The present invention relates to a multipoint spark plug having a plurality of ignition gaps, and a multipoint ignition engine including the multipoint spark plug.
JP2009-041366A discloses a multipoint ignition device in which a plurality of ignition gaps are formed by a plurality of intermediate members that are held by a head gasket interposed between a cylinder head and a cylinder block of an engine.
In the multipoint ignition device disclosed in JP2009-041366A, however, the entire head gasket must be exchanged in order to exchange a spark plug, and for this purpose, the cylinder head must be removed from the cylinder block.
The present invention has been designed in consideration of the problem described above, and an object thereof is to provide a multipoint spark plug and a multipoint ignition engine with which multipoint ignition can be achieved over a wide range and the multipoint spark plug can be exchanged easily.
According to one aspect of this invention, a multipoint spark plug configured to ignite an air-fuel mixture in a combustion chamber of an engine, includes: a main body portion formed in a flattened shape, the main body portion being inserted into an insertion hole of the engine such that a tip end portion thereof opposes the combustion chamber; a pair of side electrodes provided via a gap in a lengthwise direction of the tip end portion; and at least one intermediate electrode provided in the gap between the pair of side electrodes such that a plurality of ignition gaps are formed in the lengthwise direction of the tip end portion.
A multipoint spark plug 100 according to an embodiment of the present invention and a multipoint ignition engine (referred to simply as an “engine” hereafter) 1 that includes the multipoint spark plug 100 will be described below with reference to the figures.
First, referring to
As shown in
The engine 1 includes a pair of insertion holes 5 into which the multipoint spark plug 100 is inserted. As shown in
The insertion holes 5 are through holes having a flattened, rounded-edge rectangular shape that corresponds to a main body portion 10 of the multipoint spark plug 100. In the engine 1, the insertion holes 5 are respectively formed in positions removed from the spark plug 7 on an intake valve 8 side and an exhaust valve 9 side of the combustion chamber 4 (in a lower end portion of the combustion chamber 4). Accordingly, one multipoint spark plug 100 is provided in a position removed from the spark plug 7 on the opposite side of the intake valve 8 thereto, and one multipoint spark plug 100 is provided in a position removed from the spark plug 7 on the opposite side of the exhaust valve 9 thereto. In the engine 1, ignition is performed by the multipoint spark plugs 100 in addition to the spark plug 7, and therefore a flame motion can be generated during combustion. Hence, fast combustion can be realized without providing a squish area, and as a result, cooling loss can be reduced.
It should be noted that the present invention is not limited to this configuration, and instead, the insertion holes 5 may be formed away from the spark plug 7 in locations within the combustion chamber 4 where the temperature of the air-fuel mixture is low, or in other words locations where knocking is more likely to occur. Further, the insertion hole 5 may be formed in a single location in the combustion chamber 4, or in a plurality of three or more locations. By forming the insertion holes 5 in accordance with the shape of the combustion chamber 4 in this manner, a desired number of multipoint spark plugs 100 can be provided.
Next, referring to
As shown in
The main body portion 10 has a rounded-edge rectangle-shaped cross-section corresponding to the shape of the insertion hole 5, and is formed at a length corresponding to the insertion hole 5. The main body portion 10 is formed from a metal such as aluminum. By forming the main body portion 10 in a flattened shape, a surface area of the multipoint spark plug 100 that is within the combustion chamber 4 can be reduced in comparison with a case where electrodes 17 forming the plurality of ignition gaps 14 are provided but the main body portion 10 is not formed in a flattened shape. As a result, the multipoint spark plug 100 can be disposed in the combustion chamber 4 with a greater degree of freedom.
As shown in
The tip end portion 11 is formed in an identical shape to an inner periphery of the combustion chamber 4, and forms a part of the inner periphery of the combustion chamber 4. More specifically, the tip end portion 11 is formed in a spherical surface shape that has an identical radius to the hemispherical combustion chamber 4 when the multipoint spark plug 100 is attached to the cylinder head 3 in which the hemispherical combustion chamber 4 is provided. Further, the tip end portion 11 is formed in a curved surface shape that has an identical radius to an inner periphery of the cylinder 2a when the multipoint spark plug 100 is attached to the head gasket 6.
The side electrodes 12 are held on the main body portion 10 via the insulators 15. The side electrodes 12 project further into the combustion chamber 4 from the insulators 15. The side electrodes 12 are formed so as to project from the tip end portion 11 in an L shape. One of the side electrodes 12 (a first side electrode 12) penetrates the main body portion 10 and the flange portion 20 so as to extend to an input terminal 22, to be described below. The other side electrode 12 (a second side electrode 12) penetrates the main body portion 10 and the flange portion 20 similarly so as to extend to a connection terminal 23, to be described below. The pair of side electrodes 12 are provided so that respective tip ends thereof face each other. An ignition current from an ignition coil (not shown) is input into the first side electrode 12 via the input terminal 22.
The intermediate electrodes 13 are provided in a pair and disposed between the pair of mutually opposing side electrodes 12. The intermediate electrodes 13 are held on the main body portion 10 via the insulator 15. The intermediate electrodes 13 project further into the combustion chamber 4 from the insulator 15. In contrast to the side electrodes 12, the intermediate electrodes 13 do not penetrate the main body portion 10. Instead, the intermediate electrodes 13 are held on the main body portion 10 by being inserted partially therein.
The intermediate electrodes 13 are disposed in a straight line so as to form three ignition gaps 14 at equal intervals between the pair of mutually opposing side electrodes 12. By forming the plurality of ignition gaps 14 on the tip end portion 11 of the flattened main body portion 10 so as to extend in the lengthwise direction in this manner, multipoint ignition can be implemented over a wide range of the combustion chamber 4.
The intermediate electrode 13 may be provided singly, or in a plurality of three or more. The number of intermediate electrodes 13 may be set as desired in accordance with a lengthwise direction dimension of the tip end portion 11 of the main body portion 10, a designed number of ignition gaps 14, and so on.
The intermediate electrodes 13 are formed so as to project from the tip end portion 11 in a T shape. In so doing, the ignition current input into the first side electrode 12 from the ignition coil can pass through the ignition gaps 14 in a straight line and flow into the second side electrode 12. As a result, sparks can be generated reliably in the ignition gaps 14.
The insulators 15 insulate the side electrodes 12 and the intermediate electrodes 13 from the main body portion 10. The insulators 15 that hold the side electrodes 12 project partially from the tip end portion 11, and are formed to be long enough to penetrate the main body portion 10 and the flange portion 20. The insulator 15 that holds the intermediate electrodes 13 projects partially from the tip end portion 11, and is formed at a size enabling a part thereof to be inserted into the interior of the main body portion 10.
As shown in
By forming the curved surface portions 15c in this manner, a path from the side electrodes 12 and intermediate electrodes 13 to the outer periphery of the main body portion 10 is longer than in a case where the bottom surface 15b is not formed so as to be recessed from the tip end portion 15a. As a result, a situation in which the side electrodes 12 and intermediate electrodes 13 short-circuit to the cylinder head 3 via the outer periphery of the main body portion 10 can be prevented from occurring.
As shown in
The bead portion 16a projects in an annular shape from substantially the center of the metal gasket 16 toward an outer periphery thereof. By providing the bead portion 16a, the gap between the main body portion 10 and the insertion hole 5 can be sealed without being affected by errors in the inner periphery of the insertion hole 5 and the outer periphery of the main body portion 10 or the like.
The flange portion 20 is formed around the entire periphery of the main body portion 10 so as to project from the main body portion 10 toward the outer periphery thereof. The flange portion 20 is formed integrally with the main body portion 10 from a metal such as aluminum. The flange portion 20 includes a pair of fastening holes 25a. The flange portion 20 is fastened to an outer surface of the cylinder head 3 by a pair of bolts 25 inserted into the fastening holes 25a. An O-ring 21 is provided on the flange portion 20 as a second sealing material that seals a contact surface between the flange portion 20 and the cylinder head 3.
The O-ring 21 is inserted into an O-ring groove 20a formed in an annular shape in a surface of the flange portion 20 that opposes the main body portion 10. The O-ring 21 is formed from a rubber material.
The O-ring 21 is compressed between the flange portion 20 and the cylinder head 3 by a fastening force of the bolts 25. Accordingly, when the flange portion 20 is fastened to the cylinder head 3, the O-ring 21 seals the gap between the main body portion 10 and the insertion hole 5.
In the engine 1, the gap between the main body portion 10 of the multipoint plug 100 and the insertion hole 5 of the engine 1 is sealed doubly by the metal gasket 16 and the O-ring 21, but the gap may be sealed by only one of the metal gasket 16 and the O-ring 21.
The flange portion 20 includes the input terminal 22, which is connected to the first side electrode 12 and receives the ignition current from the ignition coil, and the connection terminal 23, which is connected to the second side electrode 12 and to the input terminal 22 of the other multipoint spark plug 100.
As a result, the pair of the multipoint spark plugs 100 provided in the single combustion chamber 4 can be connected in series via a plug cord (not shown) so as to perform ignition simultaneously. Further, the spark plug 7 can be connected in series to the ends of the pair of multipoint spark plugs 100 via a plug cord (not shown) so as to perform ignition simultaneously therewith. At this time, an earth electrode 7a (see
Next, an operation for exchanging the multipoint spark plug 100 will be described.
To exchange the multipoint spark plug 100, first, the pair of bolts 25 are removed and the main body portion 10 is withdrawn from the insertion hole 5 in the engine 1. Next, the metal gasket 16 is wound around the main body portion 10 of the new multipoint spark plug 100, and the O-ring 21 is inserted into the O-ring groove 20a. The new multipoint spark plug 100 is then inserted into the insertion hole 5 in the engine 1. Next, the pair of bolts 25 are inserted into the fastening holes 25a and fastened, whereby exchange of the multipoint spark plug 100 is complete.
Hence, the multipoint spark plug 100 can be exchanged simply by withdrawing the multipoint spark plug 100 from the insertion hole 5 in the engine 1 and inserting the new multipoint spark plug 100, and as a result, the multipoint spark plug 100 can be exchanged easily.
Moreover, at this time, the multipoint spark plug 100, in contrast to the spark plug 7, does not have to be rotated so as to be screwed to a female screw formed in the cylinder head 3, and therefore the side electrodes 12 and intermediate electrodes 13 can be disposed reliably in prescribed positions within the combustion chamber 4. Hence, the positions of the ignition gaps 14 do not change even when the multipoint spark plug 100 is exchanged, and as a result, the air-fuel mixture can be burned as designed.
According to the embodiment described above, following effects are obtained.
In the multipoint spark plug 100, the plurality of ignition gaps 14 are formed to extend in the lengthwise direction along the tip end portion 11 of the flattened main body portion 10, and therefore multipoint ignition can be achieved over a wide range. Further, the flattened main body portion 10 is inserted into the insertion hole 5 in the engine 1 so that the tip end portion 11 thereof opposes the combustion chamber 4. Therefore, the multipoint spark plug 100 can be exchanged simply by withdrawing the multipoint spark plug 100 from the insertion hole 5 in the engine 1 and inserting the new multipoint spark plug 100. Hence, with the multipoint spark plug 100 and the engine 1, multipoint ignition can be achieved over a wide range, and the multipoint spark plug 100 can be exchanged easily.
Embodiments of this invention were described above, but the above embodiments are merely examples of applications of this invention, and the technical scope of this invention is not limited to the specific constitutions of the above embodiments.
For example, as shown in
Further, in the above embodiment, the air-fuel mixture in the combustion chamber 4 is ignited by both spark plug 7 and the multipoint spark plugs 100, but the spark plug 7 may be omitted so that the multipoint spark plugs 100 are provided alone. In a case where an inner diameter (a bore diameter) of the combustion chamber 4 is comparatively small, for example, fast combustion can be realized in a similar manner to the above embodiment even when ignition is performed by the multipoint spark plugs 100 alone.
Furthermore, in the above embodiment, the main body portion 10 and the flange portion 20 are formed integrally from a metal such as aluminum, and the insulators 15, which are formed from an insulating material such as a ceramic, are inserted therein. Instead, however, the main body portion 10 and the insulators 15 may be formed integrally from an insulating material such as a ceramic, and the flange portion 20 may be formed from a metal such as aluminum and attached thereto.
This application claims priority based on Japanese Patent Application No. 2016-022982 filed with the Japan Patent Office on Feb. 9, 2016, Japanese Patent Application No. 2016-022983 filed with the Japan Patent Office on Feb. 9, 2016, and Japanese Patent Application No. 2016-128127 filed with the Japan Patent Office on Jun. 13, 2016, the entire contents of which are incorporated into this specification.
The embodiments of this invention in which an exclusive property or privilege is claimed are defined as follows:
Number | Date | Country | Kind |
---|---|---|---|
2016-022982 | Feb 2016 | JP | national |
2016-022983 | Feb 2016 | JP | national |
2016-128127 | Jun 2016 | JP | national |