Abstract
The problem of negative impact on the environment of motor transport is one of the most fundamental in the complex of global problems. The constant increase in the number of cars with internal combustion engines encourages the search for methods and ways to reduce the volume of negative impulses. The operation of heat engines is accompanied by significant emissions of gaseous harmful substances into the atmosphere, i.e. nitrogen oxides, carbon monoxide, hydrocarbons, as well as solid particles, including soot. The solution to this problem should be implemented within the framework of a systematic approach. To do this, it is necessary to combine the study of technical, economic, and organizational approaches to the organization of the exhaust gas disposal process. To date, there is a significant methodological base in the field of organizational and economic decisions. The article discusses various methods of cleaning exhaust gases of piston engines, their advantages and disadvantages are noted. The method of processing using ammonia is widely known. It is noted that a catalytic method for reducing nitrogen oxides using ammonia is quite economical. However, the optimal temperature range at which nitrogen oxides are reduced is rather narrow. To solve this problem, it is proposed to use the vortex effect in the exhaust system. The efficiency of using a vortex gas recirculation pipe is due to its significant influence on the thermal gasdynamic processes occurring in the exhaust system. Using the principles of non-equilibrium thermodynamics allows us to take into account dissipative processes when establishing the relationship of fuel and economic indicators of internal combustion engines with thermodynamic parameters. This significantly increases the accuracy of calculations and allows you to develop measures to reduce the level of negative impact on the environment.
Highlights
Environmental issues are becoming more and more acute
Exhaust gases (EG) of diesel power plants (DPP) are a complex multicomponent mixture of gases that contain more than 250 components, including products of complete fuel combustion and substances formed at high temperatures (nitrogen oxides ((NOx), products of incomplete fuel combustion), as well as sulfur oxides, aldehydes, etc. [1, 2]
Analysis of the main factors affecting the formation of harmful substances in diesel engines has shown that due to the peculiarities of the working process occurring in them, a decrease in emissions of incomplete combustion products, carbon oxides, hydrocarbons and harmful particles is accompanied by an increase in emissions of nitrogen oxides and by contrast [1, 2, 4, 5, 6]
Summary
Environmental issues are becoming more and more acute. At the same time, one of the sources of toxic substances released into the atmosphere is diesel power plants (DPP). Exhaust gases (EG) of DPP are a complex multicomponent mixture of gases that contain more than 250 components, including products of complete fuel combustion and substances formed at high temperatures (nitrogen oxides ((NOx), products of incomplete fuel combustion (carbon monoxide , hydrocarbons , soot)), as well as sulfur oxides, aldehydes, etc. Analysis of the main factors affecting the formation of harmful substances in diesel engines has shown that due to the peculiarities of the working process occurring in them, a decrease in emissions of incomplete combustion products, carbon oxides, hydrocarbons and harmful particles is accompanied by an increase in emissions of nitrogen oxides and by contrast [1, 2, 4, 5, 6]. To ensure that diesel meets current and future standards for harmful emissions, exhaust gas recirculation and a catalytic method for their recovery are widely used to reduce nitrogen oxide emissions [7, 8, 9, 10,11,12]
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