RU2006611C1 - Method of operation of diesel internal combustion engine - Google Patents

Abstract

FIELD: engine engineering. SUBSTANCE: air is throttled and oxygen content of the air is increased before injection to cylinders of the engine. Phase of injection of a coolant into the cylinders, which is overheated by exhaust gases, and a coolant of a cooling system is in the range: at 5-0 before the beginning of the fuel the injection begins, at 5-10after the top dead center injection ends. EFFECT: enhanced efficiency of the engine and decreased toxicity of exhausts owing to decreasing pressure at the end of compression stroke. cl, dwg

Description

 The invention relates to mechanical engineering, more specifically to internal combustion engines.

Known technical solutions for increasing power, improving the efficiency of internal combustion engines and reducing exhaust toxicity by introducing into the composition of the working fluid refrigerant water or liquid in an evaporated or drip-liquid state. When water is supplied to the internal combustion engine at the end of the compression stroke - the beginning of expansion, a reduction in the exhaust gas toxicity by NO _x decreases and the mass of the working fluid decreases, while the average molecular weight (μ) and the expansion polytropic index (n ₂ ) and the characteristic gas constant increase ( R) the working fluid on the expansion stroke, which leads to an increase in the expansion work, and therefore, improves the power and fuel and economic characteristics of the internal combustion engine (prototype US patent N 4408573, CL 123-25, 1983). At the same time, heating the injected water (water-water emulsion, another liquid) with the heat of the exhaust gas and the cooling agent of the cooling system allows to reduce the cost of the heat released during combustion of the fuel to heat the injected liquid and increase the injection dose, but in this case it is advisable to increase the dose only to a maximum up to 40-70% of the fuel mass, since a large dose reduces the thermodynamic parameters of the working fluid at the expansion stroke, which means that the power of the internal combustion engine also worsens its economy (Somov V.A. and Ischuk Yu. G. Ship multi-fuel e engines AL:. Shipbuilding, 1983, p 240), whereas at higher doses the water injection work is possible further expansion growth by further reducing μ n and _2, and larger R, that when the internal combustion engine by known processes can not. to be achieved.

 Technical solutions are also known in which, due to the throttling of the fresh charge at the inlet of the ICE at idle (application Germany No. 2906915, class F 02 D 9/00) and low loads, they reduce the cost of compressing the fresh charge of the DS, which increases the power and improves the efficiency of ICE. However, at regimes close to the rated power, throttling leads to insufficient oxygen in the working mixture necessary for fuel combustion, which causes a drop in power, a decrease in efficiency and an increase in exhaust toxicity due to an increase in incompleteness of fuel combustion.

 Known technical solutions that provide the internal combustion engine during oxygen enrichment (CO) of a fresh charge by, for example, adding oxygen (ozone) that is present when the engine is in a reduced, compressed, or chemically bound form, or, which is more promising, by separating non-oxygen components from the incoming in the internal combustion engine of air directly on the engine using electromagnetic separation (application of Germany N 3013673, class F 02 M 33/00), centrifugal separation (application of Japan N 61-28750, class F 02 M 33/00), separation of air into gas membranes (aut St. USSR N 853133, class F 02 B 51/00). Due to KO of the working fluid, the toxicity of internal combustion engine exhaust is reduced for some components with a slight increase in power and improved fuel economy of internal combustion engines (see Abstract Journal of Internal Combustion Engines, separate issue of the USSR State Committee for Science and Technology, USSR Academy of Sciences, VINITI, 1988, N 7, p. 35 1988, N 12, p. 25, 1987, N 3, 1978, N 5, p. 40). This is due to a reduction in the induction period, an increase in the speed and completeness of fuel combustion.

However, the thermodynamic parameters of the filling and compression processes are retained in the well-known schemes for SC, the whole positive effect is caused by an increase in the combustion parameters, in particular, the combustion rate, which increases the average pressure of the cycle (Kuznetsov E.V. Effect of oxygen concentration on the engine process. 1956, p; 107-114). At the same time, a significant part of the energy received during fuel combustion is expended on the compression of a part of the working fluid that is not involved in the combustion process (mainly molecular nitrogen N ₂ ), and an increase in the combustion temperature leads to an increase in the emission of nitrogen oxides with exhaust gases (OG).

 The aim of the invention is to increase the effective performance of ICE.

This goal is achieved by the fact that the fresh charge is throttled to the inlet to the DS, its oxygen content is increased, the refrigerant injection phase is maintained in the interval: the beginning of injection - for 5-0 ^about crankshaft rotation (PCV) before the start of fuel injection, the end of injection - for 5- 10 ^{about the} rotation of the crankshaft after top dead center (TDC).

Due to the throttling of the fresh charge on the intake pressure is reduced end filling (P _a), which reduces the working fluid compression energy cost to the declining in view of this end of compression pressure (P _s), but the temperature at the end of compression in this case is sufficient for auto-ignition of diesel fuel ( applications from Germany, class F 02 D 9/00, F 02 D 39/02, N 2906915) even at P _a = 0.015 MPa. Ignition of fuel from an external source, such as a spark plug, at such P _a occurs in carburetor ICEs under low load conditions without difficulty.

When water is injected into the working fluid, the working fluid with a higher water content, and, therefore, with a lower average molecular weight (μ) and a larger characteristic of the gas constant (R) than during compression, will already expand in the internal combustion engine, and the increase in the water content of the working fluid reduces the magnitude of the index of polytropic expansion (n ₂ ). This allows you to compensate for the loss of the working fluid from throttling and, therefore, to maintain and even increase the magnitude of the expansion work compared to a serial ICE. The presence of water makes it possible to prevent an increase in the combustion temperature, leading to an increase in the emission of nitrogen oxides from the exhaust gas.

 Since the amount of work spent on compressing the working fluid decreases, and the work obtained during expansion is maintained unchanged and even increases, the total work of the ICE cycle, and hence its efficiency, increases.

 Joint KO and throttling of a fresh charge makes it possible to reduce the work of compression while maintaining in the working fluid the same amount of oxidizing agent-oxygen, which is necessary for combustion of the same dose of fuel as in a serial DVM, and the injection of a large (several times more dose of fuel) amount heated water provides the ability to restore the mass of the working fluid, partially lost during throttling, and this becomes possible only due to the simultaneous KO and throttling at the inlet, which reduces the mass of fresh aryada without reducing the amount of fuel that releases part of the heat released during the combustion of fuel to heat the water injection. At the same time, the presence of a large amount of water makes it possible to prevent an increase in the combustion temperature, and hence the emission of nitrogen oxides from the exhaust gas, not only without a decrease, but even with an increase in the work of expansion relative to the serial ICE due to the increase in mass and the characteristic gas constant of the working fluid to also expand and decrease the magnitude of the indicator of polytropic expansion. This means that a super-effect is observed that is superior to the sum of the effects when the KO is used separately, the fresh charge is throttled at the inlet and the water is injected, and its occurrence is possible only when combined.

 New in the invention is the joint KO and throttling of a fresh charge and the injection of heated water into the internal combustion engine at the end of compression - the beginning of combustion. Comparison with analogues shows that in this case a result is achieved that exceeds the sum of the effects when applied separately. This makes it possible to conclude that the claimed invention meets the criteria of "novelty" and "significant differences".

 The drawing shows a device for implementing the proposed method.

 The device consists of a basic diesel engine 1, a device for enriching air with oxygen, for example, a membrane gas separator 2, a water pump 3, a heat exchanger-recuperator 4, a cooling liquid-injected water, a heat exchanger-recuperator 5, the exhaust gas is injected water, a heat exchanger-recuperator - screen 6, located on the fire bottom of the head of the internal combustion engine, the discharge valve 7, the water tank 8, the pipe 9 for supplying air from the air cleaner 10 through the valve 11 to the gas separator 2 and then to the internal combustion engine 1, the bypass pipe 12 with a throttle 13 and an exhaust pipe 14 with an ejector 15 located in the exhaust tract of the internal combustion engine, and water pipelines - low pressure 16 and high pressure 17.

 The device operates as follows.

The air entering the internal combustion engine through the air cleaner 10 can move into the intake manifold in two ways: through the valve 11 and the gas separator 2, and here the gas mixture (air) enriched with oxygen up to 45% enters the internal combustion engine or through the bypass pipe 12 with the throttle open 13. When this gas mixture (air) with low oxygen content is sucked off by the ejector 15 from the low pressure side of the gas separator 2 in the exhaust path of the internal combustion engine. The total oxygen content of the gas mixture entering the internal combustion engine is regulated by the valve 11 and throttle 13: when the completely throttle 13 and the valve 11 are open, the mixture with the maximum oxygen content (45% oxygen) throttled on the gas separator enters the engine; with a closed valve 11 and an open throttle 13 - ordinary air. At intermediate positions of the valve 11 and throttle 13, the oxygen content of the air entering the internal combustion engine varies from 23 to 45%. The pressure of the end of the filling R _a varies from 0.09 in ordinary air to 0.06 MPa in air with a maximum oxygen content. This allows, with increased oxygen content and reduced mass of the cylinder charge, to supply much more to the cylinder than is possible with traditional ICE methods, the amount of water, the water injected through the pressure valve 7 by the pump 3, taken from the tank 8, is preheated by the heat of the coolant in heat exchanger-recuperator 4, the heat of exhaust gases in the heat exchanger-recuperator 5 and the heat of the burning mixture in the heat exchanger-screen-recuperator 6. Water supply starts at 5-0 ^about PC AT. before the start of fuel injection and ends 5-10 ^about after TDC.

So, when operating a diesel engine according to the claimed method, due to the combined throttling and oxygen enrichment of the fresh charge, the mass of the cylinder charge decreases, which reduces the energy consumption for compression, but the actual amount of oxygen remains the same as a serial diesel engine, which allows you to burn the same amount of fuel that with traditional methods of operation of internal combustion engines. The loss of part of the cylinder charge during throttling is fully compensated by the injection of heated water into the cylinder, which allows you to save or even increase the work of expansion at a moderate value of the highest cycle temperature T _z . As a result, engine power and economy are increased, and as a result of an increase in the oxygen concentration in the mixture and maintaining a moderate temperature T _{z, the} toxicity of the exhaust is reduced.

(P_a· V_a - P_с· V _b) ,
расширение l_p =

(P₂· V_z - P_b· V _b) , где n₁, n₂ - показатели политропы процессов сжатия и расширения;
V_a, V_c, V_z, V_b - соответственно полный объем, объем камеры сгорания ДВС, объем при максимальном давлении сгорания Р_z и объем при давлении конца расширения Р_в.For a serial DVM 4411 / 12.5 with a geometric compression ratio ε = 16, the pressure of the end of filling is P _a ≈ 0.09 MPa, the pressure of the end of compression is P _s ≈4 MPa, and the effective power at a nominal speed of 2200 min ^-1 is N _c = 56 , 6 kW. The equations of thermodynamic work for the polytropic process have the form
compression l _c =

(P _a · V _a - P _s · V _b ),
extension l _p =

(P ₂ · V _z - P _b · V _b ), where n ₁ , n ₂ are the indicators of the polytropic processes of compression and expansion;
V _a , V _c , V _z , V _b - respectively, the total volume, volume of the combustion engine of the internal combustion engine, the volume at the maximum pressure of combustion P _z and the volume at the pressure of the end of expansion P _in .

It can be established by calculation that when the oxygen content of a fresh charge is increased by pumping it through a membrane gas separator based on polyvinyltrimethylsilane membranes to 45 wt. % and dross-sieving of a fresh charge to P _a = 0.06 MPa, P _s decreases to 2.6 MPa and the energy consumption for compressing the charge decreases by almost 40% (by 803.4 nm). It is advisable to heat the water injected into the cylinder sequentially: in the heat exchanger with the heat of the coolant, then with the heat of the combustion products in the exhaust heat exchanger-heat exchanger - water and the heat exchanger-screen mounted on the surface of the cylinder head in contact with the hot working mixture. Moreover, due to water injection, the maximum pressure of the cycle rises, the polytropic exponent n ₂ decreases, and as a result of this, the magnitude of the expansion work is preserved or even slightly increased. As a result, the effective engine power is increased by about 16.5%, and the presence in the working fluid of a greater amount of oxygen and water and a small amount of nitrogen helps to reduce the toxicity of exhaust from nitrogen oxides.

 With a more complete utilization of the heat removed from the internal combustion engine, the dose and temperature of the injected water can be increased, which will further increase the work of expansion. Thermal insulation of parts forming the combustion chamber also allows to increase the effect.

 (56) Application of Germany N 3013673, CL F 02 M 33/00, 1981.

 U.S. Patent 4,408,573, class. 123-25, publ. 1983.

Claims (1)

WAY OF WORKING THE INTERNAL COMBUSTION DIESEL ENGINE by admitting air into the cylinders, compressing it, injecting and igniting the fuel, expanding the products of combustion, converting the energy of the expanding gases into the rotational energy of the shaft and discharging the exhaust gases; exhaust gas of the refrigerant of the cooling system and its injection into the cylinders, characterized in that, in order to increase effective performance, the air in front of the inlet Ohms are throttled into cylinders and its oxygen content is increased and the refrigerant injection phase is maintained in the interval: the beginning of the injection is 5 - 0 ^o turn the crankshaft before the start of fuel injection, the end of the injection is 5 - 10 ^o turn the crankshaft after top dead center.

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