1, characterized in that the low-temperature and high-temperature heat accumulators are equipped with electric heaters in communication with the energy source energy converter.  3. ASJ according to any one of paragraphs. 1 and 2, characterized in that the refrigerator of the heat engine is in heat communication with a low-temperature heat accumulator, for example, is located in it, and its heat heater is in communication with a high-temperature heat accumulator, for example, a gas heat exchange circuit.  4. AJ according to any one of paragraphs. 1-3, characterized in that the high-temperature heat accumulator is located inside the low-temperature heat accumulator.  5. AJ according to any one of paragraphs. 1-4, characterized in that the gift of energy is made at least in the form of a vortex wind power installation with an electric energy converter.  6. AJ according to any one of paragraphs. 1-5, characterized in that the heat engine is designed to run according to the Rankine cycle, its heater is made in the form of a steam generator communicated with a high-temperature heat accumulator by means of a gas coolant circuit, the refrigerator is made in the form of a steam condenser hydraulically connected with a low-temperature heat accumulator by means of a liquid circuit coolant or due to its immersion in the coolant of a low-temperature heat accumulator.  7. AJ according to any one of paragraphs. 1-6, characterized in that all the electric energy converters of gift sources are connected to a common distributor of this energy, made with the possibility of primary supply of high-temperature heat storage and gas circulation circuit.  8. The AFL according to any one of paragraphs. 1-7, characterized in that the heat engine is additionally kinematically connected with pumps and gas blowers for circulating coolants in the circuits of the coolant.  9. The AFL according to any one of paragraphs. 1-8, characterized in that the heater of the heat engine is equipped with a backup fuel, for example, gas burner source of heat energy, the heat engine and the generator are equipped with a device for stabilizing the frequency and voltage in the power supply network of buildings and auxiliary drives of the ACL, made with the possibility of its connection to the backup power supply system .  10. The ACL according to claim 9, characterized in that the heat generator’s generator is equipped with a device for synchronizing it in frequency, phase and voltage with a backup power supply system made in the form of a central power grid, with the possibility of transferring excess electricity to it.  11. The AFL according to any one of paragraphs. 1-9, characterized in that the low-temperature heat generator is communicated through a heat meter with at least one heating system with the possibility of both transferring excess heat energy into it and receiving additional heat energy from it.  12. The AFL according to any one of paragraphs. 1-11, characterized in that the high-temperature heat accumulator and the electric generator of the heat engine are configured to transfer thermal and electric energy to external high-temperature heat accumulators located, for example, on mobile machines.  13. The AFL according to any one of paragraphs. 1-12, characterized in that the high-temperature and low-temperature heat accumulators are made with the possibility of adjustable heat transfer from the high-temperature heat accumulator directly to the low temperature by means of an additional heat exchange circuit.

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