JP2015055184A - Gas engine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gas engine which burns a lean mixture in an ignition chamber thereby improving the durability.SOLUTION: A gas engine 1 includes: a combustion chamber 2 into which an air fuel mixture M, in which a fuel gas and air are mixed, is suctioned; a plug cover 30 which forms an ignition chamber 3 in the combustion chamber 2 and has multiple communication ports 321 that allow the ignition chamber 3 to communicate with the combustion chamber 2; and an ignition plug 4 which is attached to a cylinder head 5 so that an electrode part 41 is exposed in the ignition chamber 3. An introduction port 51 for supplying a lean mixture G having an air ratio larger than that of the air fuel mixture M opens in the ignition chamber 3.

Description

  The present invention relates to a gas engine.

  In a gas engine that operates using a gaseous fuel such as natural gas, a lean air-fuel mixture containing a relatively high proportion of air is used compared to a case where a fuel such as gasoline is used. As a result, misfires and fuel consumption are often reduced. In order to effectively ignite the lean air-fuel mixture, an ignition chamber is provided in the combustion chamber by covering the electrode portion of the spark plug with a plug cover having a plurality of communication ports. Then, the flame generated by the combustion of the air-fuel mixture in the ignition chamber is ejected to the combustion chamber, and the air-fuel mixture in the combustion chamber is combusted.

  For example, in the engine of Patent Document 1 and the pre-chamber plug attached thereto, an engine in which a plug cover that forms an ignition chamber is provided on a plug body is disclosed. The plug body is attached to the cylinder head, and the plug cover is formed with a communication port for communicating the ignition chamber and the combustion chamber. Then, the air-fuel mixture flowing from the combustion chamber into the ignition chamber through the communication port is burned, and a flame caused by combustion is ejected from the ignition chamber to the combustion chamber through the communication port.

JP 2011-99403 A

However, the gas engine disclosed in Patent Document 1 has the following problems.
In the gas engine of Patent Document 1, exhaust gas generated when an air-fuel mixture is burned is discharged from an exhaust port opened in the combustion chamber in an exhaust process. At this time, in the ignition chamber formed inside the plug cover, the exhaust gas hardly flows and the exhaust gas tends to stay in the ignition chamber. Since the exhaust gas is hot, if the exhaust gas stays, the ignition chamber and the plug cover become hot, and the durability of the spark plug and the plug cover decreases.

  The present invention has been made in view of such a background, and an object of the present invention is to provide a gas engine that can suppress the temperature rise of the spark plug and the plug cover and improve the durability thereof.

One aspect of the present invention is a combustion chamber in which an air-fuel mixture in which fuel gas and air are mixed is sucked,
A plug cover that forms an ignition chamber in the combustion chamber and has a plurality of communication ports that communicate the ignition chamber and the combustion chamber;
An ignition plug mounted on the cylinder head so that the electrode portion is exposed in the ignition chamber,
In the gas engine, the ignition chamber has an opening for introducing a lean air-fuel mixture having an air ratio larger than that of the air-fuel mixture.

In another aspect of the present invention, a combustion chamber in which an air-fuel mixture in which fuel gas and air are mixed is sucked,
A plug cover that forms an ignition chamber in the combustion chamber and has a plurality of communication ports that communicate the ignition chamber and the combustion chamber;
An ignition plug mounted on the cylinder head so that the electrode portion is exposed in the ignition chamber,
An introduction port for introducing air is opened in the ignition chamber,
The ignition chamber is configured to produce a lean air-fuel mixture by mixing the air-fuel mixture flowing from the combustion chamber and the air introduced from the introduction port.

  The gas engine has the introduction port in the ignition chamber, and introduces the lean air-fuel mixture or air into the ignition chamber from the introduction port, so that the air ratio is higher than that in the combustion chamber. A large air-fuel mixture can be supplied into the ignition chamber. Since the combustion temperature of the air-fuel mixture decreases as the air ratio increases, the combustion temperature in the ignition chamber can be lowered. Therefore, the temperature rise around the spark plug and the plug cover can be effectively suppressed.

  Further, by introducing the lean air-fuel mixture or air into the ignition chamber from the introduction port, the exhaust gas in the ignition chamber can be discharged to the combustion chamber and discharged from the combustion chamber to the exhaust port. As a result, the high-temperature exhaust gas staying in the ignition chamber can be effectively discharged. Therefore, the temperature rise around the spark plug and the plug cover can be further suppressed.

  As described above, according to the gas engine, it is possible to suppress the temperature rise of the spark plug and the plug cover and improve the durability thereof.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an explanatory diagram showing a gas engine in an intake process in Embodiment 1. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an explanatory view showing a gas engine in a combustion process in Embodiment 1. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an explanatory view showing a gas engine in an exhaust process in Embodiment 1.

  In the gas engine, it is preferable that a check valve for preventing a backflow from the ignition chamber is disposed at the introduction port. In this case, the backflow of the exhaust gas and the air-fuel mixture from the ignition chamber side into the introduction port can be prevented.

Example 1
Examples of the gas engine will be described with reference to FIGS.
As shown in FIG. 1, the gas engine 1 shown in this example includes a combustion chamber 2 into which an air-fuel mixture M obtained by mixing fuel gas and air is sucked, an ignition chamber 3 in the combustion chamber 2, and an ignition chamber. 3 and a plug cover 30 having a plurality of communication ports 321 communicating with the combustion chamber 2, and a spark plug 4 mounted on the cylinder head 5 so that the electrode portion 41 is exposed in the ignition chamber 3. .
In the ignition chamber 3, an introduction port 51 for supplying a lean mixture G having an air ratio larger than that of the mixture M is opened.

This will be described in more detail below.
As shown in FIGS. 1 to 3, the gas engine 1 is operated by burning an air-fuel mixture M of fuel gas such as natural gas and air. The gas engine 1 includes a cylinder head 5 and a cylinder block 6 that form a combustion chamber 2.

The cylinder head 5 is provided with an intake port 52 for sucking the air-fuel mixture M into the combustion chamber 2 and an exhaust port 53 for exhausting the exhaust gas E after combustion from the combustion chamber 2. The intake port 52 is provided with an intake valve 521 that can be opened and closed, and the exhaust port 53 is provided with an exhaust valve 531 that can be opened and closed.
The cylinder 61 is configured by arranging a piston 611 that can reciprocate in a hole 612 formed in the cylinder block 6.

  As shown in FIGS. 1 to 3, the plug cover 30 has a cylindrical portion 31 attached to the cylinder head 5 and a hemispherical tip portion 32 formed continuously from the cylindrical portion 31. The plurality of communication ports 321 are provided at the hemispherical tip portion 32. The hemispherical tip 32 projects into the combustion chamber 2 so as to cover the electrode part 41 of the spark plug 4. The plug cover 30 is provided so as to face the center position of the cylinder 61.

The communication ports 321 can be provided at 3 to 6 locations in the plug cover 30. The communication port 321 is provided so as to be inclined so that the flame formed in the ignition chamber 3 is ejected as uniformly as possible to each part in the combustion chamber 2.
The spark plug 4 is attached to the cylinder head 5 in a state where an electrode portion 41 constituted by the center electrode 411 and the ground electrode 412 is directed to the combustion chamber 2 side so as to be exposed in the ignition chamber 3.

  As shown in FIGS. 1 to 3, an introduction port 51 for supplying a lean air-fuel mixture G having an air ratio larger than that of the air-fuel mixture M is opened in the ignition chamber 3. The introduction port 51 is open to a portion inside the cylindrical portion 31 in the cylinder head 5 and is configured to be able to supply a lean air-fuel mixture G having an air ratio larger than the air-fuel mixture M into the ignition chamber 3. Further, a check valve 511 for preventing a back flow from the ignition chamber 3 is disposed at the introduction port 51. In this example, the check valve 511 is pushed by the flow of the lean air-fuel mixture G in the intake process of the gas engine 1 to open the introduction port 51. In the compression, combustion, and exhaust processes of the gas engine 1, the check valve 511 is introduced. Is configured to close.

In the gas engine 1 of this example, combustion is performed as follows.
As shown in FIG. 1, in the intake process, the piston 611 moves to the bottom dead center, the intake valve 521 opens, the air-fuel mixture M is taken into the combustion chamber 2 from the intake port 52, and from the introduction port 51. A lean air-fuel mixture G is supplied into the ignition chamber 3. At this time, the exhaust gas E staying in the ignition chamber 3 is discharged into the combustion chamber 2 through the communication port 321 by the lean air-fuel mixture G supplied from the introduction port 51.

Next, in the compression process, the piston 611 moves to the top dead center, the combustion chamber 2 is reduced, and the air-fuel mixture M and the lean air-fuel mixture G are compressed. Next, in the combustion process, the lean air-fuel mixture G in the ignition chamber 3 is ignited by the spark generated at the electrode portion 41 of the spark plug 4.
At this time, as shown in FIG. 2, a flame formed in the ignition chamber 3 is ejected into the combustion chamber 2 from the plurality of communication ports 321, and the air-fuel mixture M in the combustion chamber 2 is combusted by this flame. Then, the combustion gas expands and the piston 611 moves to the bottom dead center.

  Next, as shown in FIG. 3, in the exhaust process, the piston 611 moves to the top dead center due to inertia, and the exhaust valve 531 opens to exhaust the exhaust gas E in the combustion chamber 2 from the exhaust port 53. At this time, the exhaust gas E in the ignition chamber 3 flows into the combustion chamber 2 through the plurality of communication ports 321 and is then exhausted from the exhaust port 53.

Next, the function and effect of this example will be described.
The gas engine 1 has an introduction port 51 in the ignition chamber 3, and the lean air-fuel mixture G can be introduced into the ignition chamber 3 from the introduction port 51. Since the combustion temperature of the air-fuel mixture decreases as the air ratio increases, the combustion temperature in the ignition chamber 3 can be lowered by introducing the lean air-fuel mixture G into the ignition chamber 3. Therefore, the temperature rise of the plug cover 30 can be effectively suppressed.

  Further, by introducing the lean air-fuel mixture G into the ignition chamber 3 from the introduction port 51, the exhaust gas E in the ignition chamber 3 can be discharged to the combustion chamber 2 and discharged from the combustion chamber 2 to the exhaust port 53. . Thereby, the high-temperature exhaust gas E staying in the ignition chamber 3 can be effectively discharged. Therefore, the temperature rise around the spark plug 4 and the plug cover 30 can be further suppressed.

The introduction of the lean air-fuel mixture G from the inlet 51 to the ignition chamber 3 can be started in the exhaust process. In this case, the exhaust gas E in the ignition chamber 3 can be discharged to the combustion chamber 2 more effectively.
Further, the amount of lean mixture G introduced from the inlet 51 into the ignition chamber 3 is preferably sufficient to discharge the exhaust gas E in the ignition chamber 3. For example, the exhaust gas E in the ignition chamber 3 can be reliably discharged by introducing a lean air-fuel mixture G that is larger than the volume of the space formed in the ignition chamber 3.

  As described above, according to the gas engine 1 of this example, the temperature rise of the spark plug 4 and the plug cover 30 can be suppressed, and the durability thereof can be improved.

(Example 2)
This example shows an example in which the configuration of the gas engine 1 in the first embodiment is partially changed.
The gas engine 1 shown in this example is configured to supply air A from the inlet 51 into the ignition chamber 3. In the ignition chamber 3, the air-fuel mixture M flowing from the combustion chamber 2 and the air A introduced from the introduction port 51 are mixed to create a lean air-fuel mixture M.

  In the intake process of the gas engine 1 of this example, the piston 611 moves to the bottom dead center, the intake valve 521 is opened, the air-fuel mixture M is taken into the combustion chamber 2 from the intake port 52, and ignition is performed from the introduction port 51. Air A is supplied into the chamber 3. At this time, the exhaust gas E staying in the ignition chamber 3 is discharged into the combustion chamber 2 through the communication port 321 by the air A supplied from the introduction port 51. In addition, the air-fuel mixture M flows from the combustion chamber 2 to the ignition chamber 3 through the plurality of communication ports 321. As a result, the air A and the air-fuel mixture M are mixed in the ignition chamber 3, and an air-fuel mixture having a larger air ratio than the air-fuel mixture M is created in the ignition chamber 3.

The introduction of the air A from the introduction port 51 to the ignition chamber 3 can be started in the exhaust process. In this case, the exhaust gas E in the ignition chamber 3 can be discharged to the combustion chamber 2 more effectively.
When air A is introduced from the inlet 51 into the ignition chamber 3 in the exhaust process, the amount of air A introduced from the inlet 51 into the ignition chamber 3 is such that the exhaust gas E in the ignition chamber 3 is discharged. It is preferable that the amount is sufficient. For example, the exhaust gas E in the ignition chamber 3 can be reliably discharged by introducing the air A that is larger than the volume of the space formed in the ignition chamber 3.
Other configurations are the same as those of the first embodiment.
Also in this example, it is possible to obtain the same effect as that of the first embodiment.

  In the first embodiment and the second embodiment, the supply amounts of the lean air-fuel mixture G and air A to the ignition chamber 3 can be set as appropriate.

DESCRIPTION OF SYMBOLS 1 Gas engine 2 Combustion chamber 3 Ignition chamber 30 Plug cover 321 Communication port 4 Spark plug 41 Electrode part 5 Cylinder head 51 Inlet 511 Check valve

Claims (3)

A combustion chamber into which a mixture of fuel gas and air is taken in, and
A plug cover that forms an ignition chamber in the combustion chamber and has a plurality of communication ports that communicate the ignition chamber and the combustion chamber;
An ignition plug mounted on the cylinder head so that the electrode portion is exposed in the ignition chamber,
A gas engine characterized in that an introduction port for introducing a lean air-fuel mixture having an air ratio larger than that of the air-fuel mixture is opened in the ignition chamber. A combustion chamber into which a mixture of fuel gas and air is taken in, and
A plug cover that forms an ignition chamber in the combustion chamber and has a plurality of communication ports that communicate the ignition chamber and the combustion chamber;
An ignition plug mounted on the cylinder head so that the electrode portion is exposed in the ignition chamber,
An introduction port for introducing air is opened in the ignition chamber,
The gas engine according to claim 1, wherein the ignition chamber is configured to produce a lean air-fuel mixture by mixing the air-fuel mixture flowing from the combustion chamber and the air introduced from the inlet.   The gas engine according to claim 1 or 2, wherein a check valve for preventing a backflow from the ignition chamber is arranged at the introduction port.

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