RU2730756C1 - Device for catalytic cleaning of internal combustion engine exhaust gases - Google Patents

Abstract

FIELD: engine building.SUBSTANCE: device for catalytic purification of ICE exhaust gases by selective catalytic reduction / oxidation method comprises control and control system with sensors of parameters and process control elements, units for selective reduction and / or oxidation of harmful components of exhaust gases, at least, one device for supply of chemically active additives with at least one container and with one pneumatic device for dispensing and supply of chemically active additives in a solid phase into a thermal reactor, including thermolysis zones of chemically active additives in a solid phase with a unit for heating thermolysis catalysts and hydrolysis of harmful products of thermolysis in gas phase to simple substances, output ejector of pneumatic supply to exhaust manifold to corresponding catalyst unit for selective catalytic reduction of chemically active additives in gaseous phase, wherein thermolysis catalyst heating unit is additionally equipped with at least one controlled heat pipe connected to exhaust manifold, with control and adjustment system, with parameters sensors and with heat transfer process control elements, and each of selective reduction and / or oxidation units of harmful exhaust gas components are equipped with at least one controlled heat pipe connected to exhaust manifold, with thermal accumulator, with regulation and control system, with sensors of parameters and with heat transfer process control elements.EFFECT: device for catalytic cleaning of ICE exhaust gases is proposed.1 cl, 2 dwg, 1 tbl

Description

The device for catalytic cleaning of exhaust gases of an internal combustion engine (ICE) is intended for catalytic cleaning of exhaust gases from internal combustion engines and can be used in the national economy in conjunction with any internal combustion engine, mainly in power engineering.

Known is a device for catalytic cleaning of ICE exhaust gases by the method of selective catalytic reduction / oxidation of exhaust gas components and supply of chemically active additives, containing a regulation and control system with parameter sensors and process controls, units for selective reduction and / or oxidation of harmful components of exhaust gases, at least , one storage device for chemically active additives, at least one pneumatic device for dosing and feeding chemically active additives (in the solid phase) into a thermal reactor, including zones of thermolysis of chemically active additives in the solid phase with a heating unit for thermolysis catalysts and hydrolysis of harmful thermolysis products in gas phase to simple substances, the output ejector of pneumatic supply to the exhaust manifold on the corresponding catalyst unit for selective catalytic reduction of chemically active additives in the gas phase, (see RF patent RU 2673030 C2, patent holder JONSON MATTY KATALISTS (JERMANI) GMBH, publ. 03/13/2018).

The main disadvantage of the device for the catalytic purification of exhaust gases from an internal combustion engine is the complexity of organizing the process of dosing, supplying and evaporating ammonia or its precursor from an aqueous solution.

Known is a device for catalytic cleaning of ICE exhaust gases by the method of selective catalytic reduction / oxidation of exhaust gas components and supply of chemically active additives, containing a regulation and control system with parameter sensors and process controls, units for selective reduction and / or oxidation of harmful components of exhaust gases, at least , one device for storing chemically active additives, at least one device for dosing and feeding chemically active additives into a thermal reactor, including zones of thermolysis of chemically active additives with a unit for heating catalysts for thermolysis and hydrolysis of harmful thermolysis products in the gas phase to simple substances, pneumatic outlet ejector feeding into the exhaust manifold to the corresponding catalyst unit for selective catalytic reduction of chemically active additives in the gas phase (see RF patent RU 2538368 C2, patent holder OGAIO UNIVERSITY publ. 01/10/2015).

The main disadvantage of the device for the catalytic purification of exhaust gases from an internal combustion engine is the complexity in all operating modes and the transition between them for the internal combustion engine to organize the process of thermal hydrolysis of urea, subsequent evaporation in the required amount and the supply of ammonia or its precursor from an aqueous solution.

Known is a device for catalytic cleaning of ICE exhaust gases by the method of selective catalytic reduction / oxidation of exhaust gas components and supply of chemically active additives, containing a regulation and control system with parameter sensors and process controls, units for selective reduction and / or oxidation of harmful components of exhaust gases, at least , one device for storing chemically active additives, at least one device for dosing and feeding chemically active additives into a thermal reactor, including zones of thermolysis of chemically active additives with a unit for heating catalysts for thermolysis and hydrolysis of harmful thermolysis products in the gas phase to simple substances, pneumatic outlet ejector feeding into the exhaust manifold to the corresponding catalyst unit for selective catalytic reduction of chemically active additives in the gas phase (see RF patent RU 2667852 C2, patent holder SCANIA SV AB publ. 09.24.2018).

The main disadvantage of the device for catalytic purification of exhaust gases from an internal combustion engine is the complexity of the control and organization of a two-stage process of supplying and evaporating portions of additives in the form of ammonia or its precursor from a liquid solution at all operating modes of the internal combustion engine.

A device for catalytic cleaning of gases, for example, exhaust gases of an internal combustion engine, is known by the method of selective catalytic reduction / oxidation of components of exhaust gases and the supply of chemically active additives, containing a regulation and control system with parameter sensors and process controls, blocks for selective reduction and / or oxidation of harmful components of exhaust gases at least one device for storing chemically active additives, at least one electromechanical device for dosing and feeding chemically active additives in the solid phase into a thermal reactor, including zones for thermolysis of chemically active additives in the solid phase with a heating unit for thermolysis and hydrolysis catalysts of harmful products thermolysis in the gas phase to simple substances, the output ejector is fed into the exhaust manifold to the corresponding catalyst unit for the selective catalytic reduction of chemically active additives in the gas phase, (see RF patent RU 2391288 C2, patent the owner of MAN NUTZFARZOYGE AKTSIENGEZELLSHAFT publ. 10.06.2010).

The main disadvantage of the device for the catalytic purification of exhaust gases from an internal combustion engine is the complexity of organizing the process in the thermolysis zone of chemically active additives in the solid phase with an electric unit for heating thermolysis and hydrolysis catalysts in the gas phase of harmful thermolysis products to simple substances due to the large and constant consumption of electricity from the internal combustion engine power supply system. that at high speeds of rotation of the output shaft and heavy loads additionally overloads the power supply system of the internal combustion engine.

Known is a device for catalytic cleaning of ICE exhaust gases by the method of selective catalytic reduction / oxidation of exhaust gas components and supply of chemically active additives, containing a regulation and control system with parameter sensors and process controls, units for selective reduction and / or oxidation of harmful components of exhaust gases, at least , one device for storing and supplying chemically active additives with at least one container and with one pneumatic device for dosing and supplying chemically active additives in the solid phase into a thermal reactor, including zones for thermolysis of chemically active additives in the solid phase with a heating unit for thermolysis catalysts and hydrolysis of harmful products of thermolysis in the gas phase to simple substances, the output ejector of pneumatic feed into the exhaust manifold to the corresponding catalyst unit for the selective catalytic reduction of chemically active additives in the gas phase, (see patent US NT US 6928807 B2, patent holder MAN NUTZFAHRZEUGE AKTIENGESELLSCHAFT publ. 27.08.2003).

The main disadvantage of the device for the catalytic purification of exhaust gases from an internal combustion engine is the complexity of organizing the process of feeding into the reaction chamber and maintaining the mode of converting solid carbamide in it into ammonia or into its precursor in the gas phase at all operating modes of the internal combustion engine, and the necessary constant energy costs for heating the surface thermal reactor and constant maintenance of the temperature of this surface required for the thermolysis of carbamide into ammonia and for the endothermic reaction of thermolysis of carbamide and hydrolysis of isocyanic acid. This creates a constant increased load on the electrical system of the internal combustion engine. Heating the catalyst by direct heat transfer of heat through the materials of the walls of the exhaust manifold and the thermal reactor from the exhaust gases requires a sufficiently long time, which cannot ensure the promptness of heating the catalyst when the operating mode of the internal combustion engine changes and the amount of ammonia increases with increasing rotation speed or load.

The technical objective of the proposal is to increase the efficiency of the internal combustion engine by reducing the load on the electric power system of the internal combustion engine, reducing the fuel consumption and increasing the efficiency of heat use in the internal combustion engine, including the heat of exhaust exhaust gases, increasing the stability of the thermal reactor of carbamide thermolysis and hydrolysis of isocyanic acid. and corresponding catalyst units for selective catalytic reduction of chemically active additives in the gas phase and increasing the responsiveness of the thermal reactor to changes in the operating mode of the internal combustion engine.

The technical problem is solved by the fact that the device for catalytic cleaning of the exhaust gases of the internal combustion engine by the method of selective catalytic reduction / oxidation of the components of the exhaust gases and the supply of chemically active additives, containing a regulation and control system with parameter sensors and process controls, blocks for selective reduction and / or oxidation of harmful components of exhaust gases , at least one device and supply of chemically active additives with at least one container and with one pneumatic device for dosing and supply of chemically active additives in the solid phase into a thermal reactor including zones of thermolysis of chemically active additives in the solid phase with a heating unit catalysts for thermolysis and hydrolysis of harmful products of thermolysis in the gas phase to simple substances, the output ejector of pneumatic supply to the exhaust manifold to the corresponding catalyst unit for selective catalytic reduction of chemically active additives in gases phase, and the unit for heating catalysts for thermolysis and hydrolysis of harmful thermolysis products is additionally equipped with at least one controlled heat pipe connected to the exhaust manifold, with parameter sensors, with controls for the heat transfer process and with a control and management system, and each of the blocks selective reduction and / or oxidation of harmful components of exhaust gases are equipped with at least one controlled heat pipe with a thermal accumulator connected to the exhaust manifold, with a thermal accumulator, with parameter sensors, with controls for the heat transfer process and with a regulation and control system.

It should be clarified, however, that emissions from internal combustion engines (ICEs) are divided into emissions from carburetor and diesel engines. This division is due to the fact that carburetor engines (CD) work with homogeneous fuel-air mixtures, while diesel engines (DD) - with heterogeneous mixtures (see the book AG Vetoshkin "Processes and gas cleaning devices". manual. Penza: Publishing house of vocational school, 2006, pp. 164-180).

Emissions from carburetor-type internal combustion engines include hydrocarbons, carbon oxides, nitrogen oxides and fugitive emissions. Contamination occurs as a result of reactions and during combustion in bulk and on surfaces. The blow-by of gases through the piston rings and exhaust from the cylinders are less intensive sources of pollution. In 1980, 4% of the world's passenger cars and trucks were equipped with diesel engines, and by the end of the 1980s this figure had increased to 25%. The main pollutant emissions of diesel engines are the same as those of carburetor engines (hydrocarbons, carbon monoxide, nitrogen oxides, irregular emissions), but carbon particles (soot aerosol) are added to them. The content of harmful substances in car emissions varies widely and depends on many factors, for example, at a speed of 70 km / h, the exhaust of a car contains 0.2 ... 0.3% CO, at a speed of more than 100 km / h and when the engine is running on idling, the content of this dangerous gas reaches 12%. A passenger car emits carbon monoxide CO up to 3 m3 / h, a truck - up to 6 m3 / h (3.6 kg / h).

The composition of the exhaust gases of cars with different types of engines can be judged from the data given in Table 8.1.

It should be clarified that it is obvious that in the proposed design, classical non-controllable heat pipes can of course be used, and additional restrictions will arise during their operation, associated with the constant transfer of heat and the temperature of the beginning of their operation.

It should also be clarified, since it is well known that a controlled heat pipe is called a classical heat pipe, which, in addition to a sealed housing for moving the flow of the gaseous phase of the internal coolant, means for moving the flow of the liquid phase of the internal coolant and places for supplying and removing heat to it when its aggregate state changes from liquid to gaseous and vice versa, usually additionally equipped with means for monitoring the thermal state, the presence and regulation of the flow of the liquid and / or gaseous phase of the internal heat carrier, this cannot be the subject of the invention. These tools allow you to determine her working or non-working state, the intensity of her work, regulate the heat transfer process and turn it off if necessary. In addition, the operating temperature of the heat pipe (that is, the boiling / condensation temperature of the internal heat carrier) cannot be lower than the operating temperature of the device for heating the catalysts of thermolysis and hydrolysis of harmful thermolysis products in the gas phase to simple substances such as ammonia, etc., respectively. Obviously, the temperature of the blocks for selective reduction and / or oxidation of harmful components of exhaust gases must be different from the above, for this reason, each controlled heat pipe connected, respectively, with its thermal accumulator, parameter sensors, control elements for the heat transfer process and with a control system and control must operate within the operating temperature range of the corresponding catalyst. This achieves the following technical results, described below.

The general sequence of operation of the device for catalytic cleaning of exhaust gases of an internal combustion engine is almost the same as in the prototype, but new technical results are achieved and differences in operation begin when the controlled heat pipe reaches the operating temperature, when the controlled heat pipe enters the operating mode, that is, the process of evaporation / boiling and condensation and vice versa of the internal heat carrier becomes intense, and due to this, an intensive process of heat exchange and maintenance of the temperature state of thermolysis catalysts and hydrolysis of harmful thermolysis products in the gas phase to simple substances should take place. For this reason, high-temperature and other heat pipes allow, in addition to intensifying the use of waste heat of exhaust gases, to achieve an additional technical result, such as temperature stabilization of the processes of operation of a thermal reactor for carbamide thermolysis and hydrolysis of isocyanic acid, and for the corresponding catalyst units for selective catalytic reduction / oxidation and supply the corresponding chemically active additives in the gas phase, by means of temperature stabilization of the process, to increase the efficiency of the process by operating them at the optimum operating temperature due to such a physical effect as the constancy of the condensation temperature of the internal coolant of the heat pipe.

The proposal is illustrated by drawings.

FIG. 1 shows the general diagram and design of a device for catalytic cleaning of exhaust gases from an internal combustion engine. FIG. 2 shows the design of a thermal reactor with at least one controlled heat pipe connected to parameter sensors, a regulation and control system and controls for the heat transfer process, including zones of thermolysis of chemically active additives in the solid phase with a heating unit for thermolysis and harmful hydrolysis catalysts thermolysis products in the gas phase to simple substances.

FIG. 1 shows: an internal combustion engine 1, an exhaust manifold 2 for removing exhaust gases with a turbine 3 of a turbocharger drive, a pipeline 4 of the exhaust system, a preliminary starting catalyst 5 of a device for catalytic cleaning of exhaust gases of an internal combustion engine, at least one unit 6 of a selective catalytic reduction catalyst / oxidation or SCR (the term "SCR" means selective catalytic reduction), a device for storing and supplying reactive additives with a capacity 7 for storing urea, and each device for storing and supplying reactive additives is made not only with at least one with a capacity 7, but also with at least one pneumatic device 13 for dosing and feeding chemically active additives in the solid phase into a thermal reactor 8, while a thermal reactor 8 for the production of ammonia (NH ₃ ) is made with a thermolysis zone, in which the reaction chamber 9 with a thermolysis catalyst is made with the possibility of preliminary heating by an electric heating element 10 of the thermolysis catalyst, and with a hydrolysis zone - heating the catalyst 11 for the hydrolysis of harmful thermolysis products in the gas phase to simple substances, a urea level sensor 12 in a urea storage tank 7, a pneumatic dosing device 13 serves for dosing and feeding urea into pneumatic device for dosing and supplying other chemically active additives in the solid phase to another similar thermal reactor 8. Tube 14 for pneumatic supply of urea to the thermolysis reactor 8 for the production of ammonia (NH ₃ ), connected to a pneumatic pump 15 for supplying urea, tube 16 for supplying air to the metering device 13 for feeding urea, with a valve-regulator 17 for feeding urea. The pipe 18 for supplying aqueous exhaust gases and a regulator valve 19 for supplying aqueous exhaust gases serve to regulate the supply of water to the hydrolysis catalyst 11 in the zone of hydrolysis of harmful thermolysis products in the gas phase to simple substances. The regulation and control system with parameter sensors and process controls also includes a control, regulation and control unit 20 with parameter sensors and process controls, a control channel 21 of a pneumatic pump 15, a control channel 22 of a pneumatic metering device 13, a control channel 23 of a blocking valve-regulator 17, control channel 24 for movable positioning of the regulator valve 19, control line 25 for the thermal power of the heating element 10, control channel 26 of the control unit 20 of the regulation and control system with parameter sensors and process controls, information panel 27 of the control unit 20, measuring channel 28, the content of NO _x in the exhaust manifold 2 for collecting the exhaust gases, the measuring channel 29 of the temperature and, if necessary, also the pressure of the exhaust gas in the exhaust gas line 4 at a point upstream of the pre-catalyst 5, such measurements are provided through the measuring channel 28, the NO _x content in the exhaust gas collection line 2, the measuring channel 30, which serves to transmit data on the rotational speed, torque and mass flow of the exhaust gases of the engine 1, the measuring channel 31, which serves to transfer data on the temperature of the branch of the exhaust gas flow into the supply pipeline 18 for the supply of exhaust water-containing gases, the measuring channel 32, which serves to transmit data on the state of filling the supply container with urea, measured by the sensor 12, the measuring channel 33, which serves to transmit data on the temperature in the thermolysis zone of the reaction chambers 9, measuring channel 34, which serves to measure the temperature of the exhaust gas in the exhaust gas pipeline 4 when the exhaust gas is introduced into the SCR catalyst 6, an ammonia intake from the outlet zone 35 of the thermal reactor 8, a pipeline 36 that serves to remove ammonia from the outlet zone 3 5 into the outlet ejector 37 of pneumatic supply to the exhaust manifold to the corresponding unit 6 of the catalyst for selective catalytic reduction of reactive additives in the gas phase, in this case, ammonia.

The device for catalytic purification of ICE exhaust gases by the method of selective catalytic reduction / oxidation of exhaust gas constituents and the supply of chemically active additives, contains a regulation and control system including a control unit 20 with parameter sensors and process controls, units 6 for selective catalytic reduction and / or oxidation of harmful constituents exhaust gases, at least one device for storing and supplying chemically active additives, for example, urea, with at least one container 7 and one pneumatic device 13 for dosing and feeding chemically active additives in the solid phase into a thermal reactor 8, including a zone thermolysis with a reaction chamber 9 for thermolysis of a reactor 8 of chemically active additives in the solid phase, with an electric heating element 10 for a heating unit for heating thermolysis catalysts in a thermal reactor 8, and a hydrolysis zone with a catalyst 11 for hydrolysis of harmful thermolysis products in the gas phase to simple substances, the output ejector 37 of pneumatic supply of chemically active additives in the gas phase to the exhaust manifold 2 to the corresponding unit 6 of the catalyst for selective catalytic reduction or oxidation of reactive additives in the gas phase.

The controlled heat pipe 38 and other typical details of this part of the invention are shown in FIG. 2, including the sensor 39 of the temperature of the exhaust gases at the inlet to the hot part of the heat pipe 38, the sensor-regulator 40 of the presence and regulation of the flow of the internal heat carrier in the controlled heat pipe 38, the sensor 39 of the temperature at the outlet of the heat pipe at the catalysts in the thermolysis zone, the sensor 42 the heating temperature of the electric heating element 10 of the unit for heating the catalysts of thermolysis and hydrolysis of harmful thermolysis products in the gas phase to simple substances. The unit for heating the catalysts in the reaction chamber 9 of the thermolysis catalyst and the hydrolysis catalyst 11 of harmful thermolysis products is additionally equipped with at least one controllable heat pipe 38 connected to the exhaust manifold 2, with a regulation and control system including a control unit 20, with parameter sensors ( such as sensor 39 of the temperature of the exhaust gases at the inlet to the hot part of the heat pipe, the sensor 41 of the temperature at the outlet of the heat pipe at the catalyst in the reaction chamber 9 of the thermolysis of the reactor 8 in the thermolysis zone, the sensor-controller 40 of the presence and regulation of the flow of the internal heat carrier, the sensor 42 electric heating element 10 of the unit for heating catalysts of thermolysis and hydrolysis of harmful products of thermolysis in the gas phase to simple substances, etc.) and with controls for the heat transfer process, for example, such as a sensor-controller 40 for the presence and regulation of the flow in the gas phase of the internal heat carrier in at controlled heat pipe 38, and each of the blocks 6 (which are not shown in detail in the drawings, but are made with a similarly controlled heat pipe 38) for selective reduction and / or oxidation of harmful components of exhaust gases, including the starting pre-catalyst 5, are equipped with at least one controlled heat pipe with a thermal accumulator connected to the exhaust manifold, with a corresponding thermal accumulator, with a regulation and control system, with parameter sensors and with controls for the heat transfer process.

The device for catalytic cleaning of exhaust gases of internal combustion engines by the method of selective catalytic reduction / oxidation of components of exhaust gases and the supply of chemically active additives operates as follows.

Obviously, the thermal power for heat transfer by the controlled heat pipe 38 should be sufficient to provide heat and sufficient heating of the catalyst to the temperature of urea thermolysis on the thermolysis catalyst in the thermolysis reaction chamber 9 of the reactor 8 at any even the most intensive operation of the internal combustion engine. It is always easier to reduce the intensity of heat transfer by the controlled heat pipe 38 than to intensify this process. The main limiting factor in this case may be, for example, limiting the flow rate and flow of the liquid phase of the internal heat carrier forcibly, or through a capillary wick or by gravity.

During the initial start-up of a cold internal combustion engine 1 until the required heating of the starting pre-catalyst 5 and blocks 6 of the catalyst for selective catalytic reduction / oxidation of harmful components of exhaust gases (the sequence of catalytic treatment / neutralization of their individual harmful components depends on the chemical properties of each component and for this purpose it is proposed to use its own reduction catalyst or oxidation, for this reason the most harmful and common components will be considered here) ad- or ab-sorbents of products of incomplete combustion of fuel in the usual manner can be involved. After heating these parts of the device to the operating temperatures of the corresponding catalysts for catalytic purification of exhaust gases of internal combustion engines by the method of selective catalytic reduction / oxidation of harmful components of exhaust gases in accordance with their chemical nature, for example, starting pre-catalyst 5, which, for example, in addition to its function as a sorbent and oxidizer of carbon monoxide (CO) and hydrocarbons in the exhaust gas system, usually performs the function of a significant increase in the proportion of NO _x , in this case, a chemical additive in the exhaust gases can be a natural oxidizing agent, for example, oxygen from the secondary air, then at the next stage in the region of the optimum temperature in the catalyst blocks 6 are reducing the nitrogen oxide contained in the exhaust gases. In the part of the device for catalytic cleaning of exhaust gases of internal combustion engines by the method of selective catalytic reduction of components of exhaust gases from NO _x by supplying one of the chemically active additives, namely ammonia (NH ₃ ) in the device for storing and supplying chemically active additives, a container 7 for storing urea is put into operation in the solid phase, in which it is stored in a dry state in the form of a powder, granulate or microgranules, coupled with which and with at least one pneumatic metering device with a control valve 17 for supplying urea and a pneumatic device 13 for feeding urea in a solid phase into thermal reactor 8 of thermolysis and production of ammonia (NH ₃ ), and with a sufficiently electrically heated reaction chamber 9, which is divided respectively into thermal zones of thermolysis of urea reactor 8 and hydrolysis, that is, hydrolysis treatment of harmful products of thermolysis in the gas phase, for example, such as isocyanic acid (HCNO), by introducing water or water-containing gas into this zone, for example, by means of a means for supplying water-containing exhaust gases made in the form of a tube 18 with a control valve 19 for supplying these gases. Under the action of water on the hydrolysis catalyst 11, harmful products of thermolysis in the gas phase, for example, such as isocyanic acid (HCNO), decompose to simple substances, that is, ammonia and carbon dioxide (CO ₂ ). Also comes into operation a pneumatic device 13 for feeding urea from a supply container - a container 7 for storing urea, which is supplied in controlled or predetermined measured quantities to the reaction chamber 9 of the thermolysis of the reactor 8, while the electric heating element 10 in the heat treatment zone in the reaction chamber 9 is preheated to the temperature of the start of the thermolysis reaction of the reactor 8, and the device for regulating the temperature of the electric heating element 10 maintains this temperature so that the urea introduced into the reaction chamber 9 spontaneously decomposes by rapid heat treatment into ammonia (NH ₃ ) and isocyanic acid ( HCNO), and the device for introducing water or water-containing gas supplies water (H ₂ O) in the required quantities into the reaction chamber 9 of the reactor 8, and the hydrolysis catalyst 11 in the hydrolysis zone of the reaction chamber 9 of the reactor 8 in the presence of water to convert isocyanic acid (HCNO) is converted as a result of rapid heat treatment, in addition to the previously treated urea and the resulting ammonia (NH ₃ ), converted into ammonia (NH ₃ ) and carbon dioxide (CO ₂ ) and all the ammonia obtained in these processes in the form of a chemical active additive in gas phase enters the outlet ejector 37 of the pneumatic supply of the generated gas to the exhaust manifold to the corresponding unit 6 of the catalyst for selective catalytic reduction of reactive additives in the gas phase, or another type of nozzle introduces such products into the pipeline 4 of the exhaust system to the corresponding unit 6 of the catalyst. In this case, other harmful components of the exhaust gases are converted into harmless ones at other similar units for selective catalytic reduction / oxidation of the components of the exhaust gases, possibly by supplying other chemically active additives.

It is obvious that the supply of water or water-containing gas to this zone should be carried out in terms of the actual content of water in it, that is, it should correspond to the amount required for the normal operation of the hydrolysis catalyst 11. The simplest method of regulating this process in this case can be carried out by supplying a calculated amount of water in the liquid phase, obtained from the corresponding tank, or its condensate obtained from the exhaust gases.

After starting and warming up the internal combustion engine, the exhaust gases reach operating temperatures and the exhaust gas temperature sensor 39 at the inlet to the hot part of the heat controlled pipe 38 transmits to the control unit 20 of the regulation and control system with parameter sensors and process controls a command of readiness for operation of the controlled heat pipe 38, and the sensor-regulator 40, in the presence of an internal heat carrier flow in a gaseous form, opens and, if necessary, regulates this flow in the controlled heat pipe 38 to the required heat flux to the thermolysis catalyst and ensures the operation of the thermal reactor 8 for the production of ammonia thermolysis and hydrolysis catalysts (NH ₃ ) in quantities required for the normal operation of the corresponding unit 6 of the SCR catalyst. Heat pipe 38 can be adjusted in two ways. The first way is to shut off or limit the supply of the gaseous flow of the internal heat carrier to the heating zone of the thermolysis / cooling (condensation) catalyst of the heat carrier. The second way is to block or limit the supply of the condensed (in the liquid phase) flow of the internal heat carrier to the heating / evaporation zone. The physics of the process and the operating mode of the controlled heat pipe 38 stabilizes the temperature of its surface of the thermolysis catalyst, due to the stability of the condensation temperature of the internal coolant, which excludes the possibility of overheating of the thermolysis catalyst and obtaining, instead of the thermolysis process, another process, for example, thermal cracking of carbamide, which is obvious, since overheating of the surface of catalysis can only be achieved by direct excessive heating of the surface of the thermolysis catalyst directly by the heat of the superheated exhaust gases. Regulation of the supply of the flow of the internal heat carrier and the corresponding heat to the thermolysis catalyst is necessary to reduce its temperature and limit the production of ammonia in some operating modes of the internal combustion engine with a reduced generation of harmful emissions. Obviously, within certain limits, the maximum heating temperature during the condensation of the gaseous phase of the internal heat carrier can be increased by any method known from the physics of gases, for example, by raising the internal pressure of the gaseous phase, etc. Heating of the hydrolysis catalyst 11, which requires lower temperatures, can be carried out by the flow of the internal heat carrier in its liquid phase with the required temperature control. At the same time, the electric heater is switched off from work and the load on the electric generator and the ICE power supply system is reduced, which also makes it possible to reduce the fuel consumption for their drive and, accordingly, the release of toxic, harmful components of the ICE exhaust gases. The electrical connections and electrical signal lines in FIG. 2 are not shown conventionally. It is obvious that it is also possible to install a thermal accumulator together with a controlled heat pipe, but this is usually not advisable, since this unnecessarily complicates the design of the unit for heating the catalysts of thermolysis and hydrolysis of harmful thermolysis products. In this case, the system for regulating and controlling the heat pipe with sensors of parameters and process control can be made of known sensors and control and regulation bodies, with already known means of automating this process.

For similar purposes, each of the units 20 for selective reduction and / or oxidation of harmful components of exhaust gases serves, each of which is equipped with at least one controllable heat pipe with a thermal accumulator (not shown in the drawings, since their design is similar, but design features can be very diverse), connected to the exhaust manifold, with a suitable thermal accumulator, with parameter sensors, with controls for the heat transfer process and with a regulation and control system. With an excessive amount of heat for heating the corresponding unit 6 of the catalyst for selective catalytic reduction and / or oxidation of harmful components of exhaust gases and reaching the required temperature for the operation of the controlled heat pipe during its further operation, the heat, similar to heating the thermolysis catalyst, begins to enter the thermal accumulator, in which it heats the corresponding environment, for example, melts a metal with the required melting point or another substance with a change in its state of aggregation. It should be noted that the place of heat input to the hot part of the controlled heat pipe can be combined with the corresponding unit for selective reduction and / or oxidation of harmful components of exhaust gases or performed separately, and the means and controls for the heat transfer process can be made multi-pass, for example, three-pass or more, that is, in accordance with the number of units for selective reduction and / or oxidation of harmful constituents of exhaust gases served by the multi-point controlled heat pipe. After the completion of the process of complete thermal storage, that is, the accumulation of the largest possible amount of heat, the heat transfer process in the controlled heat pipe is forcibly stopped or reduced to the level of replenishing the heat losses in the thermal accumulator. It is obvious that the thermal accumulator must be well insulated from the environment. The heat reserve in it can subsequently be used to heat the corresponding catalyst in the internal combustion engine operating modes, in which the heat of the exhaust gases is insufficient to warm up and / or reach operating temperatures of the corresponding at least one unit of the catalyst for selective catalytic reduction and / or oxidation of harmful components exhaust gases. The organization and means of regulating electrical and mechanical connections with a thermal accumulator, with parameter sensors, with controls for the heat transfer process and with a regulation and control system can be varied, and a complete, detailed and detailed description of each design option, means and sequence of the heat pipe control process in the volume of this proposal cannot fit and for this reason is not given. The most demanded mode for this will be in the process of starting a cold engine, in which, due to increased fuel consumption at the stages of start-up and warm-up and due to cold parts of the internal combustion engine, an increased release of toxic components of exhaust gases occurs, and heat is needed to heat the corresponding catalyst blocks. Similar processes occur at idle, especially in cold weather, as well as at acceleration, maximum power and rotation speed, when the temperature and aerodynamic processes of mixture formation and combustion are difficult or not stationary. It should be noted that, by its physical nature, each heat pipe is a self-regulating device, since more intense cooling of the cold part, in which condensation from the gaseous phase into the liquid internal coolant occurs, causes an intensification of the movement of its gaseous phase to it and, accordingly, an increase in the flow of heat, only in this case, the hot part should also be heated sufficiently intensively.

In addition, when changing the operating mode of the internal combustion engine, it is difficult to achieve a prompt response to the total mass of ammonia supply necessary for neutralizing all NO _{x by} conventional means, since heating the catalyst by electric current due to its inertia and subsequent slow contact sequential heat transfer by materials using their thermal conductivity. For this reason, the heating of the thermolysis catalyst by electricity and the supply of carbamide in the solid phase must be started ahead of time before the rotation speed or load increases, taking into account the time spent on carrying out chemical transformation reactions. This is especially true for the operation of motor transport ICEs during their operation in the urban cycle, which includes their operation in non-stationary modes, such as at idle, during acceleration and deceleration.

Based on the above, the following can be stated.

The technical problem posed is solved by technical means and can be used in the proposed form in the national economy, therefore, the proposal meets the criterion of the invention "industrial applicability".

The proposal differs from the design and the sequence of operation of the known device, therefore, meets the criterion of the invention "novelty".

The proposal, with the implementation of all known and new design features, and the sequence of actions during their operation, allows to achieve new previously unknown technical results, therefore, meets the criterion of the invention "inventive step".

Claims (1)

A device for catalytic cleaning of ICE exhaust gases by the method of selective catalytic reduction / oxidation of exhaust gas constituents and the supply of chemically active additives, containing a regulation and control system with parameter sensors and process controls, units for selective catalytic reduction and / or oxidation of harmful exhaust gas constituents, at least , one device for storing and feeding chemically active additives with at least one container and with at least one pneumatic device for dosing and feeding chemically active additives in the solid phase into a thermal reactor, including zones of thermolysis of chemically active additives in the solid phase with a unit for heating catalysts for thermolysis and hydrolysis of harmful products of thermolysis in the gas phase to simple substances, an outlet ejector of pneumatic feed to the exhaust manifold to the corresponding catalyst unit for selective catalytic reduction of reactive additives in the gas phase, characterized in that the unit for heating the catalysts of thermolysis and hydrolysis of harmful thermolysis products is additionally equipped with at least one controlled heat pipe connected to the exhaust manifold, with a regulation and control system, with parameter sensors and with controls for the heat transfer process , and each of the units for selective reduction and / or oxidation of harmful components of exhaust gases is equipped with at least one controllable heat pipe with a thermal accumulator connected to the exhaust manifold, with a thermal accumulator, with parameter sensors, with controls for the heat transfer process and with a control system, and management.

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