SU550485A1 - The method of regulating the internal combustion engine and device for its implementation - Google Patents

Description

one

The invention relates to the field of mechanical engineering, in particular engine building.

Methods are known for regulating internal combustion engines. The efficiency of internal combustion engines under partial load conditions is reduced due to deteriorating conditions. mixture formation and combustion of fuel, and frequent and abrupt changes in loads lead to premature failure of the cylinder-piston group parts. To eliminate the disadvantages noted above, the fuel supply to a part of the cylinders is shut off, while the remaining cylinders operate with a load close to the nominal, which ensures that relatively high economic performance is maintained.

Devices are known for carrying out a method for controlling an internal combustion engine, comprising nozzles installed in cylinders, each of which is in communication with a fuel pump during a pipeline.

Devices are known in which the fuel supply is disconnected by withdrawing the fuel pump rail to zero iodine.

In the process of adjusting the engine in a manner known per se, the temperature conditions of the cylinder components with the fuel supply turned off are significantly different from the temperature conditions of the other cylinders. When cylinders are put into operation, additional thermal stresses arise in their parts, which reduces their durability and reliability of the engine. In addition, during the period of stabilization of the temperature regime, after the cylinder is put into operation, the efficiency of using the fuel burned in these cylinders somewhat decreases.

In order to increase the reliability and efficiency of the engine, the fuel supply to the cylinder is turned off for one cycle alternately, and the cycles with the fuel supply turned off alternate at regular intervals. In the device for

implementation of the described method in the discharge line of each fuel pump has a shut-off valve with a drive connected to the crankshaft via an interrupter. The drive can be made in the form of an electromagnet connected with one of its terminals to the current source, and the other to the distributor connected to the same source, equipped with moving and fixed contacts, the first of which is connected

with crankshaft.

FIG. 1 is a schematic diagram of the device described; in fig. 2 - distributor, longitudinal section; in fig. 3 - the same cross section; in fig. 4 - zinc valve-type organ.

Six fuel pumps 1 are each connected via their injection line 2 with a nozzle 3 installed in one of the diesel cylinders. In each line there is a locking body 4 (Fig. 1, in accordance with cylinder numbers IVI IV2, IVZ, IV4, IVB, IVB. Each of the locking bodies is equipped with an electromagnetic drive 5 connected by one of its terminals to the current source 6 and the other to the connected with the same source to the distributor 7. The distributor shaft 8 is kinematically connected to the diesel engine crankshaft and equipped with a movable contact 9 (VK) fixed to it. The fixed contacts 10 (Fig. 1, Кь К2, Кз, К4, Ks and Кб in accordance with the numbers cylinders) placed in a fixed cover 11 bldg Usa 12 distributor.

The locking member is in the form of a spool, the body 13 of which is fastened with the help of fittings in the discharge line of the fuel pump. The plunger 14 of the spool is made elongated, placed as a core in the coil of the electromagnetic actuator 5 and spring-loaded in the latter by means of a spring 15. The seal between the housing and the plunger is carried out using a bellows 16. A plunger has a channel a, perpendicular to its axis, and a broken channel b, communicated by one of its end openings with the pipeline 17 to drain the excess fuel. A drainage channel is provided in the body to direct fuel leakage between the plunger and the body of the spool into the drain tank.

At the modes of loads close to the nominal, the contacts K are open, the control circuit is de-energized and the engine operates without gaps in the flashes. When the load is reduced, the fuel pump control rail moves to decrease the fuel supply (to the right) and closes contacts K, as a result of which power is supplied to the rotating contact VC of the distributor. In the position shown in FIG. 1, contacts VK and Ki are closed and a pulse is applied to the actuator of the individual switch of the first cylinder. The contact closure time of the contacts VK and Ki coincides with the start of the injection stroke of the plunger of the fuel pump of the first cylinder, and the closure duration is equal to the duration of the injection stroke of the plunger. When a pulse is applied to the spool actuator, the plunger is displaced, and the fuel supply channel to the injectors is closed.

Thus, each pair of contacts (VK and K) serves as a chopper in the supply circuit of the plunger drive current. At the same time, the channel b ensures the transfer of fuel from the injection line to the supply tank, after which the contacts VC and Ki open and the drive is de-energized. When the crankshaft is rotated in the engine, six flashes occur in accordance with the order of operation of the cylinders. Gear ratio i from the crankshaft to the fuel distributor

equal to seven, which ensures the missed outbursts every 420 ° angle of rotation of the crankshaft. As a result, after the shut-off of the first cylinder, the third is shut off, then the fifth and so on. In this way, alternate shut-off of the fuel supply to the cylinder for one cycle at regular intervals is ensured. As the engine load increases, the fuel pump rail moves in the direction of increasing the fuel supply (to the left) and at a position corresponding to the cycle feeds close to the feeds at the nominal load, it opens the contacts K. The engine starts

work without skipping flashes.

The angles of rotation of the crankshaft, through which the individual skips occur, can be calculated by the formula

ALL1 Z k

a ZbO „- -,

where a is the angle of rotation of the crankshaft (in degrees) between the individual gaps of the flashes in the engine cylinders;

The t-factor is 1 for a two-stroke engine and 2 for a four-stroke;

Z is the number of engine cylinders; , 2, 3, ... - dimensionless dimension,

determine ju and the power range in which the adjustment is made.

For example, for a five-cylinder engine, the “+” sign in the formula for the engine will be missing every sixth flash, for - every seventh flash, - every eighth flash, and so on.

The device allows the use of cylinder deactivation to control various power ranges. For example, in the first range - skipping every eighth flash; in the second range - skipping every fourth flash; in the third range, each second flash is skipped with a corresponding decrease in engine power.

The proposed control method and device for its implementation in addition to the economic effect, which is expressed in reducing fuel consumption under partial load conditions and idling the engine, as a result of shutting off the fuel supply to individual cylinders, it maintains the same thermal stress of all cylinders, and there are no abrupt changes in the temperature regime of cylinder-piston parts groups prn turn on and off the cylinder, which increases the reliability and durability of the engine as a whole. In addition, the possibility of applying the method to engines of large dimensions is facilitated. The advantage of the proposed method also lies in the fact that with frequent load changes the temperature drops of the parts are reduced, and the engine

Constantly ready to receive a load up to a nominal load, which is especially important for the main engines of icebreakers, tugboats, and fishing vessels. It should be noted that the invention can be equally successfully used on both two-stroke engines and four-stroke engines.

Claims (4)

1. A method for controlling an internal combustion engine by shutting off the fuel supply to the cylinders, characterized in that, in order to increase reliability and efficiency, the fuel supply to the cylinders is shut off for one cycle in turn. 2. The method according to claim 1, wherein that the cycles with the fuel supply off alternate at regular intervals. 3. A device for implementing the method according to claim 1, containing installed in the cylinders nozzles, each of which is connected to the fuel pump by means of a discharge line, characterized in that a shut-off member with a drive is connected to the crankshaft via an interrupter in the discharge line. 4. The device according to claim 3, characterized in that the drive is made in the form of an electromagnet connected by one of its terminals to the current source and the other to the one connected to the same source to the distributor provided with movable and fixed contacts, the first of which is kinematically connected to the crankshaft. R iiitTJ Ml . (1L .. # 0:, | st: a-1 / Vl fxSSijt / e.-ffe; -a, Schz  - juciif-vm / g 1j ig. one ID A-A FIG. 2 f3