RU66428U1 - INSTALLATION OF AUTONOMOUS HEAT AND POWER SUPPLIES - Google Patents

Abstract

The invention relates to power engineering, and in particular to equipment designed to generate and supply to consumers simultaneously two types of energy (electrical and thermal). The problem solved by the invention is to increase the reliability and efficiency of the installation with a higher coefficient of use of heat of combustion of fuel, with the ability to control the supply of thermal energy depending on the needs of consumers. Installation for autonomous heat and power supply contains an internal combustion engine 1 in an embodiment (LAN) with an electric generator 2 and a network water pump 3 installed in the cut of the network water pipe 4. LAN 1 is equipped with a lubricant oil circuit 5 with a heat oil lubricant utilizer 6 (UTMS) attached to it, a coolant circuit 7 with a heat coolant utilizer 8 connected to it, a cooling system 9 for two radiators 10, 11 lubricant oil and a coolant and an exhaust gas pipe 12 with an associated exhaust gas heat recovery unit (UTOG) 13. The lubricant oil circuit 5 includes a series-connected line 14 of LAN 1, a temperature regulator 15 of lubricant oil and a radiator 10 of lubricant oil. UTMS 6, connected by pipelines 16, 17 to the lubricant oil circuit 5, structurally includes a housing 18, an intermediate coolant pump 19 with a pressure pipe 20 and a sprayer 21, heat exchangers 22, 23, respectively, of lubricating oil and network water, located inside the housing 18, moreover, the input of the heat exchanger 22 is connected by a pipe 16 to the input of the thermostat 15, and the output of the heat exchanger 22 is connected by a pipe 17 to the output of the thermostat 15. The housing 18 is made in the form of a vertically mounted hollow column with a bottom a lid (not indicated by the diagram). In the upper part of the housing 18, a breathing valve 24 is installed, and in the lower part there is a pointer 25 of the intermediate coolant level. The coolant circuit 7 includes a series-connected pipeline 26 LAN 1, thermostat 27 of the coolant and the radiator 11 of the coolant. UTOZH 8, connected by pipelines 28, 29 to the coolant circuit 7, structurally includes a housing 30, an intermediate coolant pump 31 with a pressure pipe 32 and a sprinkler 33, heat exchangers 34, 35, respectively, of coolant and network water located inside the housing 30, and the input of the heat exchanger 34 is connected by a pipe 28 to the input of the thermostat 27, and the output of the heat exchanger 34 is connected by a pipe 29 to the output of the thermostat 27. Housing 30

made in the form of a vertically mounted hollow column with a bottom and a cover (not shown in the diagram). In the upper part of the housing 30, a breathing valve 36 is installed, and in the lower part there is an indicator 37 of the intermediate coolant level. The cooling system 9 of the radiators 10, 11 includes a fan 38 and shutters 39. The exhaust pipe 12 is equipped with a pivotally mounted damper 40 covering the outlet. UTOG 13, connected by a pipe 41 to an exhaust gas pipe 12, includes a housing 42, an intermediate heat transfer pump 43 with a pressure pipe 44 and a sprinkler 45, heat exchangers 46, 47 of the supply water. The housing 42 is made in the form of a vertically mounted hollow column with a bottom and a cover (not shown in the diagram). In the dissection of the pipeline 41 connecting the inner space of the upper part of the housing 42 with the exhaust gas pipe 12, an exhaust gas flow regulator 48 is installed. In the lower part of the housing 42, an index 49 of the intermediate coolant level is installed and discharge of 50 excess condensate of water vapor into the sewer is framed. The cavity 51, located between the heat exchanger 47 and the surface 52 of the intermediate heat transfer medium, is connected via a pipe 53 to an exhaust fan (exhaust fan) 54. The pipe 53 is additionally connected to the atmosphere by a pipe 55, into the cut of which a regulator 56 of the atmospheric air flow is installed. In the cross-section of the return line 4 of the network water after the pump 3 of the network water, heat exchangers 47, 23, 35, 46 of the network water are connected in series. The output of the heat exchanger 46 is connected to the pipe 57 of the consumer's heat network. The inventive "Installation for autonomous heat and power supply" allows to increase the reliability and efficiency of the installation with a higher coefficient of use of heat of combustion of fuel, with the ability to control the supply of heat energy depending on the needs of consumers, due to the fact that the installation for autonomous heat and power supply contains an electric generator, the first and second gas-liquid heat exchangers are combined into a single exhaust gas heat recovery unit installed in the exhaust pipe gas, inside the upper part of the body of each heat recovery unit a sprinkler is installed, connected through a pipeline and a pump to the lower part of the body of each heat source, which is a reservoir for the intermediate heat carrier, two are placed in the internal space of heat exchangers of lubricating oil and coolant, separated by heights of independent heat exchangers, with lubricant oil and coolant heat exchangers respectively installed at the top, and network water at the bottom, in cut An exhaust gas flow regulator is installed in the exhaust gas sampling pipeline, the internal space of the exhaust gas heat exchanger housing, installed in it, spaced apart in height - the first above the second, network water heat exchangers, is connected to the atmosphere through an exhaust fan and a pipe, in cut

which has a regulator of atmospheric air flow, and the return pipe of the heating network, in the cut of which the mains water pump is connected, is connected to the inlet of the second gas-liquid heat exchanger of the exhaust gas heat utilizer, the output of which is connected to the inlet of the heat exchanger of the coolant of the lubricant oil heat utilizer, the outlet of which is connected to the input of the heat exchanger of the coolant heat recovery agent of the coolant, the output of which is connected to the inlet of the first heat exchanger fluid exhaust heat recovery, the output of which is connected to the conduit network thermal consumer. 1 p. F-ly / 1 ill.

Description

The utility model relates to power engineering, and in particular to equipment designed for the generation and supply to consumers of two types of energy simultaneously (electrical and thermal).

The USSR author's certificate is known No. 1495483, P02G 5/00, publ. 07/23/89, "System of Autonomous Heat and Power Supply". The system comprises a diesel engine, an electric generator, heat exchangers, a waste heat boiler of a diesel exhaust gas, a compression heat pump and a storage tank. To use low potential diesel heat in the external heating network and reduce fuel consumption in the recovery boiler, the storage tank is made with a gas jacket and an internal water cavity included in the return pipe of the external heating network between the heat pump condenser and the waste water boiler circuit and made with a bypass the pipeline. The gas cavity of the storage tank is connected to the exhaust pipe. The waste heat boiler is made with a combustion chamber and with a bypass gas channel.

The disadvantage of this system is its complexity and, as a consequence, the high cost.

Known USSR author's certificate No. 1779757, F01P 3/20, publ. 12/07/92, "The cooling system of an internal combustion engine." The system contains hot and cold coolant circuits, a bypass line, a tank with a steam-air valve, two fans, an oil temperature regulator in the lubrication system. The hot circuit includes a series-connected liquid pump, engine cooling cavities, a thermostat in the form of a three-way valve, a first radiator and a bypass line. The cold circuit includes a circulation pump connected in series by a pipeline, oil and charge air coolers, and a second radiator. The output of the thermostat and the fluid installed at the fluid outlet from the engine cooling cavities is connected via a bypass line to the drain tank and radiators, the fan and radiator drives are connected to temperature sensors installed respectively at the fluid outputs from the engine and from the charge air cooler. Thermostat is installed at the oil inlet to the cooler the input of which is in communication with the engine lubrication system, and the outputs are with the inlet of the cooler 15 and an oil bypass connected to the return master alyu oil cooler of the engine.

The presented technical solution is aimed at ensuring the optimum temperature of the charge air, cooled by the same fluid that cools the coolant and engine oil. At the same time, it is possible to optimize the temperatures of all coolants in the cooling system. However, it should be noted that the disadvantage of this system is its complexity and, as a consequence, the high cost and lack of efficiency, since the issue of the beneficial utilization of heat removed from heated parts of the internal combustion engine (ICE) by the lubrication and cooling systems of the ICE and heat carried away exhaust gas engine.

The closest analogue of the claimed invention, selected as a prototype, is the technical solution for the patent for the invention of the Russian Federation No. 2007606, F02G 5/04, publ. 02/15/94, "Installation for autonomous heat supply." This invention solves the problem of increasing the efficiency of the installation by making better use of the heat of the exhaust gases. Installation for autonomous heat supply, contains a diesel engine (internal combustion engine), a heat exchanger (heat recovery oil of lubricant) connected to the oil circuit of the lubricant, a heat exchanger (heat recovery heat of the coolant) connected to the coolant circuit, a gas-liquid heat exchanger, the water of which is heated by heat exhaust gas of the engine, a water circuit connected to the return pipe of the consumer’s heat network, an additional gas-liquid heat exchanger, the water of which is heated by the heat of the exhaust gases of the engine, a water circuit connected to the pipeline of the consumer’s heat network. The water circuits of all utilizers (heat exchangers) use water supplied from an external heat network, which passes sequentially through all heat exchangers, first through an additional gas-liquid heat exchanger (first), then through a water-oil heat exchanger, through a water-water heat exchanger and through a gas-liquid heat exchanger (second) .

The disadvantage of the closest analogue is the low reliability and efficiency of the device, for example, due to the possibility of network water entering the lubrication system and engine coolant. Another disadvantage is that there is no possibility of regulating the supply of thermal energy to consumers with seasonal and daily changes in ambient temperature.

The technical problem solved by the utility model is to increase the reliability and efficiency of the installation with a higher coefficient of use of heat of combustion of fuel, with the possibility of regulating the supply of thermal energy depending on the needs of consumers.

This object is achieved in that an installation for autonomous heat and power supply, comprising an internal combustion engine, a heat oil lubricant coupler connected to an engine lubricant oil circuit, a coolant heat exchanger connected to an engine coolant circuit, a first gas-liquid heat exchanger whose water is heated by exhaust gas heat engine, a water circuit connected to the pipeline of the consumer’s heat network, a second gas-liquid heat exchanger, the water of which preheated by the engine exhaust gas heat, connected to the return pipe of the consumer’s heat network by a water circuit, according to a utility model, contains an electric generator, the first and second gas-liquid heat exchangers are combined into a single exhaust gas heat exchanger installed in the exhaust gas pipe, inside the upper part of each heat utilizer body a sprinkler is installed, connected through a pipeline and a pump to the lower part of the body of each utilizer, which is a reservoir for an intermediate heat carrier, two independent heat exchangers are installed in the internal space of heat exchangers for lubricating oil of lubricant and coolant connected to the atmosphere, and heat exchangers of lubricating oil and coolant are installed at the top, and network water is installed at the bottom, into the cut of the extraction pipe The exhaust gas flow regulator is installed, the internal space of the body of the exhaust gas heat utilizer, with the diversity and in height - the first above the second, the heat exchangers of the network water are connected to the atmosphere through an exhaust fan and a pipe, in the cut of which a regulator of the flow of atmospheric air is installed, and the return pipe of the heating network, in the cut of which the network water pump is connected, is connected to the inlet of the second gas-liquid heat exchanger heat exhaust gas heat exchanger, the output of which is connected to the inlet of the coolant heat exchanger of the oil heat heat utilizer, the output of which is connected to the heat exchange inlet the coolant heat recovery liquid cooler, the outlet of which is connected to the inlet of the first exhaust gas heat recovery heat exchanger coolant exchanger, the outlet of which is connected to the consumer’s heat network pipeline.

Due to the fact that the installation for autonomous heat and power supply contains an electric generator, the first and second gas-liquid heat exchangers are combined into a single exhaust gas heat exchanger installed in the exhaust gas pipeline, a sprinkler is installed inside the upper part of the body of each heat utilizer, connected through a pipeline and a pump to the bottom part of the body of each utilizer,

which is a reservoir for the intermediate coolant, two independent heat exchangers are installed in the internal space of heat exchangers for lubricating oil and coolant, connected to the atmosphere, and heat exchangers for lubricating oil and coolant, respectively, are installed at the top and cut-off water at the bottom The exhaust gas flow regulator is equipped with an exhaust gas flow regulator, the internal space of the exhaust gas heat recovery body, with data, separated in height - the first above the second, heat exchangers of network water, is connected to the atmosphere through an exhaust fan and a pipe, into the cut of which an air flow regulator is installed, and the return pipe of the heating network, into the cut of which a network water pump is connected, is connected to the inlet of the second gas-liquid heat exchanger of the exhaust gas heat utilizer, the output of which is connected to the inlet of the coolant heat exchanger of the heat oil utilizer of the lubricant oil, the outlet of which is connected n with the inlet of the coolant heat exchanger coolant heat exchanger of the coolant, the outlet of which is connected to the inlet of the first heat exchanger coolant heat exchanger of the exhaust gas heat exchanger, the outlet of which is connected to the pipeline of the consumer's heat network., the reliability and efficiency of the plant with a higher coefficient of utilization of the heat of combustion of fuel increases with the possibility of regulating the supply of thermal energy depending on the needs of consumers.

Thus, the combination of the claimed features can improve the reliability and efficiency of the installation with a higher coefficient of use of heat of combustion of fuel, with the ability to control the supply of thermal energy depending on the needs of consumers.

The inventive "Installation for autonomous heat and power supply" has a novelty, differing from the prototype of the above characteristics, and ensures the achievement of the technical result perceived by the applicant.

The inventive "Installation for autonomous heat and power supply" can be widely used as equipment designed for generation and supply to consumers of thermal energy (hot water, steam), therefore, meets the criterion of "industrial applicability".

The essence of the proposed "Installations for autonomous heat and power supply" is illustrated in the drawing, which presents:

Figure 1 - General view of "Installations for autonomous heat and power".

Installation for autonomous heat and power supply contains an internal combustion engine 1 in the embodiment (ICE) with an electric generator 2 and a network water pump 3 installed in the cut of the network water pipe 4. ICE 1 is equipped with a lubricant oil circuit 5 with a heat lubricant oil heat exchanger (UTMS) 6 attached to it, a coolant circuit 7 with a coolant heat utilizer 8 connected to it, a cooling system 9 for two radiators 10, 11 of lubricant oil and a coolant and an exhaust gas pipe 12 with an associated exhaust gas heat recovery unit (UTOG) 13. The lubricant oil circuit 5 includes serially connected by a pipeline 14 ICE 1, a temperature regulator 15 of lubricant oil and a radiator 10 of lubricant oil. UTMS 6, connected by pipelines 16, 17 to the lubricant oil circuit 5, structurally includes a housing 18, an intermediate coolant pump 19 with a pressure pipe 20 and a sprayer 21, heat exchangers 22, 23, respectively, of lubricating oil and network water, located inside the housing 18, moreover, the input of the heat exchanger 22 is connected by a pipe 16 to the input of the thermostat 15, and the output of the heat exchanger 22 is connected by a pipe 17 to the output of the thermostat 15. The housing 18 is made in the form of a vertically mounted hollow column with a bottom a lid (not indicated by the diagram). In the upper part of the housing 18, a breathing valve 24 is installed, and in the lower part there is a pointer 25 of the intermediate coolant level. The coolant circuit 7 includes a series-connected pipe 26 ICE 1, thermostat 27 of the coolant and the radiator 11 of the coolant. UTOZH 8, connected by pipelines 28.29 to the coolant circuit 7, structurally includes a housing 30, an intermediate coolant pump 31 with a pressure pipe 32 and a sprinkler 33, heat exchangers 34, 35, respectively, of coolant and network water, located inside the housing 30, and the input of the heat exchanger 34 is connected by a pipe 28 to the input of the thermostat 27, and the output of the heat exchanger 34 is connected by a pipe 29 to the output of the thermostat 27. The housing 30 is made in the form of a vertically mounted hollow column with bottoms it and the lid (not indicated on the diagram). In the upper part of the housing 30, a breathing valve 36 is installed, and in the lower part there is an indicator 37 of the intermediate coolant level. The cooling system 9 of the radiators 10, 11 includes a fan 38 and shutters 39. The exhaust pipe 12 is equipped with a pivotally mounted damper 40 covering the outlet. UTOG 13, connected by a pipe 41 to an exhaust gas pipe 12, includes a housing 42, an intermediate heat transfer pump 43 with a pressure pipe 44 and a sprinkler 45, heat exchangers 46, 47 of the supply water. The housing 42 is made in the form of a vertically mounted hollow column with a bottom and a cover (not shown in the diagram). In dissection of the pipe 41 connecting the inner space of the upper part of the housing 42 with

exhaust gas pipe 12, an exhaust gas flow controller 48 is installed. In the lower part of the housing 42, an index 49 of the intermediate coolant level is installed and discharge of 50 excess condensate of water vapor into the sewer is framed. The cavity 51, located between the heat exchanger 47 and the surface 52 of the intermediate heat transfer medium, is connected via a pipe 53 to an exhaust fan (exhaust fan) 54. The pipe 53 is additionally connected to the atmosphere by a pipe 55, into the cut of which a regulator 56 of the atmospheric air flow is installed. In the cross-section of the return line 4 of the network water after the pump 3 of the network water, heat exchangers 47, 23, 35, 46 of the network water are connected in series. The output of the heat exchanger 46 is connected to the pipeline 57 of the heat network of the consumer (figure 1).

Installation for autonomous heat and power works as follows. When the internal combustion engine 1, the associated electric generator 2 provides consumers with electrical energy. At the same time as electric energy, heat energy is supplied to consumers from heated lubricant oil from lubricant oil circuit 5 through a UTMC 6 connected to circuit 5, from heated coolant from coolant circuit 7 through connected to CUT 8, from heated exhaust gases through connected to pipeline 12 UTOG 13. From ICE 1, heated lubricating oil is directed to the radiator 10 of the lubricating oil partially along the lubricating oil circuit 5 through the temperature regulator 15, and partially through the heat exchanger 22 UTMS 6 by connecting ruboprovodam 16, 17. In the UTMS 6 interim coolant supplied to the coolant pump 19 in the intermediate sprayer 21 to the discharge conduit 20, heat exchanger 22 is washed first lubricating oil, and then the heat exchanger 23, mains water. In this way, heat is transferred from the warmer lubricating oil to the less heated supply water. The amount of intermediate coolant in UTMS 6 is controlled using an intermediate coolant level indicator 25, and the pressure inside the housing 18 of the UTMS 6 is maintained at approximately atmospheric by means of a breathing valve 24. From ICE 1, the heated coolant is sent to the radiator 11 of the coolant partially along the coolant circuit 7. through the temperature regulator 27, and partially through the heat exchanger 34 UTOZH 8 through the connecting pipes 28, 29. In UTOZH 8 the intermediate heat carrier supplied by the pump 31 intermediate th coolant in the spray arm 33 via pressure pipe 32, first heat exchanger 34 is washed by the coolant, and then washed by water heat exchanger network 35, thereby effecting heat transfer from the hotter coolant to a less heated water network. The amount of intermediate coolant in UTOZH 8 is controlled by an intermediate level indicator 37, and the pressure inside the housing 30 UTOZH 8 is maintained at approximately atmospheric by means of a breathing valve 36. When

If necessary, the lubricating oil and coolant are additionally cooled in the radiators 10, 11 through which passes, created by the fan 38 and adjustable shutters 39, the flow of atmospheric air. From the internal combustion engine 1, heated exhaust gases through the exhaust gas pipe 12 are directed to the atmosphere, partly through the outlet, while opening the pivotally mounted damper 40 by the exhaust gas pressure, and partly through the internal space of the housing 42 of the exhaust system 13 through the connecting pipe 41, into the cut of which the regulator is installed 48 exhaust gas consumption. In UTOG 13, the intermediate coolant supplied by the intermediate coolant pump 43 to the sprayer 45 via the pressure pipe 44 is first sprayed into the exhaust gas stream forcibly entering the interior of the upper part of the housing 42 via the connecting pipe 41 from the exhaust gas pipe 12. Then, the resulting gas-vapor mixture washes the heat exchangers 46, 47 of the network water, thereby transferring heat from the warmer exhaust gases to the network water. Moreover, the amount of intermediate coolant supplied through the sprayer 45 to the exhaust gas stream is such that in front of the heat exchanger 46 the temperature of the gas-liquid mixture is approximately equal to the temperature of condensation of water vapor, and in front of the heat exchanger 47 the temperature of the gas-liquid mixture is lower than the temperature of condensation of water vapor. From the space 51, located between the heat exchanger 47 and the surface 52 of the intermediate coolant, the exhaust gases with an admixture of water vapor and condensate of water vapor in a finely dispersed state are sucked through the pipe 53 by an exhaust fan (smoke exhaust) 54 and is discharged into the atmosphere. Excess condensate of water vapor in the form of droplets fall on the surface 52 of the intermediate coolant and through the drain 50 are removed into the sewer. The amount of intermediate coolant in the UTOG 13 is controlled using the pointer 49 level of the intermediate coolant. The regulation of the amount of exhaust gases entering forcedly into UTOG 13 and, accordingly, the regulation of the temperature of the supply water is carried out by the regulator 48 of the exhaust gas flow. Maintaining the calculated volumetric flow rate of gas through the exhaust fan (exhaust fan) 54, when changing the heat load, is carried out by suction of atmospheric air supplied to the pipe 53 through the pipe 55, into the cut of which the regulator 56 of the flow of atmospheric air is installed. The supply of thermal energy to consumers is carried out through the network water pumped by the network pump 3 through the return pipe 4 of the network water through heat exchangers 47, 23, 35, 46 of heat recovery units and further into the pipeline 57 of the thermal network of thermal energy consumers. From the heating network of consumers, the network water is returned to the suction pump 3 network water.

The claimed "Installation for autonomous heat and power supply" on the one hand eliminates the ingress of network water into the internal combustion engine in case of violation of the tightness of the heat exchangers of the lubricating oil and internal combustion engine water due to the fact that the heat exchangers are spaced apart in height and washed by a sprayed intermediate coolant at a pressure approximately equal to atmospheric, while the pressure inside heat exchangers above atmospheric, and on the other hand, with daily and seasonal changes in the temperature of the air, regulate the amount of heat energy generated by the consumer due to the fact that the amount of exhaust gas supplied to the heat exhaust gas utilizer is regulated through a pipeline, the cut-off of which the exhaust gas flow regulator is installed, and the volumetric gas flow rate through the exhaust fan (exhaust fan) is maintained in the calculated parameters by feeding the internal cavity of the exhaust gas utilizer of the atmospheric air through a pipeline, into the cut of which an air flow regulator is installed.

This “Installation for Autonomous Heat and Power Supply” can be used as a mini-cogeneration plant with an integrated heat utilization system (SKIT mini-CHP), but with a higher coefficient of utilization of the heat of combustion of fuel.

The inventive "Installation for autonomous heat and power supply" allows to increase the reliability and efficiency of the installation with a higher coefficient of use of heat of combustion of fuel, with the ability to control the supply of heat energy depending on the needs of consumers, due to the fact that the installation for autonomous heat and power supply contains an electric generator, the first and second gas-liquid heat exchangers are combined into a single exhaust gas heat recovery unit installed in the exhaust pipe gas, inside the upper part of the body of each heat recovery unit a sprinkler is installed, connected through a pipeline and a pump to the lower part of the body of each heat source, which is a reservoir for the intermediate heat carrier, two are placed in the internal space of heat exchangers of lubricating oil and coolant, separated by heights of independent heat exchangers, with lubricant oil and coolant heat exchangers respectively installed at the top, and network water at the bottom, in cut The exhaust gas flow regulator is installed in the exhaust gas extraction pipeline, the internal space of the exhaust gas heat exchanger body, installed in it, spaced apart in height - the first above the second, heat exchangers of mains water, is connected to the atmosphere through an exhaust fan and a pipe, into the cut of which the regulator is installed atmospheric air flow, moreover, the return pipe of the heating network, into the cut of which the network water pump is connected, is connected to the inlet of the second gas-liquid heat heat exchanger heat exchanger

the outlet of which is connected to the inlet of the coolant heat exchanger of the heat exchanger of the lubricant oil lubricant, the outlet of which is connected to the inlet of the coolant heat exchanger of the heat exchanger of the coolant oil, the outlet of which is connected to the inlet of the first heat exchanger of the heat exchanger of the exhaust gas heat utilizer, the outlet of which is connected to the consumer’s heat network pipeline.

Claims (1)

Installation for autonomous heat and power supply, comprising an internal combustion engine, a heat lubricant oil heat exchanger connected to an engine lubrication oil circuit, a coolant heat heat exchanger connected to an engine coolant circuit, a first gas-liquid heat exchanger whose water is heated by engine exhaust gas heat, and a water circuit connected to the consumer’s heat pipeline, a second gas-liquid heat exchanger, the water of which is heated by the heat of the exhaust gases a boiler, connected by a water circuit to the return pipe of the consumer’s heat network, characterized in that it contains an electric generator, the first and second gas-liquid heat exchangers are combined into a single exhaust gas heat exchanger installed in the exhaust gas pipe, a sprayer is installed inside the upper part of each heat utilizer body through the pipeline and pump with the lower part of the body of each utilizer, which is a reservoir for the intermediate coolant, into the inner its space of heat exchangers for lubricating oil and coolant, connected to the atmosphere, has two independent heat exchangers spaced apart in height, with heat exchangers for lubricating oil and coolant being installed at the top, and network water at the bottom, and a flow regulator installed in the cut of the exhaust gas extraction pipe exhaust gas, the internal space of the exhaust gas heat exchanger housing, with the height installed in it, separated in height - the first over the second, the heat exchanger network water, connected to the atmosphere through an exhaust fan and a pipe, into the cut of which a regulator of atmospheric air flow is installed, the return pipe of the heating network, into the cut of which the pump of network water is connected, is connected to the inlet of the second gas-liquid heat exchanger of the exhaust gas heat utilizer, the output of which is connected with the heat exchanger coolant heat exchanger inlet of the lubricant oil heat, the outlet of which is connected to the heat exchanger coolant heat exchanger inlet of the heat exchanger coolant, the outlet of which is connected to the inlet of the first heat exchanger of the coolant of the exhaust gas heat utilizer, the outlet of which is connected to the pipeline of the consumer’s heat network.