RU2615559C1 - Mobile multifunction independent double-caps bathing furnace - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: mobile multifunction independent double-caps bathing furnace contains the combuster, heating tunnel, the first cap, the open heater chamber, chimney, the double walls with possibility to fill the space between them with water, the pipes with valves for the cold water supply and hot water discharge, located on the outer wall of the furnace, the pipe with a tap for vapour release, the second cap, formed by the inner cylinder of the open heater chamber and outer surface of the chimney base. At that the first cap is disposed coaxially to the second cap. The furnace additionally contains the Stirling engine, vapour-water flexible pipe to supply vapour into the sweat bath or to the open chamber of the heater or the chamber for clothes vapouring, gas burner and cylinders with reducers, serving as the tanks for the storage and use of the compressed or liquefied gas, heat receiving cylindrical chamber for heat transfer from the combustion chamber of the furnace to the device for heat dissipating and transferring to the heating chamber of the Stirling engine, the flywheel of which is kinematically connected to the electric generator, charging the accumulator batteries unit, the Stirling engine cooling system, the film photovoltaic modules, that are configured to generate power, the thermoelectrical heater with temperature sensor, installed in the lower part of the cavity between the double walls of the furnace and providing to heat the water from the produced and stored electric power, using the Stirling engine and film photovoltaic modules, charge-discharge controller of the accumulator battery unit, the inverter, which serves to convert the DC voltage of the accumulator battery unit into the AC voltage to power thermoelectrical heaters, adjustable mechanical overpressure valve, the additional tank of the constant water level in the cavity between the furnace walls. At that the pipe with a tap for vapour release and adjustable mechanical overpressure valve located at the upper ring of the furnace double walls, and a furnace tunnel is made movable.

EFFECT: versatility, mobility and independence, energy efficiency increase, control of the vapour temperature, power generation.

5 dwg

Description

The invention is a mobile multifunctional autonomous two-bell sauna stove (MMFADKBP), which uses wood or gas fuel, as well as a renewable energy source in the form of solar radiation, for sanitary and hygienic objects. The mobile multifunctional autonomous two-bell bathhouse is designed for steam and washing people, for hot water supply and heating of the bathhouse room, for hygienic treatment with superheated steam and drying of various clothes and objects both in stationary and field conditions, to maintain a positive temperature in the bathhouse room during time when there is no fuel combustion process. MMFADKBP can be used in bath and laundry plants, in individual, mobile saunas, in sports and fitness centers. The heat sources that ensure the operation of the MMFADKBP are any wood fuel, compressed or liquefied combustible gas, thermoelectric heaters that use the energy stored in rechargeable batteries, generated with the help of film photovoltaic modules (PFEM) and the electric generator of the Sterling engine or obtained from an industrial voltage mains. Moreover, solar cells use the energy of solar radiation, converting it into electricity, and the Stirling engine utilizes the heat of a two-bell sauna stove in the form of rotational motion, turning it with the help of an electric generator into electric energy. The mobility of a two-bell bathhouse consists in the possibility of moving it by carrying by one person inside the bathhouse or to the vehicle. Mobility is ensured by the low weight of both the two-bell sauna stove and the exhaust pipe used. This is achieved by the fact that the risk of burnout of the metal and welds is minimized. All structural elements have a low temperature load, thin-sheet metal is used for the manufacture of a bath furnace, so the furnace has a small weight. The versatility of a two-bell sauna stove is provided by the following features: soaring and washing people; sanitization of clothes by steaming in a special chamber and subsequent drying of these clothes in the room where the bath stove is installed; power generation through the use of film photovoltaic modules; utilization of the heat generated during combustion of the furnace using an electric generator driven by a Stirling engine, as well as maintaining a positive temperature in the bath room during the inter-bath season. Autonomy consists in the fact that the operation of the MMFADKBP is ensured by: firstly, the use of widely available various types of wood fuel; secondly, using compressed or liquefied gas in cylinders as fuel; thirdly, by using electricity received from film photovoltaic modules using solar radiation energy or from an electric generator driven by a Stirling engine that utilizes heat generated by a two-bell sauna stove, as well as from an industrial voltage mains.

The invention is known RU 2499957 C2 F24B 1/24 from 05/10/2013. An Kucenko water furnace, containing the main chimney, a furnace with a blower, over which a closed-type heater is placed, in the upper part of which holes are made for supplying water and removing water vapor, the walls of the water furnace are double with the possibility of filling the space between the walls with water or another coolant, while the outer walls of the water furnace are equipped with devices for supplying and removing coolant, while the water furnace is additionally equipped with a system for supplying air to the upper combustion zone of the first cap and an internal chimney, moreover, they are made in the form of a pipe and / or several pipes located parallel to the walls of the water furnace in such a way that the additional air supply system to the upper combustion zone in its lower part is located in the blower, and its upper part is located in the upper combustion zone of the first hood, an internal chimney in its lower part it is as close as possible to the furnace, and in its upper part it protrudes minimally above the surface of the first hood, and the main chimney is placed in the second hood so that its lower part is maximally close to the partition between the first and second hood, while the furnace is lined.

The disadvantage of this invention is the presence of a large number of internal chimneys, which complicate the design. In addition, in the lower part of the heater, stones will crack due to high temperature and turn into sand over time. It should also be noted that the known water furnace is not suitable for other types of fuel. Known invention RU 2005263 C1 F24B 1/24 dated 05/10/2013, a furnace containing a furnace, a blower, a tank for heating water, a chamber with stones in it, connected to the furnace pipe, a steam door, a chimney mounted above the camera, a vertical through a pipe passing through a chamber with stones. The disadvantages of this invention are the bulkiness of the design, the furnace does not provide upper combustion of firewood, the large metal consumption of the furnace design, it is not intended to use other types of fuel. Known patent No. 2055272 F24B 1/00 of 02/27/1996, a heating cooking stove related to bunker hood furnaces and containing a stove, shelves located above the stove, firebox, blower, lower tier. Moreover, the firebox and the lower tier are combined into a single space constituting the lower hood, while holes are made in the upper and lower zones of the inner wall of the lower hood and in the side inner wall of the blower. A disadvantage of the known invention is the possibility of its use only in stationary operating conditions, and vaporization is not provided at all.

Also known is a universal metal furnace, patent UA 92441 C2, А51Н 33/06, F24C 13/00, F24B 9/00 dated 10/25/2010, containing a furnace with a blower over which a stone container and an exhaust pipe are located, located between the container for stones and the inner wall of the furnace. The universal furnace has double walls filled with water, and the outer walls are equipped with taps for supplying cold water and disassembling hot water, as well as a crane, which is located in the upper part and serves to remove steam. A disadvantage of the known invention is that the location of the exhaust pipe between the stone container and the inner wall of the furnace divides the hood space of the universal furnace into two parts. This does not contribute to the maximum transfer of heat to stones and water located between the double walls. In addition, the design of the universal furnace does not allow the use of other alternative fuels. Closed-type furnaces are known in the art, for example, in a metal casing. Such furnaces are divided into three zones: the lower one serves as a furnace, the middle one is a heater, and the upper one is used to heat water. The internal surfaces in the furnace and heater zone are laid out with bricks (see I. Shulgin. You are building a bathhouse. Kiev: Urozhay, 1993, p. 82). Also known is the Mikhailov metal stove-heater (see ibid., 88). This furnace is welded from metal sheets, has two chimneys, one is used for the furnace, the other is used to produce carbon monoxide. This oven contains a blower, a stove and a pipe. These furnaces use a wood type of fuel, are difficult to operate, require serious fire-fighting measures, since they can be red-hot, installed only stationary, which does not correspond to the tasks set in the claimed invention. As a prototype, the invention RU 2499957 C2 F24B 1/24 dated 05/10/2013, water machine Kutsenko, as the closest in its technical concept and design, was adopted. The prototype and the claimed invention is a mobile multifunctional stand-alone two-bell bath stove, have the following common features: the bath stove is made in the form of a metal structure with double walls with the possibility of filling the space between them with water, the outer walls of the stove are equipped with taps for supplying cold and removing hot water, the furnace is equipped with a blower, a chimney pipe, a second hood formed by the inner cylinder of the sauna stove and the outer cylinder of the open chamber of the heater. Moreover, the second cap is located coaxially relative to the first colnak.

The aim of the invention is the creation of a mobile, multi-functional, stand-alone, economical to operate, environmentally friendly two-bell sauna furnace with increased efficiency, having the ability to control the temperature of the steam produced in a wide range and providing accelerated heating of the steam room. The mobile multifunctional autonomous two-bell sauna stove can be used autonomously both in stationary baths and in the field. New in the declared MMFADKBP is that it is additionally equipped with the following devices: a second hood of the furnace, located coaxially relative to the first hood; movable furnace tunnel; a superheater having highways with cranes and supplying steam directly to the steam room and (or) to the open heater chamber; a gas burner and cylinders with reducers serving as a reservoir for storing and using compressed or liquefied gas as another type of fuel; a heat-receiving cylindrical chamber for transferring heat from the combustion chamber of a two-bell bath furnace to a device for removing heat and further transferring this heat to the heating chamber of the Stirling engine, which with the help of an electric generator generates electricity to heat the bath during the inter-bath period, surpluses of this electricity accumulate in the battery pack ( BAKB); Stirling engine cooling system, integrated into the cold water supply network in a two-bell sauna stove; film photovoltaic modules that store electricity generated in the daytime at BAKB; thermoelectric heaters (TEN), built into the lower part of the cavity between the double walls of the two-bell sauna stove and used to heat water from the generated and stored electric energy using the Stirling engine and PFEM or from an industrial power grid; a special camera designed for steaming clothes and various items, while using the residual heat after applying the two-bell sauna for its intended purpose; the charge-discharge controller (KZR) BAKB, adjustable temperature sensor (DT); an inverter (INV), which is used to convert the DC voltage of the BACB to an alternating voltage of 220 V, 50 Hz, suitable for wide consumption; an open heater, which is located between the first and second caps and filled with heat-sensitive material, such as stainless steel waste or stones; adjustable mechanical valve of excessive steam pressure; a steam tap, which is located on the upper ring of the double walls of the two-bell sauna stove; a refill tank that maintains a constant water level in the cavity between the double walls of a two-bell bathhouse. Significant differences that are claimed in the invention, allow to obtain the following technical result: increased efficiency; providing multifunctionality, mobility and autonomy; generation of electricity during the operation of a two-bell sauna stove; and additional generation of electricity from solar radiation. It should be noted that the manufacturing technology of a two-bell bathhouse furnace does not require sophisticated technological equipment and special machines.

The essence of the design MMFADKBP shown in the following figures. In FIG. 1 shows a General side view of the bathhouse and MMFADKBP partially in section. In FIG. 2 shows a General view in section of a two-bell bathhouse furnace. In FIG. Figure 3 shows the design of a system for transferring heat from a two-bell bath furnace to a heating chamber and a cooling system for a Stirling engine heat exchanger. In FIG. 4 shows a top view of the furnace compartment and the stationary or field-based premises with a two-bell sauna stove located therein. In FIG. 5 shows a diagram of generation and supply of electricity to consumers. The mobile multifunctional autonomous two-bell sauna bath contains the following components. A two-bell sauna stove 1, installed in room 2 for washing people in stationary or field conditions, and the room in the field is a canvas tent 3 with double walls. The Stirling engine 4 with an electric generator 5 is located in the furnace compartment 6 of room 2, and the furnace compartment 6 is separated from the room 2 by a partition made of light non-combustible material (not indicated). Film photovoltaic modules 7 are installed on the roof 8 of room 2 or tents with double walls 3. A special chamber 9 for steaming clothes is installed indoors 2 or tents with double walls 3. A steam and water pipe 10, which serves to supply steam to a special chamber 9 for various steaming clothes and items. A pipe with a faucet 11 located in the lower part of the double-walled cavity 12 of the two-bell bath furnace 1, while a pipe with a faucet 11 serves to supply cold water to the double-walled cavity 12. The outer cylinder 13 two-bell bath furnace 1; the inner cylinder 14 of the two-bell bathhouse 1, the outer cylinder 13 and the inner cylinder 14 constitute a cavity 12 with double walls and the ability to fill and heat water. The outer cylinder 15 of the open chamber of the stove 16. Moreover, the stove 16 is coaxially inside the hood 2. The volume of the stove is formed by: the inner cylinder 17 of the open chamber of the stove 16, a pipe with a tap 18 for selection of hot water from the cavity 12 with double walls of a two-bell bath furnace 1, and the pipe with the crane 18 is located at a distance of 2 / 3H from the lower edge of the two-bell bath furnace 1, where H is the height of the two-bell bath furnace 1 (Fig. 1). A pipe with a faucet 19, which serves to supply steam from a double-walled cavity 12 to a room 2 or a double-walled tent 3. A standard refill tank 20 located so that the cold water level in a standard refill tank 20 matches the water level in the cavity 12 with double walls equal to 3 / 4H of the height of the two-bell bath furnace 1 (Fig. 1). The cooling jacket 21 of the heat exchanger 22 with the screw rib of the Stirling engine 4. The pipe 23 connecting the cooling jacket 21 of the heat exchanger 22 with the screw rib of the heating chamber of the Stirling 4 engine with a standard refill tank 20. The pipe 24 for supplying water from the cooling jacket 21 of the heat exchanger 22 with the screw rib of the engine Stirling 4 in the pipe with a valve 11 for supplying cold water to the cavity 12 with double walls. A pipe 25 for supplying water from a jacket 21 of a heat exchanger 22 with a screw rib of a Stirling engine 4 to a standard refill tank 20. A movable furnace tunnel 26 with a door 27. A hole 28 in the door 27 serves to pass air during the organization of the upper combustion of wood fuel, and when using compressed or liquefied gas for mounting a gas burner 29. Furnace space 30 of a two-bell sauna stove 1 for accommodating wood fuel or a gas burner 29 when using compressed or liquefied gas as fuel aza. Blown air 31, which provides air access to the combustion space 30 when using compressed or liquefied gas as fuel. The valve 32 of a gas burner 29. Gas cylinders 33 of compressed or liquefied gas. Reducers 34 gas cylinders 33 compressed or liquefied gas. Pipelines 35 of gas cylinders 33, intended for supplying gas to a gas burner 29 when using compressed or liquefied gas as fuel for a two-bell bath furnace 1. A cylindrical heat-receiving chamber 36, which is a metal cylinder embedded in the combustion space 30 of a two-bell bath furnace 1 (FIG. .). A heat-conducting cylindrical element 37 made of pressed chips of high-quality copper, placed inside a cylindrical heat-receiving chamber 36 (Fig. 4). Thermal insulation 38 of the outer part of the heat-conducting cylindrical element 37. The heating chamber 39 of the Stirling engine 4. An adjustable mechanical overpressure valve 40, the adjustable mechanical overpressure valve 40 and a pipe with a tap 19 for supplying steam from the double-walled cavity 12 are located on the upper cavity ring 41 12 with double walls. The second hood 42 of the bathhouse furnace 1, wherein the second hood 42 is formed by the inner cylinder 14 of the two-hood bathhouse 1, the outer cylinder 15 of the open heater chamber 16 and the inner surface of the ring 43 of the second hood 42. The first hood 44 of the two-hood bathhouse 1 is parallel to the second hood 42 and is formed the inner cylinder 17 of the open chamber of the heater 16, the outer surface of the chimney pipe 45 and the inner surface of the ring 46 of the first cap 44. The chimney pipe 45 may consist of a set of several straight and bent elbows (not about signified) which are drawn according to the removal of bath dvuhkolpakovoy furnace 1 from the opening in the room for bathing persons 2 and outputs the products of combustion in the combustion air through the open floor or wall. Moreover, the chimney pipe 45 is located in the geometric center of the two-bell bath furnace 1. The inner pipe 47 is located in the zone of the first bell 44. The bottom 48 of the inner pipe 47. The bottom 49 of the two-bell bath furnace 1. The cold water supply check valve 50 installed at the outlet of the cooling jacket 21 Stirling engine 4. Thermoelectric heaters (TEN) 51, in the amount of one or more, built into the lower part of the cavity 12 with double walls. Battery Pack (BAKB) 52; charge-discharge controller (KZR) 53. Inverter (INV) 54. Infrared heaters 55. Electronic control panel 56 (EPU). The claimed mobile multifunctional autonomous two-bell bathhouse furnace operates in three modes. Pre-bath furnace 1 is installed in room 2 or in a tent with double walls 3. The first mode. Two-bell bathhouse 1 does not function as intended. Film photoelectronic modules 7, located on the roof 8 of room 2 or in a tent with double walls 3, generate electricity in the daytime, which is stored through the KZR 53 in BAKB 52 (Fig. 5), and the PFEM 7 is constantly connected to KZR 53, which controls and provides the accumulation of electricity in BAKB 52, the latter are connected to the inverter 54, issuing consumers an alternating voltage of 220 V with a frequency of 50 Hz. The second mode is the main operating mode of the MMFADKBP for its intended purpose, which is as follows. The wood fuel is loaded into the furnace space 30 without installing a movable furnace tunnel 26. After the wood fuel is loaded, the movable furnace tunnel 26 is put in place, which simplifies the operation of the two-bell sauna furnace 1. The movable furnace tunnel 26 easily compensates for the possible different thicknesses of the partitions between room 2 and the furnace compartment 6. After loading wood fuel into the furnace space 30 and installing the furnace tunnel 26, the door 27 closes, air through the hole 28 enters the top the current space 30. The cold water supply valve 11 opens in the double-walled cavity 12 of the two-bell bath furnace 1. In this case, the water through the standard refill tank 20, through the pipe 23 enters the cooling jacket 21, the heat exchanger 22, the heating chamber 39 of the Stirling engine 4 The water passes along the surface of the helical ribbing of the cooling jacket 21, cools the air or any inert gas located in the inner cavity of the heating chamber 39, which ensures the stable operation of the Stirling engine 4. Further from this cooling 21 ubashki already heated water through the check valve 50 enters the cavity 12 with the double walls of bath furnace 1 and fills it to the level 3 / 4H height of bath furnace 1 (FIG. one). It is known that the process of vaporization in a closed volume is accompanied by an increase in steam pressure in the double-walled cavity 12 of the two-bell bathhouse 1. Therefore, the use of the check valve 50 prevents the ingress of hot water through the pipe with the open valve 11 located in the lower part of the cavity 12 of the bathhouse 1 a cooling jacket 21, a heat exchanger 22 with a screw rib of the Stirling engine 4, and then through pipelines 24, 25 to the standard refill tank 20. It should be noted that the standard refill tank 20 and the cavity b 12 work on the principle of communicating vessels. Then the loaded wood fuel is ignited from above. The hot air heated in the furnace space 30 enters the upper part 42 of the second and first 44 caps of the two-bell sauna stove 1, where it is located for a long time and gives off heat to the water located in the cavity 12 and stones located in the open chamber of the heater 16. In this case, the pressure is hotter than the air in the first hood 44 and the second hood 42 grows, and the cooled air is forced out, goes down and together with the hot flue gases enters the second hood 44 of the two-bell stove 1. In the second hood 44, the hot flue gases also heat the stone and located in the open chamber of the heater 16. As heat accumulates in the first 41 and second 43 caps, pressure increases and when the pressure in the second 42 and first 44 caps is 1.10-1.15 times higher than atmospheric pressure, the exhaust flue gases through a chimney located in the geometric center of the bath furnace 1. The exhaust of these gases equalizes the pressure in the hoods 42, 44 with atmospheric pressure, this completes the exhaust, then the process is periodically repeated. As you warm up, the exhaust frequency increases. After boiling water in the cavity with double walls 12 and constant burning, the frequency of the process repeatability becomes indistinguishable without the device. The second operation mode is accompanied by the mandatory use of the Stirling 4 engine with an electric generator 5. The Stirling 4 engine is located in the furnace compartment 6 of room 2. The heating chamber 39 of the Stirling 4 engine is placed in a heat-conducting cylindrical element 37 made of pressed chips of high-quality copper. The heat-conducting cylindrical element 37, in turn, is inserted inside the cylindrical heat-receiving chamber 38 (Fig.). The heating chamber 39 is placed inside the heat-conducting cylindrical element 37. The outer part of the heat-conducting cylindrical element 37 along the length of the heating chamber 39 is covered with heat-insulating material 38 (Fig.), This retains the heat transferred to the heating chamber 39 of the Stirling engine 4, which improves the energy efficiency of the Stirling engine 4, since the heat-conducting cylindrical element 37 transfers heat to the heating chamber 39 of the Stirling engine 4 over the entire outer surface of this heating measures 39. To increase the efficiency of the Stirling 4 engine, a cooling jacket 21 of the heat exchanger 22 with a screw rib of the Stirling engine 4 is used. The cooling rate is significantly increased due to the passage of cold water inside the cooling jacket 21 along the screw rib of the heat exchanger 22, in this case the path and time of heat removal increase from the surface of the helical fin of the heat exchanger 22. It is known (see Walker G. Stirling Engines, training manual M. Mechanical Engineering, 1985) that the greater the temperature difference of the heating chamber is 39 motors of Tell Stirling 4 and the cooling temperature in the cooling jacket 21 of heat exchanger 22 with helical ribbing, the higher the number of revolutions transmitted to the electric generator 5 Stirling engine 4, which accordingly increases its efficiency. With the consumption of hot water, its level in the cavity 12 decreases, then from the replenishment tank 20, cold water through the pipe 24 enters the cooling jacket 21 of the heat exchanger 22 with helical ribbing. Cold water passes along the helical fin of the heat exchanger 22, cooling the air or working gas located in the cavity of the heat exchanger 22 of the Stirling engine 4. In the absence of hot water consumption when the sauna stove is running, the Stirling 4 engine is cooled by convection movement of water through pipelines 24, 25 (Fig. .). The Stirling engine 4 converts thermal energy into mechanical rotational motion, which is converted into electrical energy using an electric generator 5. This electricity is supplied through KZR 53 and then stored in BAKB 52. The electricity stored in BAKB 52 is converted via an inverter 54 into an alternating voltage of 220 V with a frequency of 50 Hz., Which is used by consumers for various domestic purposes. The third mode is to provide steaming and drying of various clothes and items. PFEM 7, located on the roof 8 of room 2, in the daytime generate electricity, which through KZR 53 is stored in BAKB 52 (Fig. 5, 6), and PFEM 7 is constantly connected to KZR 53, which controls and ensures the accumulation of electricity in BAKB 52 2. Two-bell bathhouse 1 is in operation. Stirling engine 4 with an electric generator 5 generates electricity, which is stored through KZR 53 in BAKB 52 (Fig. 5.) Then, various clothes or items for processing with superheated steam and subsequent drying are placed in indoor 2 or in a tent with double walls 3 . For this, a steam-water pipe 10 is connected to the pipe with a tap 19, which serves to supply steam from the cavity 12, for supplying steam in a special chamber 9 (Fig.). The crane 19 opens, superheated steam enters a special chamber 9, where clothes or other items are steamed for a certain time in accordance with the requirements of regulatory documents. Drying of clothes and other items occurs using heat from the bath furnace 1 and the operation of infrared heaters 55 (Fig.). The operation of the sauna stove 1 in the second and third modes is reserved, in the absence of wood fuel, by using compressed or liquefied gas or by connecting TEN-lei 51, operating from BAKB 52, which is constantly in the daytime through KZR 53. When using compressed or liquefied gas in the hole 28, door 27, the gas burner 29 is attached, then the valve (not shown) of the gas bottle 33 is opened, the gearbox 34 of the gas bottle 33 is adjusted to the operating pressure, then the valve 32 is opened and gas is supplied through the pipeline 35 to the gas burner 29, installed in the furnace space 30 of the sauna furnace 1. In the absence of wood and gas fuel for heating the water in the sauna furnace 1, TEN-s 51 are connected, using BAKB 52 electricity stored with PFEM 7 and generator 5 of the Stirling engine 4. Moreover, TEN-s 51 can be included when the two-bell sauna stove 1 is operating on wood or gas fuel in order to meet the requirements for increased consumption of hot water. The declared MMFADKBP has the properties of economy, autonomy of operation, is convenient for multifunctional use on the basis of renewable energy sources.

Claims (1)

The mobile multifunctional autonomous two-bell sauna stove contains a firebox, a furnace tunnel, a first bell, an open heater chamber, a chimney, double walls with the possibility of filling the space between them with water, pipes with taps for supplying cold and venting hot water located on the outer wall of the furnace, a pipe with a crane for releasing steam, characterized in that it contains a second cap formed by the inner cylinder of the open chamber of the heater and the outer surface of the base of the exhaust pipe, the first count It is located coaxially with the second cap, the Stirling engine, a steam-water flexible pipe for supplying steam to the steam room or open chamber of the heater or into the chamber for steaming clothes, a gas burner and cylinders with reducers serving as reservoirs for storing and using compressed or liquefied gas, a heat-receiving cylindrical chamber for transferring heat from the furnace furnace cavity to a device for removing heat and transferring heat to the heating chamber of the Stirling engine, the flywheel of which is kinematically connected to an electric generator, charging the battery pack, the cooling system of the Stirling engine, film photovoltaic modules configured to generate electricity, a thermoelectric heater with a temperature sensor installed in the lower part of the cavity between the double walls of the furnace and used to heat water from the generated and stored electrical energy using the Stirling engine and film photovoltaic modules, charge-discharge controller of the battery pack, inverter, used for converted I have a constant voltage of the battery pack into an alternating voltage to supply thermoelectric heaters, an adjustable mechanical valve for steam overpressure, a replenishment tank of a constant water level in the cavity between the walls of the furnace, while a pipe with a valve for releasing steam and an adjustable mechanical valve for steam overpressure are located on the top the ring of the double walls of the furnace, and the furnace tunnel is movable.

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