DE102016105365A1 - spark plug - Google Patents

Abstract

A spark plug (100) comprises a cylindrical metal housing (50) and an insulator (10) having an axial hole (12) along an axial direction (O), at least a portion of an outer circumference of the insulator (10) passing through the metal housing (50). is held. A center electrode (20) is provided in the axial hole (12) and protrudes toward a front end side in the axial direction so as to be closer than the metal shell (50) at the front end side. A ground electrode (50) has a base end fixed to the metal shell (50) and a facing surface (31) that faces a center electrode front end surface (25) which is a front end surface of the center electrode (20) , is turned on. In the spark plug (100), the center electrode front end surface (25) is positioned on an axial line (O). In addition, when the center electrode front end surface (25) and the facing surface (31) each face a first imaginary plane (VS1) perpendicular to the axial line (FIG. O), projected areas (Ar1) overlap each other. Further, a center (C) in a width direction (WD) of the facing surface (31) is displaced from the axial line (O). And further, at least a portion of the facing surface (31) is inclined with respect to the first imaginary plane (VS1).

Description

GENERAL PRIOR ART

1. Field of the invention

The present invention relates to a spark plug.

2. Description of the Related Art

The ignitability of a spark plug changes with the position of a ground electrode in a cylinder when the spark plug is attached to an engine head. Therefore, a technique for positioning the ground electrode has been proposed to increase the ignitability of the spark plug (see, for example, U.S. Pat Japanese Patent Laid-Open Publication No. 2004-92410 ).

BRIEF SUMMARY OF THE INVENTION

 Accordingly, it is an object of the present invention to provide a spark plug in which, in particular, the ignitability can be increased when a ground electrode has been positioned.

 For this purpose, the present invention may be embodied in the following forms.

 In accordance with a basic form of the present invention, a spark plug is provided. The spark plug points to a cylindrical metal housing; an insulator having an axial hole along an axial line, wherein at least a portion of an outer periphery of the insulator is held by the metal housing; a center electrode provided in the axial hole and protruding along the direction of the axial line to a front end side so as to be closer than the metal case on the front end side; and a ground electrode having a base end fixed to the metal shell and a facing surface facing a center electrode front end surface which is a front end surface of the center electrode. In the spark plug, the center electrode front end surface is positioned on the axial line. In addition, when the center electrode front end surface and the facing surface are respectively projected onto a first imaginary plane perpendicular to the axial line, the center electrode front end surface and the facing surface have regions overlapping each other. In addition, a center of the facing surface is shifted in a width direction from the axial line. And moreover, the facing surface is inclined with respect to the first imaginary plane. After the spark plug having such a shape, the facing surface of the ground electrode facing the front end surface of the center electrode is inclined with respect to the first imaginary plane perpendicular to the axial line, so that it can be positioned and positioned by such positioning Spark plug on an engine that the air flow in a cylinder extends along the inclined portion, it is possible to increase the velocity of the air flow between the ground electrode and the center electrode. Therefore, it is possible to expand a spark generated at the time of discharge, so that the ignitability of the spark plug can be increased. In this embodiment, since the center of the facing surface of the ground electrode is shifted from the axial line, it is possible to reduce the disturbing influence of the ground electrode on the growth of a flame. Consequently, it is possible to increase the ignitability of the spark plug.

 In the spark plug having the above-described shape, when the spark plug is viewed from a direction perpendicular to a ground electrode front end surface which is a front end surface of the ground electrode, the facing surface may be inclined so as to be inclined Distance along the axial line between the facing surface and a second imaginary plane containing the center electrode front end surface becomes the shortest at the center electrode front end surface. Since, according to the spark plug having such a structure, the facing surface is inclined so that the distance between the facing surface of the ground electrode and the center electrode front end surface becomes shortest along the axial line, it is possible to reduce the disturbing influence of the ground electrode on the growth of the Effectively reduce flame.

 In the spark plug having the above-described shape, the ground electrode may be provided with a noble metal tip, and when the noble metal tip and the center electrode front end face are respectively projected on the first imaginary plane, the noble metal tip and the center electrode front end face may have portions facing each other cover. Since the ground electrode is provided with the noble metal tip after the spark plug having such a shape, it is possible to increase the durability of the ground electrode.

 In the spark plug having the above-described shape, the noble metal tip may protrude from the ground electrode in a direction opposite to a direction in which the center is shifted in the width direction of the facing surface from the axial line. According to the spark plug having such a shape, even if a spark is generated on a side surface side of the ground electrode, it is possible to increase the durability of the ground electrode since the noble metal tip is present in this portion.

In the spark plug having the shape described above, when the straight line is at a position located on the center electrode front end surface and having the smallest distance to the ground electrode in a direction perpendicular to the axial line 45 degrees with respect to a metal shell front end surface, which is a front end surface of the metal shell, the straight line can cut the noble metal tip. Since the noble metal tip after the spark plug having such a shape is arranged over a wide area of the ground electrode, it is possible to increase the durability of the ground electrode.

 The spark plug having the above-described structure may be provided on a cylinder having one or more first ports communicating with an intake manifold of an internal combustion engine and one or more second ports communicating with an exhaust manifold. In this spark plug, one or the direction in which the center of the facing surface is shifted in the width direction from the axial line, a direction from a center of gravity at a position or positions of the one or more second openings to a center of gravity at a position or positions corresponding to one or more first openings. According to the spark plug having such a shape, the likelihood that the ground electrode is displaced and disposed in a direction opposite to the direction in which the air flow flows in the cylinder is increased, so that it is possible to disturbing influence of the ground electrode on the expansion of a spark and to reduce the growth of a flame.

 The present invention may be embodied in various forms other than the form of the above-described spark plug, such as a method of manufacturing a spark plug, an ignition system using a spark plug, and an internal combustion engine having a spark plug.

BRIEF DESCRIPTION OF THE DRAWINGS

1 is a partial sectional view of a spark plug according to a first embodiment.

2 illustrates the shape of the front of a ground electrode.

3 FIG. 12 is a schematic view of the shape of a ground electrode front end surface. FIG.

4 is an explanatory view of the shape of one side of the ground electrode.

5 illustrates the direction of airflow in a cylinder.

6 illustrates the shape of the front of a ground electrode according to a second embodiment.

7 illustrates the shape of the front of a ground electrode according to a third embodiment.

8th illustrates the shape of the front of a ground electrode according to a fourth embodiment.

9 illustrates the shape of the front of a ground electrode according to a fifth embodiment.

10 illustrates the shape of the front of a ground electrode according to a sixth embodiment.

11 FIG. 12 illustrates the shape of the front side of a ground electrode according to a seventh embodiment. FIG.

12 illustrates the shape of a side of a ground electrode according to a first modification.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

First embodiment

1 is a partial sectional view of a spark plug 100 according to a first embodiment of the present invention. As in 1 shown is the spark plug 100 along an axial line O long and narrow. In 1 is the right side of the alternately long and short dashed axial line O an outer front view of the spark plug 100 , and the left side of the axial line O is a sectional view of the spark plug 100 in a cross section extending on a center axis of the spark plug and beyond. In the description below, the upper side in FIG 1 is referred to as the front end side in an axial direction OD, and the lower side in FIG 1 referred to as the back end side in the axial direction OD.

The spark plug 100 has an insulator 10 , a center electrode 20 , a ground electrode 30 , a terminal metal housing 40 and a metal case 50 on. At least a portion of an outer periphery of the insulator 10 is through the cylindrical metal housing 50 held. The insulator 10 has an axial hole 12 which extends along the axial direction OD. The center electrode 20 is in the axial hole 12 provided and stands thus to the Front end in the axial direction OD before that they are closer than the metal case 50 located at the front end side. A base end of the ground electrode 30 is on the metal case 50 attached. Between the earth electrode 30 and the center electrode 20 is a spark gap, which is a gap in which a spark is generated formed.

The insulator 10 is an insulating glass formed by sintering an alumina-containing ceramic material. The insulator 10 is a cylindrical element that forms the axial hole 12 which is formed at its center and the center electrode 20 and the terminal metal housing 40 receives. At a middle section of the insulator 10 in the axial direction is a center body 19 formed with a larger outer diameter. A back-end body 18 that provides insulation between the terminal metal housing 40 and the metal case 50 is closer than the centerbody 19 on the connection metal housing 40 educated. A front-end body 17 whose outside diameter is smaller than that of the rear end body 18 is closer than the centerbody 19 at the center electrode 20 educated. Beyond the front end body 17 is an insulator footer section 13 whose outer diameter is smaller than that of the front-end body 17 is and its outer diameter to the side of the center electrode 20 becomes smaller, formed.

The metal case 50 is a cylindrical metal housing that houses a section of the insulator 10 that is from a section of the back-end body 18 of the insulator 10 to the insulator foot length section 13 extends, surrounds and holds. For example, the metal housing 50 is formed of a low carbon steel and is subjected to a coating such as a nickel plating or a zinc plating as a whole. The metal case 50 has a tool engaging portion from the back end side to the front end side in turn 51 , a sealing section 54 and a mounting thread portion 52 on. A tool for attaching the spark plug 100 on a motor head is to the tool engaging portion 51 set. The attachment thread section 52 has a screw thread which is screwed into a mounting screw hole in the motor head. The sealing section 54 is at a base of the attachment thread portion 52 formed in the shape of a flange. An annular seal 5 formed by bending a plate member becomes between the sealing portion 54 and the motor head set and inserted. A front end surface of the metal housing 50 (hereinafter referred to as the "metal shell front end surface 57 ") is a hollow cylinder 13 of the insulator 10 and the center electrode 20 stand out from the middle of the hollow cylinder.

A thin crimping section 53 is closer than the tool engaging portion 51 of the metal housing 50 provided at the back end. A press-forming section 58 as thin as the crimp section 53 is, is between the sealing section 54 and the tool engaging portion 51 provided. Ring-shaped rings 6 and 7 are in an area different from the tool-engaging section 51 to the crimping section 53 extends between an outer peripheral surface of the rear end side body 18 of the insulator 10 and an inner peripheral surface of the metal shell 50 used. A section between the rings 6 and 7 is with powdered talc 9 filled. If the spark plug 100 is manufactured, the Pressverformungsabschnitt 58 by such pushing of the crimping section 53 to the front end side, that it is bent inward, compressed and deformed. By compressing and deforming the press-forming section 58 becomes the insulator 10 in the metal case 50 through the rings 6 and 7 and the talk 9 pushed to the front end. By pushing the insulator 10 becomes the talk 9 compressed in the direction of the axial line O, so that the airtightness in the metal housing 50 is increased.

On an inner circumference of the metal housing 50 becomes a glass stage section 15 at a base end of the insulator foot portion 13 of the insulator 10 is positioned by an annular plate seal 8th against a step section 56 in the metal case 50 and at the attachment thread portion 52 is formed, pushed. The plate seal 8th is an element that provides airtightness between the metal case 50 and the insulator 10 maintains and prevents the escape of combustion gas.

The center electrode 20 is a rod-shaped element in which a core material 22 compared to an electrode base material 21 has excellent thermal conductivity in the electrode base material 21 is embedded. The electrode base material 21 contains a nickel alloy whose main constituent is nickel. The core material 22 contains copper or an alloy whose main constituent is copper. The term "main component" refers to a component having the highest mass percentage among the constituents of an object, and does not necessarily refer to an ingredient whose mass percentage 50 Exceeds percent by mass.

Near a back end portion of the center electrode 20 is a flange 23 formed on the side of the outer periphery is formed. The flange 23 is from the back end side with a step section 14 that in the axial hole 12 is formed, in contact, so that the center electrode 20 in the insulator 10 is positioned. The back end section of the center electrode 20 is about a ceramic resistor 3 and a sealing element 4 electrically with the connection metal housing 40 connected. A substantially circular cylindrical precious metal point 24 is at a front end of the center electrode 20 welded. The precious metal tip 24 is formed of, for example, platinum (Pt), iridium (Ir), ruthenium (Ru), rhodium (Rh) or alloys thereof. In the following description, the term "center electrode 20 "also be used so that he also the precious metal tip 24 includes.

The ground electrode 30 is made of a metal with a high corrosion resistance. For example, a nickel alloy with main component nickel such as Inconel (trade name) 600 or Inconel 601 is used. The base end of the ground electrode 30 is to the metal housing front end surface 57 welded. A middle section of the ground electrode 30 is bent about 90 degrees so that a side surface (a facing surface 31 in 2 ) of the ground electrode 30 to the center electrode 20 is turned. The ground electrode 30 may have a two-layered structure in which copper or a copper alloy is embedded in a base material which is the above-mentioned nickel alloy, or a three-layered structure in which nickel or a nickel alloy is embedded in copper or a copper alloy.

2 illustrates the shape of the front of the ground electrode 20 , In the embodiment, the spark plug is 100 positioned and attached to a motor head so that the air flow in a cylinder from left to right in 2 flows. The base end of the ground electrode 30 is on the metal housing front end surface 57 attached, and the ground electrode 30 indicates the facing surface 31 leading to a front end surface of the center electrode 20 (hereinafter referred to as the "center electrode front end surface 25 The facing surface 31 is with a precious metal tip 32 Mistake. The facing surface 31 the earth electrode 30 also has a rear end surface of the noble metal tip 32 in the axial direction OD. The precious metal tip 32 is formed of, for example, platinum (Pt), iridium (Ir), ruthenium (Ru), rhodium (Rh) or alloys thereof. The term "ground electrode 30 "can also be used so that it also has the precious metal tip 32 includes. The center electrode front end surface 25 is positioned on the axial line O When the center electrode front end surface 25 and the facing surface 31 the earth electrode 30 are each projected onto a first imaginary plane VS1, which is perpendicular to the axial line O, they have areas AR1 which overlap each other. When the center electrode front end surface 25 and the precious metal tip 32 the earth electrode 30 are each projected onto the first imaginary plane VS1, they have areas AR2 which overlap each other. In the embodiment, the projection surface is the center electrode front end surface 25 with respect to the first imaginary plane VS1 smaller than the projection surface of the facing surface 31 and the projection surface of the precious metal tip 32 , Further, the projected area is the center electrode front end surface 25 also in the projected area of the facing area 31 and in the projected area of the noble metal tip 32 contain. Therefore, the area AR1 and the area AR2 respectively correspond to the projected area of the center electrode front end face 25 and their positions and sizes are the same.

A center C of the facing surface 31 the earth electrode 30 in a width direction WD is shifted from the axial line O to an upstream side in the direction of the airflow (the center C is off-axis in a direction perpendicular to the axial line O, and the off-axis side of the facing surface 31 may be referred to as the upstream side). The width direction WD is perpendicular to the axial line O. In contrast, the noble metal tip 32 so at the ground electrode 30 provided to a downstream side in the direction of the air flow, that is, in a direction complementary to the direction in which the center C of the ground electrode 30 is displaced from the axial line O, is opposite, protrudes. At least a portion of the facing surface 31 the earth electrode 30 is with respect to the first imaginary plane VS1 and the metal shell front end side 57 inclined. It is more accurate when the spark plug 100 from a direction perpendicular to a front end surface of the ground electrode 30 (hereinafter referred to as the "ground electrode front end surface 33 "referred to), is her forth, at least a portion of the facing surface 31 the earth electrode 30 inclined so that a distance D1 in the axial direction OD between the facing surface 31 the earth electrode 30 and a second imaginary plane VS2 including the center electrode front end surface 25 at the center electrode front end surface 25 becomes the shortest.

3 Fig. 12 is a schematic view of the shape of the ground electrode front end surface 33 , In the embodiment, a first side surface extends 34 the earth electrode 30 leading to the facing surface 31 is opposite, perpendicular to the axial line O. A second side surface 35 and a third side surface 36 extending from the first side surface 34 extend to the back end side in the axial direction OD, are substantially parallel to the axial line O. In the direction of the air flow is the second side surface 35 an upstream side surface, and is the third side surface 36 a downstream side surface. A thickness T1 of the second side surface 35 along the axial line O is smaller than a thickness T2 of the third side surface 36 along the axial line O. A width W1 of the first side surface 34 in a direction perpendicular to the axial line O is greater than the thickness T1 of the second side surface 35 and the thickness T2 of the third side surface 36 , When the ground electrode front end surface 33 is divided by a center line C in its width direction WD (the center line C is parallel to the axial line O) becomes the ground electrode front end surface 33 in a region A1 having a small area dimension (the area A1 is located between the second side surface 35 and the center line C) and a region A2 (the region A2 is located between the third side surface and the center line C) having a large area dimension. In the embodiment, of these areas A1 and A2, the small-area-dimension area A1 is located on the upstream side in the direction of the airflow, and the large-area area A2 on the downstream side is located in the direction of the airflow.

4 is an explanatory view of the shape of one side of the ground electrode 30 , 4 illustrates the in 2 shown spark plug 100 from the right side in 2 (ie, from the downstream side in the direction of the airflow). According to the embodiment, the front end portion of the ground electrode extends 30 in a direction perpendicular to the axial line O, to a position corresponding to a position located on the center electrode front end surface 25 and in the direction perpendicular to the axial line O, farthest from the ground electrode 30 is removed. In the embodiment, the noble metal tip 32 a substantially parallelepiped shape extending in a longitudinal direction, and is at a foremost end side (the left side in 4 ) of the ground electrode 30 arranged. Further, when a straight line X intersects from a position P1 located on the center electrode front end surface 25 located and in a direction which is perpendicular to the axial line O, the smallest distance to the ground electrode 30 at an angle of 45 degrees with respect to the metal shell front end surface 57 the straight line X is the precious metal point 32 , A length D of the precious metal tip 32 in the longitudinal direction is greater than a distance E from an intersection P2 at which the straight line X is the noble metal tip 32 cuts to the ground electrode front end surface 33 , The reason why the angle of the straight line X used for determining the intersection point P2 is 45 degrees is that when a spark is generated from an end portion of the center electrode front end surface 25 as in 4 the direction at the oblique angle of 45 degrees is the direction in which the electric field strength is strongest and spark generation easily occurs. Therefore, it is possible to effectively reduce the wear of the electrodes when the noble metal tip 32 from the ground electrode front end surface 33 is arranged up to the intersection point P2.

5 illustrates the direction of airflow in a cylinder 70 an engine. 5 illustrates the state in the cylinder 70 seen from a piston schematic. The spark plug 100 is at a substantially middle portion of an upper surface 75 in the cylinder 70 arranged. To the spark plug 100 around are first openings 61 and 62 that with an intake manifold 71 communicate, and second openings 63 and 64 provided with an exhaust manifold, provided. At each of the first openings 61 and 62 an inlet valve is arranged. At each of the second openings 63 and 64 an exhaust valve is arranged. In the embodiment, it is assumed that the air flow in the cylinder 70 in a direction from a center of gravity P13 between a center position P11 of the first opening 61 and a center position P12 of the first opening 62 to a center of gravity P23 between a center position P21 of the second opening 63 and a center position P22 of the second opening 64 flows. More specifically, it is assumed that the air flow in the cylinder 70 then when the first openings 61 and 62 and the second openings 63 and 64 are projected onto a projection plane perpendicular to the axial line O of the spark plug 100 extends, in the direction of the center of gravity P13 between the center positions P11 and P12 of the respective first openings 61 and 62 in the plane of projection to the center of gravity P23 between the center positions P21 and P22 of the respective second openings 63 and 64 flowing in the projection plane. Therefore, the direction in which the center C of the facing surface 31 the earth electrode 30 in the width direction WD is shifted from the axial line O, in 2 in 5 a direction opposite to the direction of the airflow, that is, in the direction from the center of gravity P23 between the positions P21 and P22 of the respective second openings 63 and 64 to the center of gravity P13 between the positions P11 and P12 of the respective first openings 61 and 62 , Although in 5 By way of example, a case is shown in which two first openings and two second openings are arranged, any number of first openings and second openings may be used, depending on the motor.

Because after the spark plug 100 the above-described embodiment, the facing surface 31 the earth electrode 30 leading to the center electrode front end surface 25 is inclined, it is possible to control the speed of the air flow in to increase the spark gap by removing the spark plug 100 attached to the engine head so that the air flow in the cylinder 70 flows along the inclined portion. Therefore, it is possible to expand a spark generated at the time of discharge along the direction in which the air flow flows, so that the ignitability of the spark plug 100 can be increased. Moreover, in the embodiment, the center C of the facing surface 31 the earth electrode 30 is shifted from the axial line O, it is possible, the disturbing influence of the ground electrode 30 to reduce the growth of a flame. Therefore, it is possible the ignitability of the spark plug 100 to increase.

As in the embodiment, the facing surface 31 the earth electrode 30 is inclined so that the distance D1 between the facing surface 31 and the center electrode front end surface 25 along the axial line O becomes the shortest, it is possible to eliminate the disturbing influence of the ground electrode 30 to effectively reduce the growth of a flame.

Further, in the embodiment, the noble metal tip 32 so at the ground electrode 30 provided that it protrudes downstream in the direction of the air flow. Therefore, even when generating a spark riding on an airflow, it is at the side of a side surface of the ground electrode 30 possible, the durability of the ground electrode 30 increase as the precious metal tip 32 located in this section.

When a large amount of power is applied from an ignition coil of an ignition system to expand a spark, it is very likely that the range of generation of the spark will become a wide range. But there in the embodiment as in 4 shown the precious metal tip 32 is provided over a wide range, a wear of the ground electrode 30 which is caused by the generation of the spark over the wide range can be effectively suppressed.

In the embodiment, the ground electrode 30 in the direction opposite to the direction in which the air flow flows, is displaced and arranged, it is possible to eliminate the disturbing influence of the ground electrode 30 to reduce the growth of a flame.

Other embodiments

6 illustrates the shape of the front of a ground electrode 30a according to a second embodiment. In the second embodiment, the shape of a ground electrode front end surface is different 33 from that according to the first embodiment, whereas the other portions are the same as those according to the first embodiment. More specifically, in the second embodiment, in spite of the fact that a facing surface 31a as in the first embodiment is inclined, between a first side surface 34 and the facing surface 31a no second surface 35 available. Instead, it is through the first side surface 34 and the facing surface 31a an acute-angled section 37 educated. Also with this ground electrode 30a is when a spark plug 100a from a direction perpendicular to the ground electrode front end surface 33 runs, her forth, the facing surface 31a the earth electrode 30 inclined so that a distance D1 along the axial direction OD between the facing surface 31a and a second imaginary plane VS2 having a center electrode front end surface 25 at the center electrode front end surface 25 becomes the shortest. Therefore, as in the first embodiment, it is possible to increase the flow velocity in a spark gap and the ignitability of the spark plug 100a to increase.

7 illustrates the shape of the front of a ground electrode 30b according to a third embodiment. In the third embodiment, the shape of a facing surface is different 31b the earth electrode 30 from that according to the first embodiment, whereas the other portions are the same as those according to the first embodiment. While, more precisely, the shape of the facing surface 31 in the first embodiment, at the ground electrode front end surface 33 is rectilinear, is the shape of the facing surface 31b in a convex shape to the upper right side in 7 (that is, downstream in the direction of air flow and toward the front end side in the axial direction OD). Also with this ground electrode 30b is when a spark plug 100b from a direction perpendicular to the ground electrode front end surface 33 runs, her forth, the facing surface 31b the earth electrode 30 inclined so that a distance D1 along the axial direction OD between the facing surface 31b and a second imaginary plane VS2 having a center electrode front end surface 25 at the center electrode front end surface 25 becomes the shortest. Therefore, as in the first embodiment, it is possible to increase the flow velocity in a spark gap and the ignitability of the spark plug 100b to increase.

8th illustrates the shape of the front of a ground electrode 30c according to a fourth embodiment. In the fourth embodiment, the shape of a facing surface is different 31c the earth electrode 30c from that according to the first embodiment, whereas the other portions are after those of the first embodiment Embodiment are the same. More specifically, in the fourth embodiment, the shape of the facing surface 31c in a direction opposite to that in the third embodiment (that is, upstream in the direction of the airflow and toward the rear end side in the axial direction OD) curved in a convex shape. Also with this ground electrode 30c is when a spark plug 100c from a direction perpendicular to a ground electrode front end surface 33 runs, her forth, the facing surface 31c the earth electrode 30 inclined so that a distance D1 along the axial direction OD between the facing surface 31c and a second imaginary plane VS2 having a center electrode front end surface 25 at the center electrode front end surface 25 becomes the shortest. Therefore, as in the first embodiment, it is possible to increase the flow velocity in a spark gap and the ignitability of the spark plug 100c to increase.

9 illustrates the shape of the front of a ground electrode 30d according to a fifth embodiment. In the fifth embodiment, the shape of the facing surface is different 31d and the shape of a first side surface 34d the earth electrode 30d of those according to the first embodiment, whereas the other portions are the same as those of the first embodiment. More specifically, in the fifth embodiment, the shape of the facing surface 31d that after the in 8th shown fourth embodiment. The shape of the first side surface 34d is in a convex shape to an upper left side in 9 (that is, upstream in the direction of air flow and toward the front end side in the axial direction OD). Also with this ground electrode 30d is when a spark plug 100d from a direction perpendicular to a ground electrode front end surface 33 runs, her forth, the facing surface 31d the earth electrode 30d inclined so that a distance D1 along the axial direction OD between the facing surface 31d and a second imaginary plane VS2 having a center electrode front end surface 25 at the center electrode front end surface 25 becomes the shortest. Therefore, as in the first embodiment, it is possible to increase the flow velocity in a spark gap and the ignitability of the spark plug 100d to increase.

10 illustrates the shape of the front of a ground electrode 30e according to a sixth embodiment. In the sixth embodiment, the shape of a third side surface is different 36e the earth electrode 30e from that according to the first embodiment, whereas the other portions are the same as those according to the first embodiment. More specifically, in the sixth embodiment, the third side surface is 36e so inclined that the front end side of the third side surface 36e in the axial direction OD is positioned closer than the back end side on an upstream side in the direction of the air flow. Also with this ground electrode 30e is when a spark plug 100e from a direction perpendicular to a ground electrode front end surface 33 runs, her forth, the facing surface 31e the earth electrode 30e inclined so that a distance D1 along the axial direction OD between the facing surface 31e and a second imaginary plane VS2 having a center electrode front end surface 25 at the center electrode front end surface 25 becomes the shortest. Therefore, as in the first embodiment, it is possible to increase the flow velocity in a spark gap and the ignitability of the spark plug 100e to increase.

11 illustrates the shape of the front of a ground electrode 30f according to a seventh embodiment. In the seventh embodiment, the shape of a noble metal tip is different 32f from that according to the first embodiment, whereas the other portions are the same as those according to the first embodiment. More specifically, in the seventh embodiment, the noble metal tip 32f has a size larger than that according to the first embodiment and that allows the entire third side surface 36f the earth electrode 30f is covered. Also with this ground electrode 30f is when a spark plug 100f from a direction perpendicular to a ground electrode front end surface 33 runs, is considered, a facing surface 31f the earth electrode 30f inclined so that a distance D1 along the axial direction OD between the facing surface 31f and a second imaginary plane VS2 having a center electrode front end surface 25 at the center electrode front end surface 25 becomes the shortest. Therefore, as in the first embodiment, it is possible to increase the flow velocity in a spark gap and the ignitability of the spark plug 100f to increase. Because the precious metal tip 32f is large, it is also possible in the embodiment, the durability of the ground electrode 30f continue to increase. Because the precious metal tip 32f in the embodiment, in particular, the entire third side surface 36f at a front end portion of the ground electrode 30f covering is the precious metal point 32f even if a spark on the side of the third side surface 36f the earth electrode 32f is generated over a wide range of this section, so that it is possible, the durability of the ground electrode 30f continue to increase.

modifications

First modification

12 illustrates the shape of one side of a ground electrode 30g after a first modification. Also with this modification then cuts, if as in 4 show a straight line X at an angle of 45 degrees with respect to the metal shell front end surface 57 from a position P1 located on the center electrode front end surface 25 located and in a direction which is perpendicular to the axial line O, the smallest distance to the ground electrode 30 pulled, the straight line X is the precious metal tip 32 , In the modification, a structure of a front end portion of the ground electrode differs 30g from the in 4 shown construction. More specifically, in the modification, a front end of the ground electrode extends 30g so to the front end that it is closer than the precious metal tip 32 located at the front end side. Accordingly, the shape of the ground electrode 30g not limited to the shapes according to the various embodiments described above.

Second modification

Although in the embodiments described above, the noble metal tip 32 at the ground electrode 30 is provided and the precious metal tip 24 at the center electrode 20 is provided, it is not necessary, one or both of the noble metal tips 24 and 32 to use.

Third modification

In the embodiments described above, the facing surface 31 the earth electrode 30 then, if the spark plug 100 from the direction perpendicular to the ground electrode front end surface 33 runs, inclined so that the distance D1 along the axial direction OD between the facing surface 31 and the second imaginary plane VS2, which is the center electrode front end surface 25 at the center electrode front end surface 25 becomes the shortest. In contrast, the facing surface 31 be inclined so that the distance D1 at a location that is not the center electrode front end surface 25 is, is the shortest.

Fourth modification

In the embodiments described above, the noble metal tip 32 and the center electrode front end surface 25 then, if the precious metal tip 32 the earth electrode 30 and the center electrode front end surface 25 projected onto the first imaginary plane VS1, areas that overlap each other. Here, the phrase "cover" means "completely cover" and "partially cover". That is, if the precious metal tip 32 the earth electrode 30 and the center electrode front end surface 25 projected on the first imaginary plane VS1, it is sufficient if only portions of the projected areas overlap each other. In addition, it is sufficient if the center electrode front end surface 25 projected onto the first imaginary plane VS1 is the projected area of the center electrode front end surface 25 only at least a portion of the facing surface 31 the earth electrode 30 covered. And moreover, in a projection of the precious metal tip 32 the earth electrode 30 and the center electrode front end surface 25 on the first imaginary plane VS1 their projected areas do not overlap one another.

Fifth modification

Although in the embodiments described above, the noble metal tip 32 the earth electrode 30 in that direction from the ground electrode 30 protrudes, leading to the direction in which the center C in the width direction WD of the facing surface 31 is displaced from the axial line O, is opposite, needs the precious metal tip 32 not in the direction corresponding to the direction in which the center C in the width direction WD of the facing surface 31 is displaced from the axial line O, to protrude.

Sixth modification

In the embodiments described above, the straight line X intersects the noble metal tip 32 at the intersection P2 when the straight line X is from a position P1 located on the center electrode front end surface 25 located and in a direction which is perpendicular to the axial line O, the smallest distance to the ground electrode 30 at an angle of 45 degrees with respect to the metal shell front end surface 57 is pulled. But the straight line X needs the precious metal tip 32 do not cut.

Seventh variation

In the above-described embodiments, the direction in which the center C in the width direction WD corresponds to the facing surface 31 is displaced from the axial line O, the direction from the center of gravity P23 between the positions of the respective second openings 63 and 64 to the center of gravity P13 between the positions of the first openings 61 and 62 , This direction does not need to be exactly from the center of gravity P23 to the center of gravity P13. As long as the velocity of the airflow can be increased, this direction may be a direction that is in relation to the direction from the center of gravity P23 to the Center of gravity P13 with the axial line O as the center at an angle in the range of about ± 40 degrees.

 The present invention is not limited to the above-described embodiments and modifications, so that various configurations can be made within a scope that does not depart from the gist of the present invention. For example, any of the technical features in the embodiments and modifications that correspond to the technical features in the forms described in the "Summary of the Invention" section may correspond to how to solve some or all of the above problems or to achieve some or all of the above all of the above advantages are appropriately replaced by others or combined with others. If their technical features are not described as essential, they may be omitted as appropriate.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• JP 2004-92410 [0002]

Claims (7)

Spark plug ( 100 ) comprising: a cylindrical metal housing ( 50 ); an insulator ( 10 ) with an axial hole ( 12 ) along an axial line (O), wherein at least a portion of an outer circumference of the insulator ( 10 ) through the metal housing ( 50 ) is held; a center electrode ( 20 ) located in the axial hole ( 12 ), wherein the center electrode ( 20 ) protrudes to a front end side of the axial line (O) so as to be closer than the metal shell (O). 50 ) is located at the front end side; and a ground electrode ( 50 ) with a base end which is fixed to the metal housing, and a facing surface ( 31 ) leading to a central electrode front end surface ( 25 ), which is a front end surface of the center electrode (FIG. 20 ), with the center electrode front end surface ( 25 ) is positioned on the axial line (O), wherein when the center electrode front end face ( 25 ) and the facing surface ( 31 ) are each projected onto a first imaginary plane (VS1) which is perpendicular to the axial line (O), the central electrode front end surface (FIG. 25 ) and the facing surface ( 31 ) Have areas that overlap each other, wherein a center (C) of the facing surface ( 31 ) is displaced in a width direction (WD) from the axial line (O), and wherein at least a portion of the facing surface (WD) 31 ) is inclined with respect to the first imaginary plane (VS1). Spark plug ( 100 ) according to claim 1, wherein when the spark plug ( 100 ) from a direction perpendicular to a ground electrode front end surface (FIG. 33 ), which is a front end surface of the ground electrode ( 30 ), is considered, the facing surface ( 31 ) is inclined so that a distance (D1) along the axial line (O) between the facing surface (D1) 31 ) and a second imaginary plane (VS2) containing the central electrode front end surface (VS2). 25 ) at the central electrode front end surface ( 25 ) is the shortest. Spark plug ( 100 ) according to claim 1 or 2, wherein the ground electrode ( 30 ) with a precious metal tip ( 32 ), and wherein when the noble metal tip ( 32 ) and the central electrode front end surface ( 25 ) are each projected onto the first imaginary plane (VS1), the precious metal tip ( 32 ) and the central electrode front end surface ( 25 ) Have areas (Ar2) that overlap each other. Spark plug ( 100 ) according to claim 3, wherein the noble metal tip ( 32 ) from the ground electrode ( 30 ) protrudes in a direction leading to a direction in which the center (C) of the facing surface ( 31 ) in the width direction (WD) from the axial line (O) is opposite. Spark plug ( 100 ) according to claim 3 or 4, wherein when a straight line (X) is at an angle of 45 degrees with respect to a front end face (Fig. 57 ) of the metal housing ( 50 ) from a position (P1) located on the center electrode front end surface (P1). 25 ) and in a direction which is perpendicular to the axial line (O), the smallest distance to the ground electrode ( 30 ), the straight line (X) is the noble metal tip ( 24 ) cuts. Spark plug ( 100 ) according to one of claims 1 to 5, wherein the spark plug ( 100 ) is adapted to a cylinder ( 70 ) having one or more first openings ( 61 ) fitted with an intake manifold ( 71 ) of an internal combustion engine, and one or more second openings ( 63 ) fitted with an exhaust manifold ( 72 ), wherein one or the direction in which the center (C) of the facing surface ( 31 ) in the width direction (WD) from the axial line (O), a direction from a center of gravity (P23) at a position or positions (P21) of the one or more second openings (P) 63 ) to a center of gravity (P13) at a position or positions (P11) of the one or more first openings (P13) 61 ) corresponds. Internal combustion engine comprising a cylinder ( 70 ) and a spark plug according to one of the preceding claims, wherein the cylinder ( 70 ) one or more first openings ( 61 ) fitted with an intake manifold ( 71 ) of the internal combustion engine, and one or more second openings ( 63 ) fitted with an exhaust manifold ( 72 ) of the internal combustion engine, wherein a direction in which the center (C) of the facing surface ( 31 ) in the width direction (WD) from the axial line (O), a direction from a center of gravity (P23) at a position or positions (P21) of the one or more second openings (P) 63 ) to a center of gravity (P13) at a position or positions (P11) of the one or more first openings (P13) 61 ) corresponds.

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