JPH0478830B2 - - Google Patents

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to an engine combustion auxiliary device that can improve the combustion characteristics of the engine by injecting alcohol fuel into the intake pipe immediately before the intake port of the engine. .

[Conventional technology]

Engines, especially diesel engines, use alcohol in addition to light oil as fuel for combustion.
Efforts are being made to improve combustion.

However, in conventional diesel engines that use alcohol in combination with diesel oil, a fuel mixture of diesel oil and alcohol is injected into the combustion chamber from a single nozzle (for example, Japanese Utility Model Application Publication No. 181928/1982), or alcohol is constantly injected into the intake pipe. Since the fuel is injected, the vaporized alcohol makes it difficult for air to enter the combustion chamber, resulting in poor combustion and reduced thermal efficiency.

Furthermore, Japanese Patent Application Laid-open No. 162756/1983 proposes a diesel engine exhaust particulate control device that injects alcohol or water into the intake port.
According to this device, it is determined whether or not to inject alcohol or water depending on the engine speed or load, and the injection amount is adjusted depending on the engine load.

However, since this device does not have a means to detect the crank angle, it is not possible to adjust the injection timing according to changes in engine speed or load, and it is not possible to sufficiently reduce engine compression loss and heat loss. The problem was that I couldn't do it.

On the other hand, Japanese Patent Application Laid-Open No. 57-76235 proposes an electronically controlled fuel injection method for a gasoline engine in which gasoline containing alcohol is injected into the intake port. Since the fuel and alcohol as auxiliary fuel are mixed in advance and injected simultaneously from one injection nozzle, it could not be applied as is to diesel engines.

Furthermore, since the throttle switch described in this publication detects the fully closed state of the throttle valve, it cannot detect the load state of the engine, and therefore does not perform injection in consideration of the load state. There was a problem that the timing could not be adjusted.

[Purpose of the invention]

The purpose of the present invention is to solve the problems of the conventional diesel engine that uses alcohol as a fuel, to prevent the loss of fresh air in the intake stroke, and at the same time reduce the temperature and pressure just before compression to reduce heat loss. To provide an excellent combustion auxiliary device for a diesel engine capable of improving combustion by increasing thermal efficiency by reducing engine speed and adjusting injection timing according to fluctuations in engine speed and load. It is.

[Structure of the invention]

The combustion auxiliary device for a diesel engine according to the present invention that achieves the above object includes a solenoid valve disposed in a fuel injection pipe that connects an alcohol supply source with a nozzle that injects alcohol toward an intake port, and The angle is compared with an injection start timing angle determined by detecting the load and rotational speed, and a fixed injection end timing angle, respectively, and the difference between the injection start timing and the injection end timing immediately before the end of the intake stroke is determined. and a control device that operates the electromagnetic valve to inject alcohol from the nozzle.

〔Example〕

Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 shows the configuration of a combustion auxiliary device for a diesel engine according to the present invention. A fuel injection nozzle 4 for injecting alcohol is provided in an intake port 2 immediately before an intake valve 3 of each cylinder of the engine 1. This fuel injection nozzle 4 is a fuel injection pipe 6 with an electromagnetic three-way valve 11 installed in the middle, and a fuel injection pump 7.
The fuel injection pump 7 is connected to the alcohol tank 5 through a fuel supply pipe 8. 9 is an alcohol return pipe connecting the alcohol tank 5 and the electromagnetic three-way valve 11;
When the power is not energized, the “black” and “black” are connected,
Alcohol from a constantly operated fuel injection pump 7 is returned to an alcohol tank 5 through an alcohol return pipe 9.

On the other hand, the solenoid 11A of the electromagnetic three-way valve 11 is connected to the control device 10.
1A is energized by the control device 10, the communication of the electromagnetic three-way valve 11 is switched from the "black"-"black" state to the "white"-"white" state, and the alcohol from the fuel injection pump 7 is injected into the fuel. Alcohol is supplied to a fuel injection nozzle 4 through an injection pipe 6, and alcohol is injected from the fuel injection nozzle 4 into the intake port 2.

A load signal L from a load detector 12 attached to the engine 1, a crank angle signal C from a crank angle detector 13, and a rotation speed signal N from a rotation speed detector 14 are input to the control device 10. , the control device 10 uses these signals L, C, and N to adjust the angle of 20 to 30 degrees just before the end of the intake stroke of each cylinder.
The solenoid 11A of the electromagnetic three-way valve 11 is energized to inject alcohol forward (indicated by θa in FIG. 2). Then, the energization is terminated slightly before the intake valve closing timing of each cylinder (indicated by θe in Fig. 2).
Change the electromagnetic three-way valve 11 from “white” to “white” to “black” to “black”
Switch to communication.

FIG. 3 is a flow chart showing an example of a procedure for controlling the electromagnetic three-way valve 11 of the control device 10. In this example, the control device 10 reads the load A in step, and the reference load value set in the control device 10 in step = 25% (total load = 100%).
Have them compare. If the reading load A does not exceed 25% (NO), the process returns to the step, but if it exceeds 25% (YES), the process moves to the step and the control device 1
0 to read the engine speed Na.

Then, in the step, the engine speed Na is
If the engine speed Na exceeds 1000 rpm (NO), the process returns to the step, but if the engine speed Na exceeds 1000 rpm (YES), the process moves to the step and causes the control device 10 to read the current crank angle θa.

Here, when the alcohol injection start angle at the maximum engine speed N _nax = θ ₀ , the alcohol injection start angle at a certain load A and a certain engine speed Na, θ = θ ₀ × A / 100 × N _nax /Na The control device 10 is made to calculate in steps,
In the step, the current crank angle θa is compared with the above θ.

When the current crank angle θa has not reached the alcohol injection start angle θ (NO), proceed to step and leave the electromagnetic three-way valve 11 between “black” and “black” to inject alcohol into the intake pipe 3. The process returns to the step without injecting alcohol, but when the current crank angle θa exceeds θ (YES), the process moves to the step and the electromagnetic three-way valve 11 is set to "white" - "white" to inject alcohol. It is injected from the nozzle 4 into the intake port 2.

Then, the process moves to step, where it is determined whether the current crank angle θa exceeds the injection end angle θe (constant regardless of the load A and the engine speed Na). When the current crank angle θa does not exceed the injection end angle θe (NO), the process returns to the step to continue the communication between "white" and "white" of the electromagnetic three-way valve 11, but when the current crank angle θa reaches the end of injection. If the angle θe is exceeded (YES), proceed to step, return the electromagnetic three-way valve 11 to “black”-“black” communication, stop alcohol injection from the fuel injection nozzle 4 into the intake port 2, and proceed to step. Returning to , alcohol injection in this intake stroke is completed, and preparations are made for alcohol injection in the next intake stroke.

As described above, according to the diesel engine combustion auxiliary device of the present invention, since alcohol is injected from the fuel injection nozzle 4 into the intake port 2 in the second half of the air stroke, a decrease in fresh air can be prevented. In addition, when alcohol is injected, the intake air temperature decreases due to the heat of vaporization, and the temperature immediately before the compression stroke decreases.
Since the pressure decreases, compression loss can be reduced due to the pressure decrease, and heat loss can be reduced due to the temperature decrease.

〔Effect of the invention〕

As explained above, the diesel engine combustion auxiliary device of the present invention includes a solenoid valve disposed in the fuel injection pipe connecting the alcohol supply source to the nozzle that injects alcohol toward the intake port, and The angle is compared with an injection start timing angle determined by detecting the load and rotational speed, and a fixed injection end timing angle, respectively, and the difference between the injection start timing and the injection end timing immediately before the end of the intake stroke is determined. , and a control device that operates the electromagnetic valve to inject alcohol from the nozzle, the following effects can be achieved.

The injection start timing for injecting alcohol into the intake port can be adjusted just before the end of the intake stroke, depending on changes in engine speed and load.

Therefore, it is possible to extremely efficiently prevent a decrease in fresh air in the intake stroke and to prevent compression loss and heat loss in the compression stroke, resulting in improved combustion, thermal efficiency, and smoke. There is.

[Brief explanation of the drawing]

FIG. 1 is a schematic diagram showing the configuration of a combustion auxiliary device for a diesel engine according to the present invention, and FIG. 2 is a diagram showing the timing of alcohol injection by the combustion auxiliary device for a diesel engine according to the present invention.
Exhaust valve lift diagram FIG. 3 is a flowchart showing an example of a control procedure of the combustion auxiliary device for a diesel engine according to the present invention. 1... Engine, 2... Intake port, 3... Intake valve, 4... Fuel injection nozzle, 5... Alcohol tank, 6... Fuel injection pipe, 7... Fuel injection pump, 8... Fuel supply pipe , 9... Alcohol return pipe, 10... Control device, 11... Solenoid three-way valve, 1
2...Load detector, 13...Crank angle detector, 14...Rotation speed detector.

Claims (1)

[Claims] 1 A solenoid valve is installed in the fuel injection pipe that connects the nozzle that injects alcohol toward the intake port and the alcohol supply source, and the injection is determined by detecting the crank angle, load, and rotational speed of the engine. By comparing the start timing angle and a certain injection end timing angle, it is possible to determine whether the injection start timing and the injection end timing are between the injection start timing and the injection end timing immediately before the end of the intake stroke.
A combustion auxiliary device for a diesel engine, comprising: a control device that operates the solenoid valve to inject alcohol from the nozzle.