RU2163975C1 - Internal combustion engine operation method - Google Patents

Abstract

FIELD: mechanical engineering; internal combustion engines. SUBSTANCE: according to proposed method of operation of internal combustion engine on fuel with high temperature of self-ignition, energy required for self-ignition of fuel at end of mixture compression in cylinder is received from residual gases. EFFECT: simplified design and operation f engine. 4 cl, 2 dwg

Description

 The invention relates to the field of engine building and hydrocarbon processing technology.

 It is known that when self-ignition engines, for example, gaseous mixtures based on methane, are used in internal combustion engines with a high temperature, an external energy supply is used to ignite them.

 Known methods of forced ignition of a mixture: spark and ignition dose of flammable fuel, for example, diesel. According to the first method, gas engines work, according to the second - gas diesel engines. In this case, with an increase in the amount of mixture in the cylinder, determined, ceteris paribus, by pressure, the required ignition energy increases. In the case of spark ignition, this requires increasing the life of the candle, which is the bottleneck in the implementation of this method. Today, new types of external energy sources are being developed that are intended to replace traditional ones - laser, plasma, plasma-chemical, etc. As a firing dose of flammable fuel, in order to replace diesel fuel in gas diesel engines, special chemical initiators of combustion are used (see, for example, Yu.N. Vasiliev, LS Zolotarevsky, SI Ksenofontov. Gas and gas-diesel engines. M: VNIIgazprom, 1992, p. 102-105).

Known methods of operating an internal combustion engine in which the self-ignition temperature of the fuel at the end of compression is achieved by increasing the temperature of the fresh charge (air or mixture) entering the cylinders at the time of filling by preheating it (see, for example, RU, patent N 2096313 , class C 01 B 3/36, 1996. "A method for producing synthesis gas"). So, in the mentioned method for producing synthesis gas based on methane conversion, the ignition of the gas-air mixture is ensured by its preliminary heating in an external heat exchanger to a temperature of 200 - 450 ^o C.

 This method by technical nature is the closest to the claimed and is selected as a prototype.

 The prototype method has a significant drawback, which consists in heating the intake manifold (receiver of the cylinder block), and therefore it is necessary to introduce structural measures for its thermal insulation.

 The invention aims at simplifying the method of operation and simplifying the design of an internal combustion engine.

 These problems are solved in the method of operation of an internal combustion engine that uses fuel with a high ignition temperature, and therefore requires an external supply of energy to ignite it, in which the energy necessary for self-ignition of the fuel at the end of compression of the mixture in the cylinder is obtained from residual gases, amount which are selected by stopping the discharge of exhaust gases from the cylinder during their forced ejection, and air or mixture is supplied to the cylinder at the moment when the ingress of residual gas is excluded in a receiver in a dangerous amount whereby if necessary reduction of the quantity of air (mixture) in a cylinder compensate increase boost pressure.

 The difference of the proposed method lies in the fact that the energy necessary for self-ignition of the fuel at the end of compression of the mixture in the cylinder is obtained from the residual gases, the amount of which is selected by stopping the exhaust gas from the cylinder during their forced ejection, and the air or mixture is fed into the cylinder the moment when the ingress of residual gases into the receiver in dangerous quantities is excluded, and if necessary, the decrease in the amount of air (mixture) in the cylinder is compensated by increasing the boost pressure.

 The first variant of the proposed method is characterized in that depending on the purpose of the engine and its operating modes, the gas distribution phases are adjustable. The second option is distinguished by the fact that it is used in engines running on any type of fuel in order to reduce harmful emissions (primarily NOx). The third variant of the method is characterized in that it is used for a gas engine with spark ignition at low loads and idling with the aim of additional supply of energy and enrichment of the mixture, which eliminates the use of additional structural measures, for example, a prechamber.

 The essence of this invention lies in the fact that the temperature necessary for self-ignition of the fuel at the end of the compression stroke is obtained by heating a fresh charge upon receipt of residual gases from the cylinder, the amount of which is selected depending on the operating conditions. The necessary amount of residual gases is provided by stopping their withdrawal from the cylinder during forced ejection: in a four-stroke engine - when the piston moves to TDC at the exhaust stroke; in a two-stroke engine - purge air during gas exchange.

For example, for a four-stroke engine, the required amount of residual gas in the cylinder is achieved by changing the valve timing: the end of the closing of the exhaust valve is set in the range of 60 ^o p.p. to TDC - 20 ^o p.c. behind TDC, when the amount of residual gases is significant and they have high thermal energy (enthalpy); the beginning of the opening of the intake valve at the moment when ingress (throwing) in dangerous (from the point of view of ignition of the fuel charge) amounts of residual gases into the receiver is excluded, for example, at moments from 10 ^o p.p. to TDC up to 50 ^o p.p. for TDC. The phase values depend on the required amount of residual gases and the instantaneous ratio of the effective flow area of the valves and the cylinder volume described by the piston.

 The temperature of the mixture necessary for self-ignition of the fuel at the end of the compression stroke can also be achieved by selecting the following parameters: the degree of compression in the cylinder, the degree of pre-cooling (heating) of the air or mixture before being fed to the receiver, and the coefficient of residual gases depending on the engine operating mode and mixture composition. To ensure engine operation in a wide range of valve timing modes, they can be adjustable.

By increasing the amount of inert residual gases, the maximum temperature of the cycle is reduced and due to this, the emission of nitrogen oxides in the exhaust gases of engines operating on any type of fuel is reduced. The enrichment of the mixture to α = 0.36 - 0.45 and obtaining a temperature in the cylinder of 1300 - 2300 ^o C for a period of 10 ^-2 - 10 ^-3 s with a crankshaft rotation speed exceeding 350 min ^-1 provide the engine to work in synthesis generator mode gas.

 The proposed method, for example, in contrast to the known recirculation method, when exhaust gases are returned to the diesel inlet, ceteris paribus, does not require gas purification (eliminates coking of the intake duct of the engine and, above all, the charge air cooler, if any) and has a higher energy consumption residual gases.

 The loss of the fraction of fresh charge in the cylinder caused by an increase in the amount of residual gases, if necessary, is compensated by an increase in boost pressure.

 An example of the operation of an engine of type D49 (CHN26 / 26) in this method is illustrated by the FIGS. 1 and 2.

Figure 1 shows the dependence of the change in the amount of residual gases γ _r and the amount of gas reflux into the intake manifold (receiver) γ _zk depending on the angle of the opening opening of the intake valves φ _n.vp and two values of the angle of the end of the closing of the exhaust valves φ _{K. vyp.} : 1 - 335 ^o p.v. angle, 2 - 345 ^o p.v. angle

In FIG. Figure 2 shows the dependences of the temperature of the mixture at the end of the compression stroke T _s in the cylinder of the engine ЧН 26/26 on the angle of the beginning of opening of the intake valves φ _n.p.
The calculation results obtained by numerical simulation of the working process show that heating the fresh charge from the residual gases ensures the temperature of the mixture at the end of the compression stroke at a level sufficient for self-ignition of a fuel with a high ignition temperature. For example, for methane, the temperature at the end of the compression stroke is T _s = 1200-1300K. In the calculation, it was assumed that the mixture was not preheated at the cylinder inlet.

From the condition of maintaining the amount of fresh charge in the cylinder, the boost pressure increased. For this reason, the charge density increases, and when the intake valves are opened earlier, the temperature of the compression end T _s also rises. However, when the phase of the inlet start is changed in the advance direction, the fraction of residual gases γ _zk thrown into the inlet receiver increases, and the danger of igniting the fuel charge in the receiver increases.

From the experience of gas-diesel engines (for example, 12CHN26 / 26 at PE-6 stations), it is known that the amount of gas throwing into the receiver up to 5% of the initial charge in the cylinder does not lead to disruptions in the normal operation of the diesel engine or to gas flashes in the receiver. If we take the indicated value of 5% permissible, and also taking into account that the gas temperature decreases sharply when throttling in the slots of the intake body, then for the engine to work according to the proposed method, the following valve timing will be best:
the end of the closing of the exhaust valves 25 degrees. p.c. to TDC;
beginning of the opening of the intake valves 15 degrees. p.c. for TDC.

In this case, the fraction of residual gases in the cylinder (coefficient of residual gases γ _r ) is 0.14-0.18 of the mixture volume. Figures 1 and 2 also show that when the outlet valve is closed ahead of time, the efficiency of internal energy supply increases.

Claims (4)

 1. The method of operation of an internal combustion engine using fuel with a high ignition temperature, and therefore requiring an external supply of energy to ignite it, characterized in that the energy necessary for self-ignition of the fuel at the end of compression of the mixture in the cylinder is obtained from residual gases, amount which are selected by stopping the discharge of exhaust gases from the cylinder during their forced ejection, and the air or mixture is fed into the cylinder at the moment when the ingress of residual gases into the iver in dangerous quantities, and if necessary, a decrease in the amount of air (mixture) in the cylinder is compensated by an increase in boost pressure.  2. The method according to p. 1, characterized in that depending on the purpose of the engine and its operating modes, the gas distribution phases are adjustable.  3. The method according to claim 2, characterized in that it is used in engines operating on any type of fuel in order to reduce harmful emissions (primarily Nox).  4. The method according to claim 1, characterized in that it is used for a gas engine with spark ignition at low loads and idle for the purpose of additional energy supply and enrichment of the mixture, which eliminates the use of additional structural measures, for example, a pre-chamber.

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