JP2019083140A - Electrode structure of ignition plug - Google Patents

Abstract

To prevent heat of an external electrode of an ignition plug from transferring to a cylinder head, and prevent an ignition failure caused by the deterioration of a temperature of the external electrode.SOLUTION: In an electrode structure of an ignition plug 1, having a center electrode 21 and an external electrode 22, the external electrode 22 is structured by a base part 221 connected with a screw part 14 of the ignition plug 1; and a tip part 222 oppositely distributed while having a prescribed space from the center electrode 21, and includes a heat transfer suppression part preventing heat on the tip part 222 side from transferring to the base part 221 side.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an electrode structure of a spark plug of an internal combustion engine.

  In recent years, in order to improve fuel efficiency and exhaust gas regulations of vehicles, a technology of operating with a mixture that is thinner than the theoretical air-fuel ratio and a technology of incorporating part of exhaust gas after combustion and reinhaling it have been developed.

  In an internal combustion engine for the purpose of improving fuel efficiency and exhaust gas regulation as described above, the amount of fuel or air in the combustion chamber deviates from the theoretical value, so that ignition failure of the fuel by the ignition plug is likely to occur. In the spark plug of an internal combustion engine, the fuel is ignited by the discharge between the center electrode and the outer electrode, but when the temperature of the outer electrode of the spark plug is low, the heat of the flame generated by the spark plug is transmitted It is deprived and it becomes easy to occur. As a result, ignition failure of the spark plug is likely to occur.

  Here, the outer electrode of the spark plug is connected to the threaded portion of the housing, and the heat of the outer electrode is transferred to the cylinder head through the threaded portion (housing). As a result, the temperature of the outer electrode, which has become high due to the spark plug discharge, drops sharply.

  Patent Document 1 discloses a multiple spark plug in which a plurality of (two) electrodes are provided in a spark plug to increase the opportunity for ignition to a mixture.

Patent No. 6007345

  However, in the multi-ignition plug disclosed in Patent Document 1, the heat of the outer electrode is transferred to the cylinder head through the flange, whereby the temperature of the outer electrode is rapidly lowered.

  Therefore, the present invention has been made focusing on the above problems, and suppresses the movement of the heat of the outer electrode of the spark plug to the cylinder head and prevents the ignition failure caused by the decrease in the temperature of the outer electrode. With the goal.

  In order to solve the above problems, an electrode structure of a spark plug having a center electrode and an outer electrode, wherein the outer electrode faces the base connected to the main body of the spark plug at a predetermined distance from the center electrode It has a tip part arranged, and has composition which has a heat transfer control part which controls movement to the base side of heat of the tip part side.

  According to the present invention, it is possible to suppress the transfer of heat of the outer electrode of the spark plug to the cylinder head and to prevent the ignition failure caused by the decrease in the temperature of the outer electrode.

It is a figure explaining the ignition plug of the internal combustion engine concerning embodiment. It is sectional drawing of the electrode part concerning embodiment. It is sectional drawing of the electrode part concerning a modification. It is sectional drawing of the electrode part concerning a prior art example. It is sectional drawing of the electrode part concerning 2nd Embodiment. It is sectional drawing of the electrode part concerning 3rd Embodiment. It is sectional drawing of the electrode part concerning 4th Embodiment.

  Hereinafter, a spark plug 1 of an internal combustion engine according to an embodiment of the present invention will be described.

FIG. 1 is a view for explaining a spark plug 1 of an internal combustion engine according to an embodiment.
FIG. 2 is a cross-sectional view of the electrode unit 20 according to the embodiment.
FIG. 3 is a cross-sectional view of an electrode unit 20A according to a modification.
FIG. 4 is a cross-sectional view of the electrode unit 20 according to the conventional example.

  In the following description, the lower side of the drawing in each drawing is defined as the lower side or lower side of the spark plug, and the upper side of the drawing is defined as the upper side or upper side of the spark plug.

[Ignition plug]
As shown in FIG. 1, the spark plug 1 has a terminal 10, an insulator (corrugation) 12, a housing 13, a screw portion 14 and an electrode portion 20.

  The terminal 10 is formed of a metal material. The terminal 10 is connected to an ignition coil (not shown) via a cable (not shown) and is supplied with high voltage current generated by the ignition coil (not shown).

  The insulator 12 covers the terminal 10 along the central axis X direction, and prevents the high voltage current supplied to the terminal 10 from leaking to other than the electrode unit 20 described later.

  The housing 13 is formed of a metal material. The housing 13 supports the insulator 12 and has a function of attaching the spark plug 1 to an internal combustion engine. At the lower portion of the housing 13, a screw portion 14 is provided.

  The screw portion 14 is formed of a metal material. The screw portion 14 is screwably provided in a spark plug mounting hole of a cylinder head (not shown), and is used when fixing the spark plug 1 to the cylinder head (not shown).

  An electrode portion 20 is provided below the screw portion 14. The electrode portion 20 is provided so as to be located in a combustion chamber (not shown) of the cylinder head (not shown) when the spark plug 1 is attached to the cylinder head (not shown).

[Electrode part]
As shown in FIG. 2, the electrode unit 20 has a center electrode 21 and an outer electrode 22.

  The central electrode 21 is connected to the terminal 10 via an axial center (not shown) formed of a steel material. The center electrode 21 is formed of an iridium alloy material or the like.

  In the electrode unit 20, an outer electrode 22 is provided with a predetermined gap S1 in the central axis X direction of the center electrode 21.

  The outer electrode 22 is formed of a nickel chromium steel material or the like.

  The outer electrode 22 is a plate-shaped member having a rectangular shape in a plan view. The thickness of the outer electrode 22 is set to h1. The base portion 221 of the outer electrode 22 is integrally connected to the lower end portion 141 of the screw portion 14 and extends from the lower end portion 141 in the central axis X direction.

  The outer electrode 22 is formed to be bent at a right angle (90 degrees) to the central axis X direction at an intermediate position in the longitudinal direction (the central axis X direction).

  In a cross sectional view, the outer electrode 22 has an L-shaped configuration by the base side wall 23 extending downward from the screw 14 and the tip side wall 24 provided at right angles (90 degrees direction) to the base side wall 23. There is. An inner side surface 222 a of the tip portion 222 of the L-shaped outer electrode 22 is provided to face the center electrode 21.

  In the outer electrode 22, the base side wall portion 23 and the tip side wall portion 24 described above are provided at right angles, and the right angle portion is a redundant portion 27.

  In the outer electrode 22, a predetermined range of the tip portion 222 (inner side surface 222a) facing the center electrode 21 is a high temperature region K (FIG. 2) by the flame generated by the discharge between the outer electrode 22 and the center electrode 21. See hatching). Then, the heat of the high temperature region K of the tip portion 222 moves to the base portion 221 through the tip side wall portion 24, the redundant portion 27 and the base side wall portion 23 (see the arrow in FIG. 2).

  Here, in the outer electrode 22, the base side wall portion 110 and the tip side wall portion 120 of the conventional spark plug 100 are connected by the curved portion 130 as much as the redundant portion 27 exists in the heat transfer path ( 4), the moving distance to the base 221 of the heat generated in the high temperature region K of the tip portion 222 becomes long.

  Therefore, in the outer electrode 22, as a result of the heat transfer distance of the tip portion 222 becoming longer, it takes time for the heat of the tip portion 222 to move to the base portion 221, and the heat of the tip portion 222 is prevented from being rapidly reduced. be able to.

  As shown in the spark plug 1A according to the modified example of FIG. 3, the outer electrode 22A may be provided with a longer redundant portion 27A. In the outer electrode 22A according to the modification, the base side wall portion 23A is extended further downward than the position in the central axis X direction of the tip portion 222A, and then connected to the tip portion 222A through the redundant portion 27A. In this case, the redundant portion 27A may be used as the tip side wall portion 24A.

  As a result, the length of the redundant portion 27A can be made longer than in the embodiment described above in which the base side wall portion 23 and the distal end side wall portion 24 are provided at right angles and the right angle portion is the redundant portion 27. . Therefore, the movement distance to the base 221A of the heat generated in the heating area K1 of the tip 222A can be made longer, and the movement time of the heat of the tip 222A to the base 221A becomes longer. As a result, the temperature of the tip portion 222A of the outer electrode 22A can be maintained at a high temperature for a longer time.

  The redundant portion 27 and the redundant portion 27A of the embodiment described above correspond to the heat transfer suppressing portion of the present invention.

As described above, in the embodiment,
(1) The electrode structure of the spark plug 1 having the center electrode 21 and the outer electrode 22, wherein the outer electrode 22 is a base 221 connected to the screw portion 14 (main body) of the spark plug 1, and the center electrode 21. And a tip portion 222 disposed opposite to each other at a predetermined interval S1, and has a heat transfer suppressing portion (for example, a redundant portion 27) for suppressing the movement of heat to the base portion 221 side of the tip portion 222 side. And

  With this configuration, the electrode structure of the spark plug 1 has a heat transfer suppressing portion (for example, the redundant portion 27) that suppresses the movement of the heat of the tip end portion 222 to the base portion 221 side. The heat transfer time of the tip 222 to the base 221 requires a longer time. Therefore, since the heat transfer suppressing portion can maintain the temperature of the distal end portion 222 at a high temperature for a longer time, it is possible to prevent the ignition failure caused by the decrease in the temperature of the distal end portion 222.

(2) Further, the heat transfer suppressing portion has a length of the outer electrode 22 (or the outer electrode 22A) connecting the tip portion 222 (or the tip portion 222A) and the base portion 221 (or the base portion 221A) The redundant part 27 (or redundant part 27A) (redundant wall) is made redundant than the length.

  According to this configuration, in the outer electrode 22 (or the outer electrode 22A), since the redundant portion 27 (or the redundant portion 27A) is provided, the tip portion 222 (or the tip portion 222A) and the base portion 221 (or the base portion 221A) And the length of the movement of the tip 222 to the base 221 or the movement of the tip 222A to the base 221A becomes longer. Therefore, it takes longer time for the heat of the tip 222 (or tip 222A) to move to the base 221 (or base 221A), and the temperature of the tip 222 (or tip 222A) is longer It is possible to maintain the high temperature and to prevent the ignition failure due to the decrease in the temperature of the tip 222 (or the tip 222A).

Second Embodiment
Next, a second embodiment of the present invention will be described.

  FIG. 5 is a cross-sectional view of the electrode portion 20B of the spark plug 1B according to the second embodiment.

  The electrode portion 20B of the spark plug 1B according to the second embodiment differs from the above-described embodiment in that a notch 25 is provided between the tip portion 222B of the outer electrode 22B and the base portion 221B.

  As shown in FIG. 5, on the inner side surface 222a of the outer electrode 22B, the notch 25 cut by a predetermined length s1 in the direction from the inner side surface 222a to the outer side surface 222b is at a predetermined position in the direction away from the tip 222B. It is provided.

  The notch 25 is provided along the width direction (the direction of the paper surface of FIG. 5) orthogonal to the longitudinal direction of the outer electrode 22B. The notch portion 25 may be provided on the entire (full width) in the width direction of the outer electrode 22B, or may be provided in a partial range in the width direction.

  Therefore, in the outer electrode 22B, a thin portion 26 having a plate thickness h2 (h2 = h1-s1) cut out by a predetermined length s1 is formed from the plate thickness h1 of the outer electrode 22B. The cross-sectional area of the thin portion 26 is smaller than the cross-sectional area of the outer electrode 22B. The base side wall 23B and the tip side wall 24B are connected by the thin portion 26.

  In the outer electrode 22B, the amount of heat that can pass through the thin-walled portion 26 having a small cross-sectional area decreases (see the arrow in FIG. 5). Movement is suppressed. Therefore, the temperature of the distal end portion 222B is maintained at the high temperature for a longer time, and it is possible to prevent the ignition failure caused by the decrease in the temperature of the distal end portion 222B.

  The function of suppressing the movement of heat generated at the tip end portion 222B to the base portion 221B by the notch portion 25 described above corresponds to the heat transfer suppressing portion of the present invention.

  Further, the function of suppressing the movement of heat generated at the tip end portion 222B to the base portion 221B by the thin portion 26 described above corresponds to the heat transfer suppressing portion of the present invention.

As described above, in the second embodiment,
(3) The heat transfer suppressing portion is configured as the notch portion 25 provided between the tip end portion 222B side and the base portion 221B side.

  With this configuration, in the outer electrode 22B, the movement of heat toward the base portion 221B on the tip end portion 222B side is suppressed by the notch portion 25. Therefore, the temperature of the tip end portion 222B is maintained at high temperature for a longer time. Ru. Therefore, in the ignition plug 1B, it is possible to prevent the ignition failure caused by the decrease in the temperature of the tip portion 222B.

(4) Further, in the outer electrode 22B, the notch 25 is formed from the inner side surface 222a which is the opposite surface to the center electrode 21B to the outer surface 222b which is the opposite surface.

  In the spark plug 1B, a flame is generated between the center electrode 21B and the outer electrode 22B, so the temperature on the inner side surface 222a side of the tip portion 222B of the outer electrode 22B becomes particularly high (see hatching in FIG. 5). In this configuration, in the outer electrode 22B, the notch 25 is provided from the inner surface 222a to the outer surface 222b of the tip 222B, and the thin portion 26 on the outer surface 222b side of the outer electrode 22B is the tip. The portion 222B and the base portion 221B are connected.

  Therefore, the heat transfer from the inner side surface 222a of the tip portion 222B to the high temperature to the base portion 221B is blocked by the notch 25 and the heat base is reduced in the thin portion 26 of the outer side surface 222b which is lower in temperature than the inner side surface 222a. A move to 221 B takes place. Thus, in the outer electrode 22B, the movement of the heat of the tip 222B to the base 221B can be efficiently suppressed, and the temperature of the tip 222B can be maintained at a high temperature for a longer time.

(5) Further, the notch 25 may be provided in the vicinity of the base 221B of the base side wall 23B (see the broken line in FIG. 5).

  With this configuration, in the outer electrode 22 </ b> B, the notch 25 is provided in the vicinity of the connection between the base 221 </ b> B and the screw 14. Therefore, the movement of heat from the base portion 221B to the screw portion 14 is suppressed at the connection portion between the base portion 221B and the screw portion 14. Therefore, the heat of the distal end portion 222B is held while maintaining a large amount of heat in a larger volume (wide range) of the distal end side wall portion 24B and the base side wall portion 23B, so that the temperature of the distal end portion 222B hardly falls. Therefore, the heat reduction of the outer electrode 22B can be suppressed more efficiently, and the ignition failure of the ignition plug 1B can be prevented more reliably.

Third Embodiment
Next, a third embodiment of the present invention will be described.

  FIG. 6 is a cross-sectional view of an electrode portion 20C of a spark plug 1C according to a third embodiment.

  In the outer electrode 22C of the spark plug 1C according to the third embodiment, the base sidewall 23C is a thin portion, and the cross-sectional area of the base sidewall 23C is set smaller than the cross-sectional area of the tip sidewall 24C. Is different from the embodiment described above.

  As shown in FIG. 6, in the electrode portion 20C of the spark plug 1C according to the third embodiment, the base side wall portion 23C of the outer electrode 22C is thinner than the tip side wall portion 24C, and the base side wall portion The plate thickness h3 of 23C is smaller than the plate thickness h1 of the tip side wall portion 24C (outer electrode 22C) (h3 <h1). Therefore, in the outer electrode 22C, the cross-sectional area of the base side wall 23C is smaller than the cross-sectional area of the tip side wall 24C.

  Therefore, in the outer electrode 22C, the amount of the heat generated at the tip 222C passes through the base sidewall 23C is reduced (see the arrow in FIG. 6). As a result, the movement of the high temperature heat of the tip portion 222C of the outer electrode 22C to the base side wall portion 23C is suppressed, and the temperature of the tip portion 222C is maintained at a high temperature for a longer time.

  In the third embodiment, the cross-sectional area of the base side wall 23C is set to be smaller than the cross-sectional area of the front end side wall 24C to suppress the heat transfer of the front end 222C. The structure is not limited to this as long as it is a structure that can maintain the high temperature for a longer time.

  For example, a part of the base side wall portion 23C is hollowed out in the thickness direction (for example, cut out in a circular shape or a square shape), and a cross sectional area of at least a part of the base side wall portion 23C is It may also be smaller. In addition, the thickness of at least a part may be reduced instead of the entire thickness of the base side wall 23C, or the thickness near the base 221C in the base side wall 23C may be reduced to form a thin portion. . In this case, the side surface of the central electrode 21C of the base side wall portion 23C may be thinned, and the thickness of the side surface opposite to the central electrode 21C may be left.

  Even with this configuration, in the ignition plug 1C, the temperature of the tip 222C is suppressed by suppressing the movement of the heat of the tip 222C to the base sidewall 23C by hollowing out or thinning a part of the base sidewall 23C. Is kept hot for a longer time.

  The heat transfer suppressing portion of the present invention has a function of suppressing the movement of heat generated at the tip portion 222C to the base portion 221C by making the cross-sectional area of the base side wall portion 23C described above smaller than the cross-sectional area of the tip side wall portion 24C. It corresponds to

As described above, in the third embodiment,
(6) The heat transfer suppressing portion is configured to be a thin portion (thin portion) of the base side wall portion 23C provided between the tip portion 222C side of the outer electrode 22C and the base portion 221C side.

  With such a configuration, the movement of heat toward the base portion 221C on the tip end portion 222C side is suppressed by the thin-walled portion of the base side wall portion 23C, so that the temperature of the tip end portion 222C is prevented from lowering and ignition failure of the ignition plug 1C It can be prevented.

(7) Further, in the outer electrode 22C, the thin-walled portion is provided on the outer surface opposite to the central electrode 21C.

  According to this configuration, the movement of heat from the inner side surface 222a of the higher temperature tip portion 222C to the base portion 221C side is suppressed, and the heat from the outer side surface 222b of the lower temperature tip portion 222C to the base portion 221C side. I am trying to move. Therefore, a decrease in temperature on the tip end portion 222C side can be prevented, and a high temperature can be maintained for a longer time.

Fourth Embodiment
Next, a fourth embodiment of the present invention will be described.

  FIG. 7 is a cross-sectional view of an electrode portion 20D of a spark plug 1D according to a fourth embodiment.

  In the outer electrode 22D of the spark plug 1D according to the fourth embodiment, at least a part of the base sidewall 23D is formed of a material having a large thermal resistance (a low thermal conductivity), as described above. It differs from the form of

  As shown in FIG. 7, in the outer electrode 22D of the spark plug 1D according to the fourth embodiment, the thermal resistor 30 with high thermal resistance (low thermal conductivity) between the tip 222D and the base 221D. Is provided.

  In the embodiment, the heat resistor 30 is provided on the base side wall 23D.

  The heat resistor 30 is made of a material having a high thermal resistance (a material having a low thermal conductivity). For example, the heat resistor 30 can be made of ceramic, glass, resin, silicone or the like. The heat resistor 30 is integrally formed on the base sidewall 23D, or the heat resistor 30 is provided as a separate member engaged with the base sidewall 23D.

  Therefore, in the outer electrode 22D, the thermal resistor 30 having a large thermal resistance (small thermal conductivity) is provided at least in a part between the tip portion 222D and the base portion 221D. The heat resistor 30 can suppress the movement of the heat of the tip end portion 222D to the base portion 221D (see the arrow in FIG. 7), and can prevent the rapid decrease in the temperature of the tip end portion 222D.

  The function of suppressing the movement of the heat of the tip end portion 222D to the base portion 221D by the heat resistor 30 described above corresponds to the heat transfer suppressing portion of the present invention.

As described above, in the fourth embodiment,
(8) The heat transfer suppressing portion is configured to be the heat resistor 30 provided between the tip portion 222D side and the base portion 221D side.

  With this configuration, in the outer electrode 22D, the heat resistor 30 can suppress the movement of heat on the tip portion 222D side to the base portion 221D side, and can prevent a decrease in temperature of the tip portion 222D. Therefore, in the outer electrode 22D, the temperature of the tip portion 222D can be maintained at high temperature for a long time, and ignition failure of the spark plug 1D due to the outer electrode 22D becoming low temperature can be suppressed.

(9) Further, the heat resistor 30 may be provided in the vicinity of the base portion 221D.

  According to this structure, in the outer electrode 22D, the heat resistor 30 for suppressing the transfer of heat is provided in the vicinity between the base portion 221D and the screw portion 14. Therefore, in the outer electrode 22D, the movement of heat from the base 221D to the screw portion 14 is suppressed at this portion. Therefore, the heat of the tip portion 222D is held with a large amount of heat in a larger volume (wide range) of the tip sidewall 24D and the base sidewall 23D, so that the temperature of the tip 222D does not easily decrease. Therefore, the heat reduction of the outer electrode 22D can be suppressed more efficiently, and the ignition failure of the spark plug 1D can be more reliably prevented.

(10) Further, the heat resistor 30 is configured to be any one or a combination of ceramic, glass, resin, or silicone.

  In this configuration, the ceramic, glass, resin, or silicone is a material having high thermal resistance (low thermal conductivity), so the thermal resistor 30 formed of these materials is a tip of the outer electrode 22D. By providing between the portion 222D and the base portion 221D, the movement of the heat of the tip portion 222D to the base portion 221D can be efficiently suppressed. Therefore, the temperature of the outer electrode 22D is maintained at a high temperature for a long time, and the ignition failure of the spark plug 1D due to the decrease in the temperature of the outer electrode 22D can be prevented.

  As mentioned above, although an example of an embodiment of the present invention was explained, all the embodiments mentioned above may be combined and any two or more embodiments may be combined arbitrarily.

  Further, the present invention is not limited to the one provided with all the configurations of the above-described embodiment, and a part of the configuration of the above-described embodiment is replaced with the configuration of the other embodiments. Alternatively, the configuration of the above-described embodiment may be replaced with the configuration of another embodiment.

  Further, some configurations of the embodiment described above may be added to, deleted from, or replaced with configurations of other embodiments.

  1: Ignition plug, 10: terminal, 12: insulator (corrugation), 13: housing, 14: screw portion, 20 electrode portion, 21: center electrode, 22: outer electrode, 221: base, 222: tip portion, 222a : Inner surface, 222b: Outer surface, 23: Base side wall portion, 24: Tip side wall portion, 25: Notched portion, 26: Thin portion, 27: Redundant portion, 30: Thermal resistor, K1: Heat generation (high temperature) region

Claims (10)

An electrode structure of a spark plug having a center electrode and an outer electrode, comprising:
The outer electrode has a base connected to the main body of the spark plug, and a tip end facing the center electrode with a predetermined gap therebetween.
The electrode structure of the ignition plug which has a heat transfer suppression part which suppresses movement of the heat by the side of the tip to the base side.   The electrode structure of a spark plug according to claim 1, wherein the heat transfer suppressing portion is a redundant wall in which a length of the outer electrode connecting the tip end portion and the base portion is made redundant.   The electrode structure of the spark plug according to claim 1, wherein the heat transfer suppressing portion is a notch portion provided between the tip end side and the base side.   The electrode structure of a spark plug according to claim 3, wherein the notch portion is formed in the outer electrode from the surface facing the center electrode to the opposite surface.   The electrode structure of the spark plug according to claim 4, wherein the notch is provided in the vicinity of the base.   The electrode structure of a spark plug according to claim 1, wherein the heat transfer suppressing portion is a thin-walled portion provided between the tip end side and the base side.   The electrode structure of a spark plug according to claim 6, wherein the thin portion is provided on the side of the outer electrode opposite to the center electrode.   The electrode structure of a spark plug according to claim 1, wherein the heat transfer suppressing portion is a heat resistor provided between the tip end side and the base side.   The electrode structure of a spark plug according to claim 8, wherein the heat resistor is provided in the vicinity of the base.   10. The spark plug electrode structure according to claim 9, wherein the heat resistor is any one or a combination of ceramic, glass, resin, or silicone.

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