RU2090804C1 - Generator heat utilizer - Google Patents

Abstract

FIELD: heating systems in industries, farming and public services. SUBSTANCE: generator includes horizontal furnace and smoke flue. Over entire outer surface of lateral walls of furnace air passages are located with inlets in lower portion of furnace and outlets in its upper portion. End wall of furnace is provided with inlet hole of smoke flue below which horizontal longitudinal partition is secure in furnace chamber, furnace door being provided on opposite side of furnace. Furnace chamber is provided with two coaxial equal-dimensional pipes forming longitudinal through passage in central portion of furnace chamber. At one end, above-mentioned pipes are tightly secured in end wall which is provided with hole of smoke flue; at opposite end, pipes may be sealed by furnace door in closed position. Furnace door has hole coaxial with longitudinal through passage. Various versions of heat generator include different heating circuits: air circuit of convective (natural) heating of the room where generator is located; air circuit of forced heating of rooms which do not contain heat generator; additional air circuit of forced heating of rooms to which convective (natural) heating circuit is shifted; circulating circuit of water heating system and domestic water circuit. EFFECT: enhanced efficiency. 11 cl, 37 dwg

Description

 The invention relates to the field of heating and can be used: in industry for autonomous heating of industrial buildings, factory floors, office buildings and the production of hot water for industrial and business needs of enterprises and institutions; in agriculture for the production of hot water and autonomous heating of livestock farms, greenhouse greenhouses and free-standing facilities, for drying and storing feeds; in other areas: for the production of hot water and autonomous heating of residential buildings, cottages, apartments of multi-storey residential buildings, buildings of kindergartens, hospitals, as well as in the form of mobile steam baths and saunas; the proposed device can be used for heating customs posts, border outposts, military barracks, as well as for equipping freight, postal, passenger and other cars on the railway.

 The proposed device is a source of heat and water, as close as possible to its consumers, having a high efficiency (up to 90%) and ensuring the disposal of solid combustible waste.

 Known heat generator containing a housing with a furnace, adjacent to the furnace air ducts, air nozzles and a device for regulating the air supply [1] This generator provides a mode of prolonged combustion, however, its disadvantage is that the air ducts are slotted, have an underdeveloped surface heated by the firebox. Part of the heat, not having time to heat the air, goes into the chimney along with smoke. Due to this, the generator has a low efficiency.

 Also known is a heat generator containing a furnace with adjacent ducts [2] The generator is made in the form of a welded metal furnace, the side walls of the furnace of which are made in the form of corrugated welded panels of double curvature. The disadvantage of this device is that it does not provide long-term burning of solid fuel, since the latter does not completely burn out due to the lack of air supply to the upper part of the combustion chamber, which leads to its low efficiency.

 The closest in technical essence to the proposed invention (its prototype) is a heat generator, which is a heating furnace in the form of a horizontally located firebox and chimney. On the entire outer surface of the side walls of the furnace there are air ducts, the entrances to which are located in the lower part of the furnace, and the exits from these channels are located in the upper part of the furnace, the flue inlet is made on the end wall of the latter, below which a horizontal longitudinal partition is fixed in the furnace chamber, and on the opposite side of the furnace there is a furnace door.

 The disadvantages of the prototype is that: the heat of the internal volume of the furnace is not used to heat the premises; the heat generated in the furnace does not provide sufficient air heating due to the small areas of the air-heating surfaces; combustible gases do not completely burn in the furnace; the walls of the furnace chamber are heated unevenly; the possibility of forced supply of heat to other rooms in the form of heated air or liquid coolant is excluded.

 These disadvantages are due to the fact that to ensure effective heating of air in the air ducts, it is necessary to increase the surface of the walls of the furnace, and at the same time the internal volume of the furnace chamber increases. Not all heat flows generated in a large volume of the combustion chamber reach the walls of the furnace and, as a result, part of the heat flows into the chimney without transferring heat to the air in the air ducts on the walls of the furnace; due to the fact that air for combustion of fuel is supplied only through the supply pipe on the furnace door, combustible gases do not completely burn in the furnace. Part of unburned combustible gases goes into the chimney; the heat flux generated during combustion unevenly heats the walls of the furnace chamber; there are no devices providing heating of premises with heated air or water, as well as providing hot water for domestic use.

 The present invention provides the following technical results.

 The heat flows generated inside the furnace chamber not only ensure uniform heating of the furnace chamber walls, but also heat transfer to the additional heat exchanger-heater; the completeness of combustion of fuel and combustible gases in the combustion chamber is increased; heat is transferred to other rooms in the form of heated air and water; Hot water is provided for thermal needs. The ability to control combustion processes with a high degree of fuel combustion makes it possible to use almost any solid combustible substance as fuel, which makes it possible to dispose of any solid combustible waste.

 These technical results lead to an increase in the efficiency of the heat generator and expand its functionality.

 The receipt of these technical results provides a number of distinctive essential features of the proposed heat generator from the prototype.

 The combustion chamber is made by two coaxially arranged different-sized pipes forming an annular cross-section and a longitudinal through channel in the central part of the furnace chamber, moreover, for these different-sized pipes, one ends are firmly and tightly fixed in the end wall in which the chimney inlet is made, and the opposite ends of the different-sized pipes placed with the possibility of sealing the combustion door in the closed position, and in the latter a hole is made coaxial with the longitudinal through channel. The indicated group of features provides an increase in the efficiency of the device, since the specified embodiment of the combustion chamber and its end parts leads to an increase in the uniformity of heating of the chamber walls: the heat flows rising upward and cover the entire volume of the furnace chamber with a ring. These heat fluxes simultaneously heat the outer walls and heat the walls of the inner pipe forming a longitudinal through channel in the central part of the combustion chamber, due to which additional heat is supplied to the heated room from the longitudinal through channel. These distinctive features provide a technical result in all cases of using the invention.

 Other distinguishing features characterize the invention in particular cases and in specific forms of its implementation.

 The cross sections of the pipes forming the furnace and the longitudinal through channel can be in the form of a polyhedron, for example, an octahedron, which ensures an increase in the area of the walls of the chamber of the furnace heated by heat fluxes and the wall area of the longitudinal through channel, increases the efficiency of the heat generator without increasing the dimensions of the latter.

 The best option for a horizontal longitudinal partition is its placement above the outer surface of the pipe forming a longitudinal through channel, with a gap and its execution with openings whose total area in the chimney area is less than the total area of openings in the furnace door area, which leads to the shaping and equalization of heat fluxes in the annular chamber of the furnace, as well as to the uniform distribution of the heat flux.

 In the case of supplying the proposed heat generator with at least a pair of air nozzles equipped with devices for regulating the air supply and mounted on the wall of the furnace with the possibility of supplying air into the cavity above the horizontal longitudinal partition, it becomes possible to fully burn combustible gases in the space above the horizontal longitudinal partition due to adjustable air supply with air nozzles. The adjustable air supply in combination with the selection and installation of a horizontal longitudinal partition with a different ratio of the total area of the holes allows you to dispose of any type of solid fuel, for example, waste from the woodworking industry, wood chips, sawdust, wood shavings, firewood, brushwood, cardboard waste, paper, peat, etc. d.

 The presence of a fan installed on the furnace door with the possibility of supplying ambient air to the longitudinal through channel makes it possible to intensify heat removal to the heated rooms, that is, to further increase the efficiency of the heat generator.

 The set of distinctive features: air ducts are formed by a panel with plates, the ribs of which are placed with the possibility of contact with the outer surfaces of the side walls of the furnace; air ducts through the nozzles communicated with the high pressure zone of the fan; the air ducts and the pipe forming the longitudinal through channel are made of heat-conducting material, for example, steel, provide efficient heating of the air and its supply to the rooms adjacent to the heat generator in order to heat them.

 The set of distinctive features: the heat generator is equipped with a closed circulation system for the liquid coolant, including a heat exchanger-economizer connected to the water supply system, communicated through a heat exchanger-heater located in a longitudinal through channel, with an entrance to the room heating heat exchanger, the output of which is connected to the heat exchanger-economizer; an economizer heat exchanger is installed outside the chimney, covering it; a heat exchanger-heater located in a longitudinal through channel is made annular in cross section and is enveloped with the possibility of contact by the inner wall of the pipe forming a longitudinal through channel in the central part of the combustion chamber; the annular cavity of the heat exchanger-heater located in the longitudinal through channel is equipped with a branch pipe for heated water for domestic use, which ensures efficient heating of the liquid coolant and its supply to neighboring rooms, as well as hot water for domestic use.

 The invention is illustrated by graphic materials, where in FIG. 1 shows a heat generator, view from the side of the door; in FIG. 2 heat generator, side view; in FIG. 3 heat generator, top view; in FIG. 4 heat generator, axonometric image; in FIG. 5 firebox without air ducts and doors, front view (without door); in FIG. 6 firebox, side view (partial section); in FIG. 7 firebox without air ducts and doors (top view); in FIG. 8 firebox without air ducts and doors, axonometric image; in FIG. 9 furnace door; in FIG. 10 - furnace door (side view); in FIG. 11 furnace door (section along AA in FIG. 9); in FIG. 12 furnace door, axonometric image; on Fig heat exchanger-heater located in a longitudinal through channel (section); in FIG. 14 heat exchanger-heater located in a longitudinal through channel (side view, partial section); in FIG. 15 - heat exchanger-heater located in a longitudinal through channel (top view, partial section); in FIG. 16 heat exchanger-heater located in a longitudinal through channel (axonometric image, partial section); in FIG. 17 furnace chamber with air ducts, partial section; in FIG. 18 is a section along CD-E-F in FIG. 17; in FIG. 19 furnace chamber with air ducts, top view (partial section); in FIG. 20 air ducts made in the form of panels with plates (axonometric image); in FIG. 21 chimney with heat exchanger-economizer (section); in FIG. 22 chimney with a heat exchanger-economizer mounted on the furnace; in FIG. 23 chimney with heat exchanger-economizer, top view (partial section); in FIG. 24 - heat exchanger-economizer (axonometric image (; in Fig. 25 - stand (axonometric image); in Fig. 26 placement of air nozzles (partial section); in Fig. 27 air nozzle (partial section); in Fig. 28 air nozzle , side view (partial section); in Fig. 29 a furnace with a stand and air ducts, the direction of the heat flow vectors; in Fig. 30 a furnace with a stand and air ducts, a side view (flow diagram of heated air); in Fig. 31 a fire chamber fan, circuit for removing heated air from the heat exchanger-n a heater located in a longitudinal through channel; in Fig. 32 a furnace with a fan, a circuit for removing heated air from a heat exchanger-heater located in a longitudinal through channel and air ducts made in the form of panels with plates; in Fig. 33 a heat recovery generator equipped with a system for circulating liquid heat carrier; in Fig. 34, the vectors of heat fluxes in the furnace chamber; in Fig. 35, the vectors of heat fluxes in the furnace chamber; in FIG. 36 general diagram of heat flow vectors in the furnace chamber; in FIG. 37 scheme of combining heat generators into a block container for heating and supplying hot water to individual facilities.

 The device of the heat generator. The heat generator contains a horizontally mounted firebox 1. The combustion chamber is made of two coaxially arranged different-sized pipes 2 and 3. Both pipes can have the shape of a polyhedron, for example, an octahedron. The inner pipe 2 forms a longitudinal through channel 4 and is firmly tightly fixed in the end wall 5, for example by welding, and can be further strengthened by metal corners 6 welded to the pipe 2 and end stack 5.

 The outer pipe 3 is also firmly tightly fixed to the end wall 5 and is equipped with a pipe 7 having a cross section in the form of a trapezoid and designed to connect the chimney 8.

 The chimney 8 has a chimney duct 9, which is attached to the nozzle 7, and a transition pipe 10 with an adjusting flap 11. The chimney 8 is also equipped with a support riser 12, which is attached to the nozzle 7. The different-sized pipes 2 and 3 form an annular combustion chamber 13 in the furnace chamber.

 On the end wall 5 below the inlet 14 of the chimney 8, a horizontal longitudinal partition 15 is fixed, which is placed above the outer surface of the pipe 2, forming a longitudinal through channel 4, with a gap, and provided with profiled holes 16 (round, slotted or other shape). The total area of the holes 16 in the area of the chimney 8 is less than the total area of the holes 16 in the area of the furnace door 17.

 The horizontal longitudinal partition 15 divides the annular combustion chamber 13 into two parts, lower 18 and upper 19, with the loaded fuel 20 burning in the lower part of the annular combustion chamber, and the combustion products being burned in the upper part.

 The heat generator is equipped with at least a pair of air nozzles 21, mounted on the wall of the furnace 1 (on the wall of the outer pipe 3) with the possibility of supplying air to the cavity of the upper part 19 of the annular combustion chamber 13. The air nozzles 21 are equipped with adjusting screws 22 and openings 23 for controlled supply in the upper part 19 of the annular combustion chamber 13 of fresh air, due to which the combustion products are burned.

 On the entire outer surface of the side walls of the furnace 1 (on the side walls of the outer pipe 3) are air ducts 24, which are formed by two panels with plates 25, the ribs 26 of which are placed with the possibility of contact with the outer surfaces of the side walls of the furnace 1.

 At the air ducts 24, the inlets 27 are located in the lower part of the furnace 1, and their outputs 28 in the upper part of the furnace 1.

 On the side of the furnace, opposite the end wall 5, the furnace door 17 is placed.

 The cover 29 of the furnace door 17 has the shape of similar octagons and repeats in cross-section the configuration of coaxial different-sized octagonal tubes 2 and 3 of the annular combustion chamber 13. The cover 29 has an octagonal flange 30 with two nozzles 31 and 32. From the side facing the furnace chamber 1, on the cover 29, sealing end elements 33 and 34 are located. In the center of the cover 29 of the furnace door 17, a through hole 35 is made, coaxial with the longitudinal through channel.

 In the lower part of the furnace door 17 there is a supply pipe 36 with a control flap 37 for supplying air to the annular combustion chamber 13 of the furnace 1.

 The furnace door 17 is equipped with a locking and sealing device, including hinge mounting loops 38, a hinged bolt 39 with a thread, a plug 40, a sealing nut 41.

 A fan 42 installed on the furnace door 17 delivers air surrounding the heat generator to the longitudinal through channel 4. The efficiency of the device increases if the furnace 1, the panels with plates 25 forming the air ducts 24, and the pipe 2 forming the longitudinal through channel 4 are made of heat-conducting material, such as steel.

 The heat generator has a stand 43 in the form of a metal closed cavity. The stand 43 is equipped with removable devices 44 and 45. The removable devices 44 have nozzles 46 connected to the nozzles 31 and 32. The removable devices 45 have nozzles 47 for transferring heated air from the air ducts 24 to other rooms under the influence of pressure created by the working fan 42.

 To expand the functionality, the heat generator can be equipped with a closed circulation system for the liquid coolant. The liquid coolant circulation system contains a heat exchanger = economizer 48 connected to the water supply system, which is made in the form of a metal container, consisting of two (or more) sections A 'and B' 49, in cross section having a C-shape and installed on pipe 7. Heat exchanger -economizer 48 is placed around the chimney duct 9. The tank forming the economizer can be made as all-metal and sealed inside by sealed partitions into sections, or separately made from independent containers. Each section A 'and B' of the heat exchanger-economizer 48 is equipped with a pipe 50 and a pipe 51, to which pipelines of cold water supply networks are connected through ball valves with floats for automatic regulation of the water level in sections A 'and B' 49, which have a drain pipe 52 and a drain pipe 53. Section A ′ also has a hot water return pipe 54. Sections 49 are equipped with a neck pipe 55 and a neck pipe 56, respectively, for manually filling the tanks A 'and B' in the absence of water supply networks or lack of water for any reason.

 The liquid coolant circulation system includes a heat exchanger 57 located in a longitudinal through channel 4. The heat exchanger 57 is formed by octagonal tubes 58 and 59 and annular end faces 60 and 61, which are in the form of similar octagons, and are tightly fixed to them. Octagonal tubes 58 and 59 assembled with end faces 60 and 61 form a closed cavity with a through channel 62. Longitudinal plates 63 are placed inside the channel 62.

 The specified closed cavity with a through channel 62 can be divided into sections (made in the form of separate sections or solid, divided inside by metal partitions 64, 65 into two or more sections A '' and B ''). On the end face 60 there are inlet nozzles 66 and 67 and outlet nozzles 68 and 69, respectively, of sections A ″ and B ″. Each of the sections A '' and B '' inside is divided by leaky partitions, providing a countercurrent of the heated fluid. Leakproof partitions 70 and 71 have openings 72 and 73.

 The closed circulation system of the liquid coolant is equipped with a heat exchanger 74 for heating the premises.

 The heat exchanger-heater 57 is located in a longitudinal through channel with the possibility of contact with the inner wall of the pipe 2, forming a longitudinal through channel 4. The cavity of the heat exchanger-heater 57 through the outlet pipe exit 69 communicates with the water circuit for domestic use.

 To ensure communication between the individual elements of the heating systems, a transition pipe 75, ventilation manifolds 76 and 77, connecting pipelines 78 and 79 can be provided in the device.

Functionally, the operation of a fully equipped heat generator is divided into several independently working circuits:
a) the air circuit of convective (natural) heating of the rooms in which the heat generator is directly installed (Fig. 29.30);
b) the air circuit of the forced heating of rooms in which the heat generator is not directly installed or removed from the place of heating (Fig. 31);
c) an additional air circuit for forced heating of the premises, into which the convective (natural) heating circuit is transferred (Fig. 32);
g) the circulation circuit of water heating of premises (Fig.33);
d) water circuit for domestic use (Fig.33).

 The furnace of the heat generator operates as follows. Fuel in the form of combustible industrial or household waste 20 (Fig. 29) is loaded into the annular combustion chamber 13 through the annular furnace door 17 when it is open and set on fire in the usual way. After loading and igniting the fuel 20, the furnace door 17 is closed, while the ends of the pipes 2 and 3 are sealed with sealing end elements 33 and 34. The furnace door is fixed in the closed position by a locking-sealing device.

To regulate the speed of combustion (smoldering) of fuel, control flaps are provided: one at the inlet 37, located on the supply pipe 36, the second 11 on the transition pipe 10 of the chimney 8. The control valve 11 has a central hole, the cross section of which, for example, is 25% of the cross section of the transition pipe 10. The regulating flap 37 on the supply pipe 36 is set to a position that provides minimal air access to the annular combustion chamber 13, while after a certain time (about 30-40 minutes) a steady smoldering mode occurs its combustion, at which the temperature in the combustion chamber 13 is set within 200-300 ^o C. This mode ensures the duration of the fuel combustion process (from 10 to 16 hours depending on the set burning speed, that is, the position of the control flaps and type of fuel).

 Heat transfer begins almost immediately after ignition of the fuel. The fuel burns out almost completely, respectively, while the ash is formed at a minimum, it is not recommended to completely remove it, since further burning (smoldering) occurs on the ash layer, which protects the lower face of the annular combustion chamber 13 and increases its service life. There is no ash pan and grate, which greatly simplifies and facilitates the design of the annular combustion chamber 13. The heat flow S-3, S-4, rising up (Fig. 34.35), covers the entire volume of the combustion chamber 13 with a ring and reaches a longitudinally located partition 15, profiling and equalizing the heat flux with the aim of more complete combustion and uniform distribution of the heat flux over the volume of the annular combustion chamber 13. The partition 15 (Fig. 35) has profiled openings 16, round or slotted, the frequency of which and p the measurements increase in the direction from the chimney to the furnace door 17. The partition 15 is mounted on skids and is removable, which allows selection and replacement of the partition 15 for each type of fuel with the appropriate location, number of holes and their cross-section.

 Thus, the motion vectors of the heat fluxes S-1, S-2, S-3, S-4 have the following directions (Figs. 29,34,35,36): from bottom to top, covering the combustion chamber 13 with a ring on the left and right; in the shape of the letter S in the direction from the supply pipe 36 on the combustion door 17 to the chimney 8.

 The complex volumetric movement of heat fluxes allows you to distribute a more uniform temperature field and to carry out correspondingly more uniform heating of the walls of the annular combustion chamber 13, with more complete burning of combustible gases in the space above the partition 15 due to the supply of fresh air using adjustable air nozzles 21 (Fig. 26 , 27.28). Air nozzles 21, arranged 2.4 or more in a row on each side, supply fresh air through the corresponding openings, each nozzle having the ability to control the flow using the adjusting screws 22 by turning the screw and, accordingly, changing the cross section of its passage opening.

 As a result of the above processes, an almost complete combustion of fuel and maximum heat transfer to the inner and outer walls of the annular combustion chamber 13 occur in the annular combustion chamber 13, which ensures a high efficiency of the heat generator.

 The operation of the air and water circuits of the heat generator is as follows.

Convective (natural) heating air circuit is designed to heat air in a room where a heat generator is directly installed. Cold air enters the air ducts 24 through the inlets 27 located in the lower part of the furnace 1. As a result of heating the air in the air ducts 24, its density decreases towards the outlet 28 from the air ducts 24. Due to the difference in density, the air flow L-1 L-2 up, warm heated air leaves channels 24, heating the room where the heat generator is installed. Plate 25, heating the outer surfaces of the side walls of the furnace 1, provide large heat removal from the outer surface of the annular combustion chamber 13. The temperature of the heated air at the outlet of their ducts reaches 150-170 ^o C.

 The forced air heating circuit is intended for heating air and for its further supply to neighboring rooms with the aim of heating them. The cold air is sucked in by the fan 42 and supplied under pressure into the through channel 62, where it is heated by its walls and longitudinal plates 63. The heated air in the through channel through the adapter pipe 75 enters the ventilation manifold 76 for subsequent supply of the heated air stream L-3 to neighboring rooms or for other purposes.

 The air circuit (optional) of forced heating of rooms is intended for heating air and its further supply to neighboring rooms with the aim of heating them. The operation of this circuit is assumed when there is no great need for heating the room where the heat generator is directly installed, but there is a need to supply heated air to neighboring rooms or for other purposes.

 Cold air under the influence of the fan 42 through the nozzles 31 and 32 enters the closed cavity of the stand 43, then into the removable devices 44, then the cold air enters the air ducts 24, where the air is heated. The heated air stream L-4 enters the removable devices 45 and through the nozzles 47 it enters the ventilation manifolds 77 for subsequent supply to neighboring rooms or for other purposes (Fig. 32).

 The circulation circuit of water heating of premises (Fig. 33) is designed to heat the water circulating in the circuit in order to heat the premises through water heating batteries. Cold water is supplied from cold water supply networks to one of the sections (for example A ') of the heat exchanger-economizer 48 through a cold water supply pipe 50 and a ball valve with a float to automatically maintain the level in sections A', which acts as an expansion tank and provides a column of water, where the water is preheated due to the heat contained in the flue gases passing through the chimney duct 9. The efficiency of the entire installation increases. The preheated water flow M-2 through the drain pipe 52 and the pipe 78 connected to the inlet pipe 66 of section A of the heat exchanger-heater 57 enters the lower part of the latter. Next, the heated water passes through the lower part of section A ", separated from the upper part of the leaky the partition 71, and, reaching its opposite end, through the hole 73 enters the upper part of section A ", where the final heating of the water flow M-2 occurs. Heated in section A" of the heat exchanger-heater 57 water through the outlet pipe 68 post falls into the water heat exchanger 74, thereby heating the rooms through which it passes.

 Then, having transferred its heat, water from the water heating heat exchanger 74 enters through the return pipe 54 again to the section A 'of the heat exchanger-economizer 48, thereby providing circulation in the circuit. The temperature of the heated water at the outlet is determined by the flow of water through the heat exchanger-economizer 48 to the heat exchanger 57, as well as the multiplicity of circulation in the circuit, the geometric dimensions of both heat exchangers and the ratios of their geometric dimensions to each other. The domestic water circuit is intended for heating cold water for domestic purposes. Cold water from cold water supply networks is supplied to one of the sections (for example, B ') of the heat exchanger-economizer 48 through a supply pipe 51 and a ball valve with a float to automatically maintain the level in section B', which acts as an expansion tank and provides a pillar of water where it occurs preliminary heating of water due to the heat contained in the flue gases passing through the chimney duct 9. In this case, the efficiency of the entire installation increases. The preheated M-1 water flow through drain pipe 53 and pipe 79 connecting to the inlet pipe of section “heat exchanger-heater 57” B enters the lower part of the latter. Next, the heated water passes through the lower part of section “B”, separated from the upper part of the leaky the partition 70, and, reaching its opposite end, through the hole 72 enters the upper part of the section "where the final heating of the water flow M-1. The water heated in the section" heat exchanger-heater 57 through the outlet pipe 69 post falls for its intended purpose for household needs (kitchen sink, shower, etc.).

Claims (11)

 1. A heat generator utilizer containing a horizontally located fire chamber, a chimney, air ducts are placed on the entire outer surface of the side walls of the fire chamber, the inlets of which are located in the lower part of the fire chamber, and the exits from these channels are located in the upper part of the fire chamber, on the end wall of the last a chimney opening, below which a horizontal longitudinal partition is fixed in the combustion chamber, and on the opposite side of the furnace there is a furnace door, characterized in that the furnace is made in two coaxial about located different-sized pipes, for example, a polygonal section, the space between which forms a combustion chamber, covering a longitudinal through channel in the center of the combustion chamber, formed by the inner space of a pipe of a smaller section, and for these different-sized pipes, one end is fixed and hermetically fixed in the end wall, in which the inlet of the chimney is made, and the opposite ends of the pipes of different sizes are placed with the possibility of sealing by the furnace door in the closed position, and in the latter Execute hole coaxial with a longitudinal through bore of the combustion chamber.  2. The generator according to claim 1, characterized in that the horizontal longitudinal partition is placed above the outer surface of the smaller pipe with a gap and is made with openings whose total area in the chimney area is less than the total area of openings in the furnace door zone.  3. The generator according to claims 1 and 2, characterized in that it is equipped with at least a pair of air nozzles with devices for regulating the air supply, mounted on the wall of the furnace with the possibility of supplying air into the cavity above the horizontal longitudinal partition.  4. The generator according to claims 1 to 3, characterized in that a fan is installed on the furnace door with the possibility of supplying ambient air to the longitudinal through channel.  5. The generator according to claims 1 to 4, characterized in that the air ducts are formed by a panel with plates, the ribs of which are placed with the possibility of contact with the outer surfaces of the side walls of the furnace.  6. The generator according to claims 1 to 5, characterized in that the furnace, air ducts and the pipe forming the longitudinal through channel are made of heat-conducting material, for example, steel.  7. The generator according to paragraphs. 5 and 6, characterized in that the air ducts by means of nozzles are in communication with the high pressure zone of the fan.  8. The generator according to claims 1 to 7, characterized in that it is equipped with a closed circulation system for the liquid coolant, including a heat exchanger-economizer connected to the water supply system, communicated through a heat exchanger-heater located in a longitudinal through channel, with an entrance to the room heat exchanger, output which is connected to a heat exchanger-economizer.  9. The generator according to claim 8, characterized in that the heat exchanger-economizer is installed outside the chimney, covering it.  10. The generator according to claims 8 and 9, characterized in that the heat exchanger-heater located in the longitudinal through channel is made of two coaxial pipes having a cross section similar to the cross section of the pipes of the combustion chamber and is enclosed by the inner wall of the combustion chamber to provide contact with the latter.  11. The generator of claim 10, characterized in that the cavity of the heat exchanger-heater, located between the coaxial pipes forming it, is equipped with a branch pipe of heated water for domestic purposes.

Images