JPS5857612B2 - Pilot injection method and device in pre-combustion chamber type diesel engine - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a pilot injection method and apparatus for reducing NOx, improving fuel efficiency, and improving ignitability by performing pilot injection prior to main injection in a diesel engine.

Diesel engines use a method to suppress diesel knock by performing pilot injection prior to main injection.

This pilot injection is known to reduce the amount of NOx generated during combustion because the pressure rise at the initial stage of combustion is gradual.

Conventional pilot injection has been carried out using a single injection valve, but it has the disadvantage that controlling the timing of main injection and sub-injection and the amount of combustion is complicated and difficult.

On the other hand, it is also known to provide a main injection valve and a sub-injection valve to perform main injection and sub-injection.

This two-injection valve system similarly prevents diesel knock and reduces the amount of NOx produced.

In all of the above-mentioned known Q) pilot injection devices, the direction of pilot injection and the direction of main injection are the same, and as a result, they could not be said to be sufficient in terms of NOx reduction and fuel efficiency. .

SUMMARY OF THE INVENTION An object of the present invention is to provide a pilot injection method and apparatus for a diesel engine that selects the optimum pilot injection direction and thereby improves fuel efficiency and reduces NOx.

This will be explained in detail below with reference to the drawings.

FIG. 1 is a schematic exploded view showing one embodiment of the present invention.

The illustrated diesel engine is a pre-combustion chamber type diesel engine, and the cylinder head 1 is penetrated through the pre-combustion chamber body 2.
is provided toward the main combustion chamber 3 , a precombustion chamber 4 is formed within the precombustion chamber body 2 , and the precombustion chamber 4 and the main combustion chamber 3 are communicated through a port 5 .

A main injection valve 6 and a sub-injection valve 7 face the pre-combustion chamber 4, and a plug 8 is further provided.

The nozzle 9 of the main injection valve 6 is directed toward the port 5 , and the nozzle 10 of the sub-injection valve 7 is directed toward the vicinity of the nozzle 9 of the main injection valve 6 .

The vicinity of the nozzle 9 of the main injection valve 6 is a reservoir in which high-temperature combustion gas generated by the spray injected by the sub-injection valve 7 accumulates.

This reservoir consists of a relatively narrow recess, and the spray from the main injection valve passes through the high-temperature gas region, thereby promoting the generation of flame kernels, which will be described later.

Although the main injection valve 6 and the sub-injection valve 7 are each supplied with fuel from separate injection pumps, a single injection pump may have a structure in which many cylinders are provided.

A water jacket 11 is formed around the pre-combustion chamber body 3 in order to cool the pre-combustion chamber body 2 .

In the present invention that has been stolen as described above, before the piston *12 reaches the top dead center (TDC), fuel is first injected as a pilot from the sub-injector 7 as shown in Pl. It is directed near the nozzle 9 to generate a flame kernel C near the nozzle 9.

Next, main injection Q1 is performed from the injection port 9 of the main injection valve 6.

Since this main injection Q1 is performed through the flame kernel C generated by the pilot injection P1, the ignition delay of the main injection Q1 is reduced and rapid combustion is prevented.

Therefore, the amount of NOx produced is also reduced as much as possible.

Hereinafter, data according to one embodiment of the present invention will be analyzed.

In FIG. 2, the horizontal axis shows the pilot injection ratio (%), and the vertical axis shows the NOx reduction rate.

Note that the pilot injection ratio here refers to the ratio of pilot injection to main injected fuel in the case of no pilot injection.

In FIG. 3, the horizontal axis shows the specific fuel efficiency rate, and the vertical axis shows the NOx reduction rate.

For the data in FIGS. 2 and 3, as a comparison target of the present invention, the pilot injection is injected in the same direction as the main injection as shown in P2 in FIG. 1.

The test engine was a 4-stroke diesel engine of 1800 cc and a compression ratio of 18, and a load rate of 3/4 (excess air ratio of 1.75) was selected to produce the highest amount of NOx emissions at 1600 rpm.

Furthermore, the plot marks in FIGS. 2 and 3 correspond to the conditions shown in Table 1 below.

As can be seen from FIG. 2, the amount of NOx gradually decreases as the pilot injection ratio increases, but when the pilot injection ratio exceeds 10%, the NOx reduction rate becomes almost flat.

This tendency is almost unrelated to the conditions in Table 1.

However, looking at Figure 3, it is clear that the direction of pyloft injection has a large effect on the specific fuel efficiency.

That is, a case where the pilot injection direction is the same as the main injection direction is represented by A in the figure, and a case where the pilot injection direction is in the opposite direction is represented by B in the figure.

Since line B is always below line A, fuel efficiency will improve if the same reduction in NOx is to be achieved.

Among these, under the conditions of pilot injection timing of 25 degrees before TDC and main injection timing of 5 degrees before TDC, the fuel efficiency decreases by 4 to 5%, about 4%.
It is possible to obtain a NOx reduction of 0%.

Note that the pilot injection timing and the main injection timing are not fixed.

Since the above data was taken at 1600 rpm, the optimum value of the injection timing changes depending on the engine speed.

Therefore, the most important point of the present invention is that a flame kernel is formed in advance near the nozzle of the main injection valve, and it is sufficient that the flame kernel is already formed when performing the main injection.

As explained above, in the present invention, a flame kernel is generated near the nozzle of the main injection valve, and it is possible to reduce NOx with lower fuel consumption than other pilot injection methods.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view showing one embodiment of the present invention, and FIG. 2 is a comparison between facing injection and co-direction injection of the present invention.
Figure 3 is a diagram showing the x reduction rate - pilot injection ratio, and shows a comparison between the opposed injection and the same direction injection of the present invention.
It is a diagram showing Ox reduction rate-specific fuel consumption rate. 4: Pre-combustion chamber, 6: Main injection valve, 7: Sub-injection valve.

Claims (1)

[Scope of Claims] 1 Pre-combustion - A fuel injection method for a diesel engine in which a main injection valve and a sub-injection valve are placed in a room, and the sub-injection valve performs a low injection prior to main injection from the main injection valve, A pilot injection is performed near the nozzle of the main injection valve, and high temperature combustion gas is generated by pilot spray near the nozzle of the main injection valve, and the pilot injection amount is 10% of the total injection amount, and the pilot injection amount is 10% of the total injection amount. A pilot injection method in a pre-combustion chamber type diesel engine, characterized in that the main injection passes through high-temperature combustion gas. 2. In a diesel engine fuel injection system in which a main injection valve and a sub-injection valve are arranged in a pre-combustion chamber and a pilot injection is performed from the sub-injection valve prior to main injection from the main injection valve, The main injection direction and the pilot injection direction from the sub-injection valve are substantially opposite directions, and the sub-injection valve is provided so that its spray is directed to the injection hole of the main injection valve, and the pilot injection direction from the sub-injection valve is A pilot injection device for a pre-combustion chamber diesel engine, characterized in that the injection amount is 10% of the total injection amount.