JP5259504B2 - Blow-by gas reduction stop control method at startup - Google Patents

Description

  The present invention relates to an engine capable of reducing the blow-by gas by sucking a blow-by gas containing DME vapor into an air suction port.

  2. Description of the Related Art Conventionally, in an engine using DME (dimethyl ether) as a fuel, a technique for reducing blow-by gas by sucking blow-by gas containing DME vapor into an air intake port is known. Such an engine is provided with a blow-by gas line for sucking blow-by gas generated in the engine into an air suction port. In particular, in order to prevent blow-by gas from being released into the atmosphere, the blow-by gas line is closed while the engine is stopped. When the engine is started, blow-by gas filling the blow-by gas line is sucked into the cylinder. Here, since DME (dimethyl ether) has a high cetane number, it has high ignitability. For this reason, the blow-by gas sucked into the cylinder is self-ignited, so that knocking occurs when the engine is started.

  Patent Document 1 describes a technique for avoiding knocking when starting an engine. In the diesel engine of Patent Document 1, an open line for releasing blow-by gas into the atmosphere is attached to a blow-by gas line for sucking blow-by gas into the air inlet through a three-way solenoid valve. The communication between the blow-by gas line and the open line and the communication between the blow-by gas line and the air inlet are switched by the control of the solenoid valve. While the engine is operating, blow-by gas is sucked into the air inlet, and when the engine is stopped, blow-by gas is released into the atmosphere. For this reason, the blow-by gas is prevented from accumulating in the blow-by gas line when the engine is started. As a result, the occurrence of knocking at the start is prevented.

Japanese Patent Laid-Open No. 10-339126

  In Patent Document 1, the blow-by gas line and the open line are always in communication while the engine is stopped. For this reason, DME does not reach vapor-liquid equilibrium, and DME vaporizes one after another from the fuel injection port. As a result, a large amount of DME fuel is released into the atmosphere. Therefore, the present invention provides a technique capable of reducing the amount of DME released into the atmosphere while preventing knocking at the time of startup in an engine.

  1st invention is the blow-by gas reduction stop control method at the time of starting in the engine provided with the blow-by gas line which attracts the blow-by gas containing the vapor | steam of DME to an air inlet, and the open line which open | releases said blow-by gas to air | atmosphere A discharge step of closing the blow-by gas line and opening the open line before starting the engine, and a reduction step of opening the blow-by gas line and closing the open line after starting the engine. The blow-by gas line and the open line are closed while the engine is stopped except for the discharge step.

  Preferably, the first invention can adopt configurations (1) and (2).

(1) The reduction process is started after a predetermined time has elapsed from the time of starting the engine.

(2) In the discharge step, the blow-by gas line is closed after the open line is opened, and in the reduction step, the open line is closed after the blow-by gas line is opened.

  In the engine, the amount of DME released into the atmosphere can be reduced while preventing knocking during startup.

It is the schematic which shows the engine containing a blow-by gas line. It is a flowchart of the blow-by gas reduction stop control at the time of starting.

  FIG. 1 is a schematic view showing an engine 1 including a blow-by gas line 5. The engine 1 is a diesel engine using DME as fuel.

  In FIG. 1, an engine 1 includes an engine body 2, an air intake port 3, an air discharge port 4, a blow-by gas line 5, an open line 6, a starter 7, a control device 10, and a first electromagnetic valve BV. -1 and a second electromagnetic valve BV-2.

  The engine body 2 includes main parts of the engine such as a piston, a cylinder, and a crankcase. A crankshaft 21, a crank angle sensor 22, and a starter starter (starter motor) 7 are provided in the engine body 2. The engine body 2 has a sealed structure except for the air intake port 3, the air exhaust port 4, and the blow-by gas line 5.

  The blow-by gas line 5 is a pipe line that connects the engine body 2 and the air suction port 3 in communication. The open line 6 is a pipe line that connects the blow-by gas line 5 and the atmosphere. The first electromagnetic valve BV-1 is provided on the blow-by gas line 5 between the connection portion between the blow-by gas line 5 and the open line 6 and the air inlet 3. The second electromagnetic valve BV-2 is provided on the open line 6.

  The control device 10 controls each part of the engine 1 as well as the starter 7, the first control valve BV-1, and the second control valve BV-2.

  FIG. 2 is a flowchart of start-up blowby gas reduction stop control. The control device 10 can execute start-up blow-by gas reduction stop control for the engine 1. Blow-by gas reduction stop control is sequence control. In the start-up blowby gas reduction stop control, processes from steps S1 to S8 described later are sequentially executed.

  While the engine 1 is stopped, the blow-by gas line 5 and the open line 6 are closed. For this reason, the blowby gas line 5 is filled with blowby gas generated in the engine body 2. At this time, the blow-by gas line 5 is sealed. For this reason, when blow-by gas filling the blow-by gas line 5 reaches vapor-liquid equilibrium, generation of blow-by gas stops.

  The engine 1 is provided with a start switch for starting the engine 1. In step S1, when detecting that the start switch has been pressed, the control device 10 starts blow-by gas reduction stop control.

  In step S2, the control device 10 opens the second electromagnetic valve BV-2. In step S3, the control device 10 closes the first electromagnetic valve BV-1.

  Steps S2 and S3 are discharge processes in which the blow-by gas line 5 is closed and the open line 6 is opened. In the release process, the blow-by gas in the blow-by gas line 5 is released into the atmosphere.

  In step S4, the control device 10 activates the starter 7. When the starter 7 is started, rotation of the crankshaft in the engine body 2 is started. As a result, the engine 1 is started. The difference between the start point of the starter 7 and the start point of the engine 1 is, for example, less than 1 second.

  In step S <b> 5, the control device 10 waits for a reduction process (steps S <b> 6 and S <b> 7), which will be described later, for a predetermined time after the engine 1 is started. In the present embodiment, the predetermined time is 15 seconds. That is, the control device 10 waits for execution of the reduction process until the rotation speed of the crankshaft reaches a predetermined rotation speed.

  In step S6, the first electromagnetic valve BV-1 is opened. In step S3, the control device 10 closes the second electromagnetic valve BV-2.

  Steps S6 and S7 are a reduction process in which the blow-by gas line 5 is opened and the open line 6 is closed. In the reduction process, blow-by gas in the blow-by gas line 5 is sucked into the air suction port 3. Inhaled blow-by gas is combusted in a cylinder in the engine body 2 together with DME fuel supplied during operation of the engine 1. That is, blow-by gas is reduced to fuel in the reduction process.

  In step S8, the control device 10 ends the blow-by gas reduction stop control at startup.

  By the blow-by gas reduction stop control at the start-up, the following actions and effects can be obtained. In the release process, the blow-by gas in the blow-by gas line 5 is released into the atmosphere. Subsequently, since the execution of the reduction process is waited until after the engine 1 is started, the blow-by gas is not reduced to fuel while the engine 1 is started. That is, even when the engine is operating, the reduction of blow-by gas is stopped at startup. For this reason, occurrence of knocking at the time of activation is prevented. Subsequently, a reduction process is executed after the engine 1 is started. For this reason, the release of blow-by gas into the atmosphere is stopped. Further, since the blow-by gas line 5 is closed while the engine is stopped, the release of the blow-by gas into the atmosphere is stopped. For this reason, compared with the case where the blow-by gas line 5 is always opened while the engine 1 is stopped, the amount of DME released into the atmosphere is reduced.

  The start-up blow-by gas reduction stop control waits for the execution of the reduction process until a predetermined time has elapsed since the start of the engine 1. That is, the blow-by gas is prevented from being sucked into the air suction port until the rotation of the engine 1 is stabilized. For this reason, the occurrence of knocking at the time of activation is reliably prevented.

  It should be noted that the time for waiting for execution of the reduction step may be set until the predetermined number of rotations of the engine 1 reaches the predetermined number of rotations instead of the predetermined time from the starting time. The control device 10 can detect that the rotation speed of the crankshaft has reached a predetermined rotation speed based on the detection value of the crank angle sensor 22.

  In particular, in the discharge process, the blow-by gas line 5 is closed after the open line 6 is opened. For this reason, the blow-by gas is surely released into the atmosphere without leaking into the air inlet 3. Further, in the reduction step, the open line 6 is closed after the blow-by gas line 5 is opened. For this reason, blow-by gas is reliably sucked into the air suction port 3 without leaking into the atmosphere.

DESCRIPTION OF SYMBOLS 1 Engine 2 Engine main body 5 Blow-by gas line 6 Open line 7 Starter 21 Crankshaft BV-1 1st solenoid valve BV-2 2nd solenoid valve

Claims (3)

A start-up blowby gas reduction stop control method in an engine comprising a blowby gas line that sucks blowby gas containing DME vapor into an air inlet, and an open line that opens the blowby gas to the atmosphere,
A discharge step of closing the blow-by gas line and opening the open line before starting the engine; and
A reduction step of opening the blow-by gas line and closing the open line after starting the engine; and
With
During the stop of the engine excluding the discharge step, the blow-by gas line and the open line are closed.
Blow-by gas reduction stop control method at startup. The reduction step is started after a certain period of time has elapsed since the start of the engine.
The start-up blowby gas reduction stop control method according to claim 1. In the discharging step, after the open line is opened, the blow-by gas line is closed,
In the reduction step, the open line is closed after the blow-by gas line is opened.
The start-up blowby gas reduction stop control method according to claim 1.

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