This application is based on and claims the benefit of priority from earlier Japanese Patent Application No. 2012-159586 filed Jul. 18, 2012, the description of which is incorporated herein by reference.
1. Technical Field
The present invention relates to a spark plug used for an internal combustion engine of a vehicle or the like.
2. Related Art
Conventionally, a spark plug is known as an ignition means for igniting air fuel mixture introduced into a combustion chamber of the internal combustion engine of a vehicle. For example, such a spark plug has a center electrode and an earth electrode with a spark discharge gap being interposed therebetween.
The lifetime of the spark plug depends on the increase of required voltage due to the extension of the spark discharge gap. That is, repeated spark discharge wears the center electrode and the earth electrode, thereby gradually extending the spark discharge gap therebetween. Accordingly, the required voltage increases which is required as voltage applied between the center electrode and the earth electrode for generating spark discharge. Then, the required voltage exceeds a predetermined value within a range in which some phenomena are not seen such as a decrease in dielectric resistance on a surface of insulator caused by, for example, smoldering. Hence, the spark plug reaches the lifetime thereof.
To solve this problem, various measures are considered for extending the lifetime of the spark plug by devising the structures of the center electrode and the earth electrode forming the spark discharge gap.
For example, JP-A-2007-250257 discloses a spark plug in which a plurality of earth electrodes are opposed to the center electrode to increase an opposing area (discharge area) between the earth electrodes and the center electrode, thereby restraining the extension of the spark discharge gap.
However, according to the measure for the spark plug disclosed in JP-A-2007-250257, in which the number of the earth electrodes opposed to the center electrode is increased, and the opposing area between the center electrode and the earth electrodes are increased, it may be difficult to easily increase the opposing area due to, for example, a constraint of the size of the center electrode or a housing holding the center electrode. Hence, measures are desired which can increase the opposing area between the center electrode and the earth electrodes by a simple structure without being influenced by the constraint of the size or the like.
An embodiment provides a spark plug for an internal combustion engine which can increase an opposing area between a center electrode and an earth electrode by a simple structure, thereby extending lifetime of the spark plug.
As an aspect of the embodiment, a spark plug for an internal combustion engine is provided. The spark plug includes: a tubular housing; a tubular insulator which is held inside the housing; a center electrode which is held inside the insulator so that an end portion thereof projects; and an earth electrode which has an opposing portion opposed to the end portion of the center electrode, a spark discharge gap being formed between the opposing portion and the end portion. The end portion is provided with an end projecting portion projecting toward the opposing portion. The opposing portion is provided with an opposing projecting portion which projects toward the end portion and is opposed to the end projecting portion. The end projecting portion and the opposing projecting portion are provided with non-projection direction opposing surfaces which are parallel to each other and are opposed to each other with a minimum distance being interposed therebetween and in a direction other than a projection direction thereof. When defining an opposing area of a portion which includes the non-projection direction opposing surfaces and where the end projecting portion and the opposing projecting portion are opposed to each other with the minimum distance being interposed therebetween, as a first opposing area, and defining an opposing area obtained when a plane of the end projecting portion and a plane of the opposing projecting portion, which are orthogonal to the projection direction, are opposed to each other in the projection direction, as a second opposing area, the first opposing area is larger than the second opposing area.
In the accompanying drawings:
With reference to the accompanying drawings, hereinafter are described embodiments of a spark plug for an internal combustion engine of the present invention.
As shown in
The end portion 41 of the center electrode 4 is provided with an end projecting portion 42 projecting toward the opposing portion 51 of the earth electrode 5. The opposing portion 51 of the earth electrode 5 is provided with an opposing projecting portion 52 which projects toward the end portion 41 of the center electrode 4 and is opposed to the end projecting portion 42 of the end portion 41.
As shown in
When defining an opposing area of a portion which includes the non-projection direction opposing surfaces 492, 592 and where the end projecting portion 42 and the opposing projecting portion 52 are opposed to each other with the minimum distance D being interposed therebetween, as A (first opposing area), and defining an opposing area obtained when a plane 490 of the end projecting portion 42 and a plane 590 of the opposing projecting portion 52 (see
The details are described below.
As shown
In addition, the tubular insulator 3 is inserted and held inside the housing 2. The center electrode 4 is held inside the insulator 3. The center electrode 4 is held in a state where the end portion 41 thereof projects toward the end side with respect to the insulator 3. In addition, the end portion 41 of the center electrode 4 is provided with the end projecting portion 42 which projects toward the opposing portion 51 of the earth electrode 5 described later.
In addition, the earth electrode 5 is joined to an end surface 201 of the housing 2. The earth electrode 5 extends from the end surface 201 and along the center electrode 4, and is bent to the inside, thereby forming the opposing portion 51 which is opposed to the end portion 41 of the center electrode 4. The opposing portion 51 of the earth electrode 5 is provided with an opposing projecting portion 52 which projects toward the end portion 41 of the center electrode 4 and is opposed to the end projecting portion 42 of the end portion 41.
In addition, the spark discharge gap G is provided between the end projecting portion 42 of the center electrode 4 and the opposing projecting portion 52 of the earth electrode 5. That is, by providing a predetermined distance between the end projecting portion 42 and the opposing projecting portion 52, the spark discharge gap G is provided.
In addition, the end projecting portion 42 and the opposing projecting portion 52 are formed of noble metal chips such as iridium alloy and are formed into substantially cylindrical shapes having the same diameter. The outside diameters of the end projecting portion 42 and the opposing projecting portion 52 can be set within a range of 2 to 5 mm.
As shown in
In addition, the projection portion 43 is formed in the radial direction so as to connect between circumference surfaces 422 of the end projecting portion 42 of the center electrode 4. The cross section of the projection portion 43 orthogonal to the radial direction has a rectangular shape. The projection portion 43 is provided with corner portions 44 formed with an end surface 431 and side surfaces 432. The width of the convex projection portion 43 can be set, for example, within a range of 0.8 to 1 mm, where the outer diameters of the end projecting portion 42 and the opposing projecting portion 52 are 2.4 mm.
Meanwhile, the opposing projecting portion 52 of the earth electrode 5 is provided with a concave portion 53 which has a concave groove shape recessed from a reference surface 520 of the opposing projecting portion 52 to the end side. Note that the reference surface 520 is a plane orthogonal to the projection direction X and parallel to the reference surface 420 of the end projecting portion 42 of the center electrode 4.
In addition, the concave portion 53 is formed in the radial direction so as to connect between circumference surfaces 522 of the opposing projecting portion 52 of the earth electrode 5. In the concave portion 53, part of the projection portion 43 of the end projecting portion 42 of the center electrode 4 is disposed. The shape of the concave portion 53 corresponds to the shape (rectangular shape) of the convex projection portion 43.
As shown in
In addition, the opposing surface 49 of the end projecting portion 42 of the center electrode 4 and the opposing surface 59 of the opposing projecting portion 52 of the earth electrode 5 have projection direction opposing surfaces 491, 591 and the non-projection direction opposing surfaces 492, 592. The projection direction opposing surfaces 491, 591 are parallel to each other and are opposed to each other with the minimum distance D being interposed therebetween in the projection direction X thereof. The non-projection direction opposing surfaces 492, 592 are parallel to each other and are opposed to each other with the minimum distance D being interposed therebetween in the direction other than the projection direction X thereof.
In addition, the corner portions 44 of the convex projection portion 43 of the end projecting portion 42 of the center electrode 4 are opposed to the inner wall surface 531 of the concave portion 53 of the opposing projecting portion 52 of the earth electrode 5 with the minimum distance D being interposed therebetween.
In addition, the opposing area A between the end projecting portion 42 of the center electrode 4 and the opposing projecting portion 52 of the earth electrode 5 is larger than the opposing area B. The opposing area A is 1.25 times or more larger than the opposing area B and 1.75 times or less larger than the opposing area B. In the present embodiment, the opposing area A is 1.5 times larger than the opposing area B.
The opposing area A is a portion which includes the non-projection direction opposing surfaces 492, 592 and where the end projecting portion 42 and the opposing projecting portion 52 are opposed to each other with the minimum distance D being interposed therebetween, that is, an opposing area of the projection direction opposing surfaces 491, 591 and the non-projection direction opposing surfaces 492, 592.
As shown in
Next, a manufacturing method for the end projecting portion 42 of the center electrode 4 and the opposing projecting portion 52 of the earth electrode 5 is described with reference to
As one example, a noble metal member having a substantially cylindrical shape and formed of, for example, iridium alloy is disposed between the end portion 41 of the center electrode 4 and the opposing portion 51 of the earth electrode 5. One end of the noble metal member is welded to the end portion 41 of the center electrode 4. The other end of the noble metal member is welded to the opposing portion 51 of the earth electrode 5. Next, the noble metal member is cut by a cutting process such as a wire cut process. In this process, a portion corresponding to the spark discharge gap G is cut off.
Accordingly, as shown in
In addition, as an another example, two noble metal members having substantially cylindrical shapes and formed of, for example, iridium alloy are individually welded to the end portion 41 of the center electrode 4 and the opposing portion 51 of the earth electrode 5. The noble metal members individually serve as the end projecting portion 42 of the center electrode 4 and the opposing projecting portion 52 of the earth electrode 5. At this time, a predetermined clearance is provided between the end projecting portion 42 and the opposing projecting portion 52.
Accordingly, as shown in
Note that the end projecting portion 42 of the center electrode 4 and the opposing projecting portion 52 of the earth electrode 5 can be manufactured by using another method.
Next, advantages of the spark plug 1 of the present embodiment are described.
In the spark plug 1, the end projecting portion 42 of the center electrode 4 and the opposing projecting portion 52 of the earth electrode 5 are provided with the non-projection direction opposing surfaces 492, 592 which are parallel to each other and are opposed to each other with the minimum distance D being interposed therebetween in the direction other than the projection direction X.
In addition, the opposing area A of a portion which includes the non-projection direction opposing surfaces 492, 592 and where the end projecting portion 42 and the opposing projecting portion 52 are opposed to each other with the minimum distance D being interposed therebetween is larger than the opposing area B obtained when the plane 490 and the plane 590, which are orthogonal to the projection direction X, are opposed to each other in the projection direction X.
Hence, by a simple structure, in which the non-projection direction opposing surfaces 492, 592 are provided on the end projecting portion 42 and the opposing projecting portion 52, an opposing area (discharge area) between the center electrode 4 and the earth electrode 5 can be easily increased. As a result, the extension of the spark discharge gap G due to wear of the end projecting portion 42 and the opposing projecting portion 52 caused by the spark discharge can be restricted, which can extend the lifetime of the spark plug 1.
In addition, an opposing area between the center electrode and the earth electrodes can be increased by a simple structure. Hence, shapes of the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode can be prevented from being complicated. In addition, the size (outside diameter or the like) of the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode can be prevented from increasing.
In addition, in the present embodiment, one (end projecting portion 42) of the end projecting portion 42 and the opposing projecting portion 52 is provided with the projection portion 43 projecting toward the other (opposing projecting portion 52) of the end projecting portion 42 and the opposing projecting portion 52. The projection portion 43 is provided with the corner portions 44 opposed to the other (opposing projecting portion 52) with the minimum distance D being interposed therebetween. Hence, spark discharge easily occur from the corner portions 44 of the projection portion 43 provided on the end projecting portion 42 of the center electrode 4 toward the opposing projecting portion 52 of the earth electrode 5, which can decrease the required voltage which is required for the spark discharge. Hence, wear of the electrode due to the spark discharge can be restrained, which can further extend the lifetime of the spark plug.
In addition, the opposing area A is 1.25 times or more larger than the opposing area B. Hence, the above advantage to extend the lifetime of the spark plug can be effectively utilized by increasing the opposing area between the center electrode 4 and the earth electrode 5 with a simple structure.
In addition, the opposing area A is 1.75 times or less larger than the opposing area B. Hence, shapes of the end projecting portion 42 of the center electrode 4 and the opposing projecting portion 52 of the earth electrode 5 can be prevented from being complicated. In addition, the size (outside diameter or the like) of the end projecting portion 42 and the opposing projecting portion 52 can be prevented from increasing.
As described above, according to the present embodiment, the spark plug 1 used for an internal combustion engine is provided which can extend the lifetime thereof by increasing the opposing area between the center electrode 4 and the earth electrode 5 with a simple structure.
In the present embodiment, as shown in
In the example shown in
In the example shown in
In the example shown in
Note that, in the example shown in
In the example shown in
In the example shown in
In the example shown in
Note that, in the examples shown in
Other basic configurations and advantages of the examples described above are the same as those of the first embodiment.
In the present embodiment, as shown in
In the example shown in
As shown in
As shown in
In addition, the opposing portions 51 of the earth electrodes 5a, 5b are provided with two opposing projecting portions 52 which project toward the end portion 41 of the center electrode 4 and are opposed to the end projecting portions 42 of the end portion 41.
In the example shown in
As shown in
As shown in
In addition, the opposing portions 51 of the earth electrodes 5a to 5c are provided with three opposing projecting portions 52 which project toward the end portion 41 of the center electrode 4 and are opposed to the end projecting portions 42 of the end portion 41.
In the example shown in
As shown in
As shown in
In addition, the opposing portions 51 of the earth electrodes 5a to 5c are provided with four opposing projecting portions 52 which project toward the end portion 41 of the center electrode 4 and are opposed to the end projecting portions 42 of the end portion 41.
Other basic configurations and advantages of the examples described above are the same as those of the first embodiment.
In the present embodiment, as shown in
As shown in
In addition, the opposing projecting portion 52 of the earth electrode 5 is provided with the concave portion 53 which has a substantially cylindrical shape recessed from a reference surface 520 of the opposing projecting portion 52 toward the end side.
In addition, the whole outer periphery of at least part of the projection portion 43 of the end projecting portion 42 of the center electrode 4, which includes the corner portions 44, is covered with the opposing projecting portion 52 of the earth electrode 5.
Other basic configurations are the same as those of the first embodiment.
In this case, the whole outer periphery of at least part of the projection portion 43 of one (end projecting portion 42) of the end projecting portion 42 and the opposing projecting portion 52, which includes the corner portions 44, is covered with the other (opposing projecting portion 52) of the end projecting portion 42 and the opposing projecting portion 52. Hence, a spark discharge is generated more easily from the corner portions 44 of the convex projection portion 43 of the end projecting portion 42 toward the opposing projecting portion 52, which can further decrease the required voltage which is required for the spark discharge. Hence, wear of the electrode due to the spark discharge can be further restrained, which can further extend the lifetime of the spark plug.
Other basic advantages are the same as those of the first embodiment.
In the present embodiment, lifetime of the spark plug (plug lifetime) is evaluated.
In the present embodiment, as shown in a table 1, spark plugs (specimens S11 to S14) are prepared in which the opposing area A is 1.25 times larger than the opposing area B (A/B=1.25). In addition, for comparison purposes, spark plugs (specimens S21 to S24) are prepared in which the opposing area A is the same as the opposing area B (A/B=1). The opposing areas A, B, and the opposing area ratio of A to B are shown in the table 1.
Then, regarding the spark plug, the change of the plug lifetime is examined while changing the opposing area A and the opposing area B.
Next, with reference to the table 1, structures of the prepared spark plugs (specimens S11 to S14, S21 to S24) are explained.
The specimens S11 to S14 are spark plugs, in which one earth electrode is provided with respect to one center electrode, and the shapes of the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode are the same as the example shown in
The specimens S21 to S24 are spark plugs, in which one earth electrode is provided with respect to one center electrode, and the shapes and structures of the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode are the same as the example shown in
Next, a method for evaluating the plug lifetime is described.
First, a spark plug is attached to an engine bench (engine test bed). Next, a voltage is applied between the center electrode and the earth electrode of the spark plug to repeatedly generate a spark discharge within the spark discharge gap. Conditions for spark discharge are set as follows: pressure is 0.6 MPa, discharge cycle is 60 Hz, and ignition energy is 110 mJ. Then, elapsed time is measured until the time when a spark discharge is started in a portion other than the spark discharge gap, or the time when discharge voltage exceeds a constant value, the times being assumed as the plug lifetime.
According to
As a result, it is confirmed that, since the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode are provided with non-projection direction opposing surfaces, and the opposing area A is larger than the opposing area B, the opposing area between the center electrode and the earth electrode can be increased with a simple structure, which can extend the lifetime of the spark plug. In addition, it is confirmed that as the opposing area A becomes larger, the plug lifetime becomes longer.
In the present embodiment, the lifetime of the spark plug (plug lifetime) is evaluated.
In the present embodiment, as shown in a table 2, spark plugs (specimens S31 to S34) whose opposing area B is 6.6 mm2 and spark plugs (specimens S41 to S44) whose opposing area B is 27 mm2 are prepared. The opposing areas A, B and the opposing area ratio A/B of the specimens are shown in the table 2.
Then, regarding each of the spark plugs, change of the plug lifetime is examined while changing the opposing area ratio A/B by controlling the opposing area A.
Note that the method for evaluating the plug lifetime is the same as that of the fifth embodiment.
Next, with reference to the table 2, structures of the prepared spark plugs (specimens S31 to S34, S41 to S44) are explained.
The specimens S31 to S34 are spark plugs, in which one earth electrode is provided with respect to one center electrode, and the shapes and structures of the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode are the same as the example shown in
The specimens S41 to S44 are spark plugs, in which three earth electrodes are provided with respect to one center electrode, and the shapes and structures of the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode are the same as the example shown in
According to
In addition, when comparing
That is, according to
As a result, it can be understood that, by making the opposing area ratio A/B of the spark plug higher, the advantage to extend the lifetime of the spark plug can be effectively utilized by increasing the opposing area of the center electrode and the earth electrode with a simple structure.
In addition, it can be understood that, by providing the projection portion to the end projecting portion of the center electrode, and providing the corner portions to the projection portion, the lifetime of the spark plug can be further extended.
It will be appreciated that the present invention is not limited to the configurations described above, but any and all modifications, variations or equivalents, which may occur to those who are skilled in the art, should be considered to fall within the scope of the present invention.
Hereinafter, aspects of the above-described embodiments will be summarized.
As an aspect of the embodiment, a spark plug (1) for an internal combustion engine is provided. The spark plug (1) includes: a tubular housing (2); a tubular insulator (3) which is held inside the housing (2); a center electrode (4) which is held inside the insulator (3) so that an end portion (41) thereof projects; and an earth electrode (5) which has an opposing portion (51) opposed to the end portion (41) of the center electrode (4), a spark discharge gap (G) being formed between the opposing portion (51) and the end portion (41). The end portion (41) is provided with an end projecting portion (42) projecting toward the opposing portion (51). The opposing portion (51) is provided with an opposing projecting portion (52) which projects toward the end portion (41) and is opposed to the end projecting portion (42). The end projecting portion (42) and the opposing projecting portion (52) are provided with non-projection direction opposing surfaces (492, 592) which are parallel to each other and are opposed to each other with a minimum distance (D) being interposed therebetween and in a direction other than a projection direction (X) thereof. When defining an opposing area of a portion which includes the non-projection direction opposing surfaces (492, 592) and where the end projecting portion (42) and the opposing projecting portion (52) are opposed to each other with the minimum distance (D) being interposed therebetween, as a first opposing area, and defining an opposing area obtained when a plane (490) of the end projecting portion (42) and a plane (590) of the opposing projecting portion (52), which are orthogonal to the projection direction (X), are opposed to each other in the projection direction (X), as a second opposing area, the first opposing area is larger than the second opposing area.
In the above spark plug, the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode are provided with non-projection direction opposing surfaces which are parallel to each other and are opposed to each other with the minimum distance being interposed therebetween and in the direction other than the projection direction thereof. The first opposing area of a portion which includes the non-projection direction opposing surfaces and where the end projecting portion and the opposing projecting portion are opposed to each other with the minimum distance being interposed therebetween is larger than the second opposing area obtained when a plane of the end projecting portion and a plane of the opposing projecting portion, which are orthogonal to the projection direction, are opposed to each other in the projection direction
Hence, by a simple structure, in which the non-projection direction opposing surfaces are provided on the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode, an opposing area (discharge area) between the center electrode and the earth electrode can be easily increased. As a result, the extension of the spark discharge gap due to wear of the end projecting portion and the opposing projecting portion caused by the spark discharge can be restricted, which can extend the lifetime of the spark plug.
In addition, an opposing area between the center electrode and the earth electrodes can be increased by a simple structure. Hence, shapes of the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode can be prevented from being complicated. In addition, the size (outside diameter or the like) of the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode can be prevented from increasing.
As described above, a spark plug for an internal combustion engine can be provided which can increase an opposing area between a center electrode and an earth electrode by a simple structure, thereby extending lifetime of the spark plug.
In the spark plug, the side which is inserted into a combustion chamber of the internal combustion engine is referred to as an end side (end side in the axial direction).
In addition, as described above, the spark plug includes the earth electrode. The spark discharge gap is provided between the earth electrode and the end portion of the center electrode. One or more earth electrodes may be provided with respect to the center electrode.
In addition, the first opposing area is an area of a portion which includes the non-projection direction opposing surfaces and where the end projecting portion and the opposing projecting portion are opposed to each other with the minimum distance being interposed therebetween. That is, the first opposing area is an area of a portion of the end projecting portion which includes the non-projection direction opposing surface and where the end projecting portion is opposed to the opposing projecting portion with the minimum distance being interposed therebetween, and an area of a portion of the opposing projecting portion which includes the non-projection direction opposing surface and where the opposing projecting portion is opposed to the end projecting portion with the minimum distance being interposed therebetween. The two areas are the same.
In addition, the second opposing area is an opposing area obtained when a plane of the end projecting portion and a plane of the opposing projecting portion, which are orthogonal to the projection direction, are opposed to each other in the projection direction without changing the outer shapes of the end projecting portion and the opposing projecting portion.
In addition, one of the end projecting portion (42) and the opposing projecting portion (52) is provided with a projection portion (43) projecting toward the other of the end projecting portion (42) and the opposing projecting portion (52). The projection portion (43) is provided with corner portions (44) opposed to the other with the minimum distance (D) being interposed therebetween.
In this case, spark discharge easily occurs from the corner portions of the projection portion provided on one of the end projecting portion and the opposing projecting portion toward the other of the end projecting portion and the opposing projecting portion, which can decrease the required voltage which is required for the spark discharge. Hence, wear of the electrode due to the spark discharge can be restrained, which can further extend the lifetime of the spark plug.
In addition, the projection portion is provided on the negative electrode side, which is one of the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode. For example, when the earth electrode is used as the positive electrode side, and the center electrode is used as the negative electrode side, sparks are emitted from the center electrode to the earth electrode. In this case, the projection portion is provided on the end projecting portion of the center electrode. Hence, the advantage described above can be effectively utilized.
In addition, the whole outer periphery of at least part of the projection portion (43) of one of the end projecting portion (42) and the opposing projecting portion (52), which includes the corner portions (44), is covered with the other of the end projecting portion (42) and the opposing projecting portion (52).
In this case, a spark discharge is generated more easily from the corner portions of the projection portion of one of the end projecting portion and the opposing projecting portion toward the other of the end projecting portion and the opposing projecting portion, which can further decrease the required voltage which is required for the spark discharge. Hence, wear of the electrode due to the spark discharge can be further restrained, which can further extend the lifetime of the spark plug.
In addition, the first opposing area is preferably 1.25 times or more larger than the second opposing area.
In this case, the above advantage to extend the lifetime of the spark plug can be effectively utilized by increasing the opposing area between the center electrode and the earth electrode with a simple structure.
In addition, the first opposing area is preferably 1.75 times or less larger than the second opposing area.
For example, if the first opposing area is more than 1.75 times larger than the second opposing area, shapes of the end projecting portion of the center electrode and the opposing projecting portion of the earth electrode can be complicated, the size (outside diameter or the like) of the end projecting portion and the opposing projecting portion can increase, and manufacturing the end projecting portion and the opposing projecting portion can be difficult.
Number | Date | Country | Kind |
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2012-159586 | Jul 2012 | JP | national |