JP2017112000A - Ignition plug - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ignition plug capable of shortening an initial combustion period.SOLUTION: The ignition plug includes: a cylindrical housing 2 mounted on a cylinder head 11 of an internal combustion engine; a cylindrical insulator 3 retained in the housing 2; a central electrode 4 retained in the insulator 3 and having a front end 42 protruding into a combustion chamber of the internal combustion engine; and a ground electrode 5 formed in the combustion chamber, spacing from the central electrode 4 and extended from one end 51 fixed on the housing 2 toward a front end 42 of the central electrode 4. A first surface 5A facing the front end 42 of the central electrode 4, of the ground electrode 5, is a heat insulation surface formed with a heat insulation film shutting down heat transfer.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a spark plug that ignites a compressed air-fuel mixture in an internal combustion engine.

  An internal combustion engine (engine) is known to have different combustion for each cycle (the illustrated work varies). When the rate of change in combustion (that is, COV of IMEP: Coefficient of Variation of Indicated Mean Effective Pressure) increases, there is a problem that the output of the internal combustion engine becomes unstable. In the case of an internal combustion engine, drivability may be reduced.

  Conventionally, various methods for reducing the combustion fluctuation rate have been proposed for the above-described problems. As one type, there is a method in which the initial combustion period correlated with the combustion fluctuation rate is shortened. The initial combustion period is the time from when the spark plug ignites the air-fuel mixture until 10% of the amount of fuel introduced into the combustion chamber burns. Generally, it is known that the shorter the initial combustion period, the lower the combustion fluctuation rate. That is, by shortening the initial combustion period, the combustion fluctuation rate can be reduced, and the output of the internal combustion engine can be stabilized.

  As a specific method for shortening the initial combustion period, it is possible to arrange a heat insulating material in the vicinity of the spark plug mounting hole in the surface constituting the combustion chamber in the cylinder head of the internal combustion engine (see Patent Document 1). . According to this method, since the air-fuel mixture around the spark plug that contributes to the generation of the initial flame receives heat from the heat insulating material and becomes high temperature, the ignitability can be improved and the initial combustion period can be shortened.

JP 2011-99379 A

  However, during the initial combustion period, the thermal energy of the flame generated by the discharge of the spark plug and the combustion of the fuel is lost not only by the wall surface of the cylinder head but also by the spark plug itself. In other words, the spark plug absorbs the thermal energy of the flame, thereby preventing the growth of the flame and prolonging the initial combustion period.

  This case has been devised in view of the above-described problems, and one of the purposes of the spark plug is to shorten the initial combustion period. The present invention is not limited to this purpose, and is a function and effect derived from each configuration shown in the embodiment for carrying out the invention described later, and has another function and effect that cannot be obtained by conventional techniques. is there.

  (1) A spark plug disclosed herein includes a cylindrical housing attached to a cylinder head of an internal combustion engine, a cylindrical insulator held in the housing, and held in the insulator, and the internal combustion engine A center electrode having a tip projecting from the combustion chamber, and spaced from the center electrode in the combustion chamber and extending from one end fixed to the housing toward the tip of the center electrode. A ground electrode provided. Of the ground electrodes, the first surface of the center electrode facing the tip is a heat insulating surface on which a heat insulating film that blocks heat in and out is formed.

(2) It is preferable that the ground electrode is provided with the first surface facing the opposite side of the intake opening that sucks the air-fuel mixture into the combustion chamber.
(3) In this case, it is preferable that a second surface of the ground electrode that faces away from the first surface is an exposed surface on which the heat insulating film is not formed.

(4) Alternatively, it is preferable that the second surface of the ground electrode that faces away from the first surface is a heat insulating surface on which the heat insulating film is formed.
(5) It is preferable that the said housing has an inner wall surface provided through the clearance gap open | released by the said combustion chamber between the outer peripheral surfaces of the said insulator. In this case, it is preferable that the inner wall surface of the housing and the outer peripheral surface of the insulator are heat insulating surfaces on which the heat insulating film is formed.

(6) It is preferable that the housing has an end portion that is coupled to the one end portion of the ground electrode and protrudes into the combustion chamber. In this case, the outer wall surface of the end portion of the housing is preferably an exposed surface on which the heat insulating film is not formed.
(7) It is preferable that the material of the heat insulating film has a smaller heat capacity and a lower thermal conductivity than the material of the heat-insulated surface.

  Among the ground electrodes, the first surface facing the tip of the center electrode is a heat insulating surface on which a heat insulating film is formed, so heat transfer from the first surface into the ground electrode can be suppressed. The heat energy taken away can be reduced. Therefore, the initial combustion period can be shortened.

It is sectional drawing which shows typically the structure of the engine to which the ignition plug which concerns on embodiment was applied. It is the schematic diagram which looked at the cylinder head of the engine from the combustion chamber lower side. (A) is a side view of the ignition plug which concerns on 1st embodiment, (b) is the fragmentary sectional view which cut | disconnected the principal part to the axial direction. (A) is a side view of the ignition plug which concerns on 2nd embodiment, (b) is the fragmentary sectional view which cut | disconnected the principal part in the axial direction.

A spark plug as an embodiment will be described with reference to the drawings. Note that the embodiment described below is merely an example, and there is no intention to exclude various modifications and technical applications that are not explicitly described in the following embodiment. Each configuration of the present embodiment can be implemented with various modifications without departing from the spirit of the present embodiment, and can be selected or combined as necessary.
In the following description, the internal combustion engine and the spark plug applied thereto are used as a reference when the internal combustion engine is arranged so that the central axis of the cylinder is vertical (the intake port and the exhaust port are positioned above). Determine the vertical direction.

[1. First embodiment]
[1-1. Constitution]
The spark plug 1 according to the present embodiment is applied to the engine 10 shown in FIG. The engine 10 is an internal combustion engine that generates power by burning fuel in a cylinder (combustion chamber 17). The fuel injection method of the engine 10 is intake port injection. That is, the intake port 18 of the engine 10 is provided with an injector 16 that injects mist-like fuel.

  A space surrounded by the cylinder head 11 of the engine 10 and the inner peripheral surface of the cylinder block 12 and the upper surface of the piston 13 functions as a combustion chamber 17 for burning fuel. The surface facing the combustion chamber 17 in the cylinder head 11 is formed into a pent roof type (gable roof type) in which an inclined surface to which the intake port 18 is connected and an inclined surface to which the exhaust port 19 is connected are attached to a triangular roof shape. Is done. An intake opening 11a connected to the intake port 18 and an exhaust opening 11b connected to the exhaust port 19 are formed on the surface.

  The intake opening 11a and the exhaust opening 11b are arranged to face each other across the central axis O of the cylinder. That is, the side where the intake opening 11a is located (hereinafter also referred to as “intake side”) and the side where the exhaust opening 11b is located (hereinafter also referred to as “exhaust side”) are opposite to each other with respect to the central axis O. The intake opening 11 a sucks the air-fuel mixture from the intake port 18 into the combustion chamber 17. On the other hand, the exhaust opening 11 b discharges combustion gas from the combustion chamber 17 to the exhaust port 19. An intake valve 14 is provided in the intake opening 11a. An exhaust valve 15 is provided in the exhaust opening 11b. Two each of these intake openings 11a, exhaust openings 11b, intake valves 14, and exhaust valves 15 are provided for one cylinder.

  As shown in FIG. 2, the intake port 18 has a siamese shape in which one passage is branched toward the two intake openings 11a. Similarly, the exhaust port 19 has a siamese shape in which two passages connected to each of the two exhaust openings 11b are joined together. In FIG. 2, the intake valve 14 and the exhaust valve 15 are omitted.

  The cylinder head 11 is provided with an attachment hole 11h for attaching the spark plug 1. The mounting hole 11h is formed coaxially with the central axis O of the cylinder, and is provided separately from (without interfering with) the two intake openings 11a and the two exhaust openings 11b. A female screw is machined on the wall surface surrounding the mounting hole 11 h in the cylinder head 11.

  The spark plug 1 is a spark plug that ignites a compressed air-fuel mixture by causing a spark discharge. The spark plug 1 is fitted into the mounting hole 11h of the cylinder head 11 from above, and is mounted so that its axis (the direction in which a center electrode 4 described later) extends coincides with the center axis O of the cylinder. As shown in FIGS. 3A and 3B, the spark plug 1 includes a housing 2, an insulator 3, a center electrode 4, and a side electrode 5.

  The housing 2 is a metal shell fixed to the cylinder head 11 and is formed in a cylindrical shape from a metal material. The housing 2 includes a caulking portion 21, an engagement portion 22, a seat portion 23, a fixing portion 24, and a taper portion 25 that are provided in order from the top to the bottom. The crimping portion 21 is a part that holds the insulator 3 by being crimped to the insulator 3. The engaging portion 22 is a portion with which a tool for attaching the spark plug 1 to the cylinder head 11 is engaged, and is formed in a shape corresponding to this tool. The seat portion 23 is a portion that is placed with respect to the cylinder head 11, is formed in a shape projecting in a radial direction from other portions, and is provided in contact with the cylinder head 11. A gasket (not shown) is provided between the seat portion 23 and the cylinder head 11.

  The fixing portion 24 is a portion fixed in the mounting hole 11h of the cylinder head 11, and has an outer wall surface 24a in which a male screw is processed and an inner wall surface 24b formed in a smooth cylindrical surface shape. The taper portion 25 (end portion) is a portion projecting into the combustion chamber 17, and a tapered outer wall surface 25a having a diameter (outer diameter of the taper portion 25) that is reduced downward and a smooth cylinder. And an inner wall surface 25b formed in a planar shape. The maximum outer diameter of the tapered portion 25 is formed smaller than the valley diameter (minimum diameter) of the outer wall surface 24 a of the fixed portion 24. Hereinafter, the inner wall surface 24b of the fixed portion 24 and the inner wall surface 25b of the tapered portion 25 are collectively referred to as “inner wall surfaces 24b and 25b of the housing 2”.

  The insulator 3 electrically insulates the housing 2 and the center electrode 4 and is formed in a cylindrical shape from an insulating and heat resistant material (for example, ceramics such as alumina). The insulator 3 is held in the housing 2 and is interposed between the housing 2 and the center electrode 4. The insulator 3 has a head portion 31, a trunk portion 32, and a leg portion 33 provided in order from the top to the bottom. The head portion 31 is a portion for insulating between the housing 2 and the upper end portion 41 of the center electrode 4, and is provided so as to protrude upward from the housing 2. The body part 32 is a part that is accommodated in the caulking part 21, the engaging part 22, and the seat part 23 of the housing 2.

  The leg portion 33 is a portion provided in non-contact with the housing 2 and is formed in a tapered shape with an outer diameter reduced toward the lower side. A gap (gas pocket) S opened to the combustion chamber 17 is provided between the outer peripheral surface 33 a of the leg portion 33 and the inner wall surfaces 24 b and 25 b of the housing 2. The leg part 33 is accommodated in the fixed part 24 and the taper part 25 of the housing 2 except for the lower end part thereof. That is, the lower end portion of the leg portion 33 is provided so as to protrude below the housing 2 (that is, in the combustion chamber 17).

  The center electrode 4 and the side electrode 5 generate a spark discharge when a voltage is applied between them, and are disposed in non-contact with each other. Both the center electrode 4 and the side electrode 5 are formed in a rod shape from a heat-resistant metal material (for example, nickel alloy). The center electrode 4 is held in the insulator 3. The side electrode 5 is coupled to the tapered portion 25 of the housing 2 and is provided in the combustion chamber 17.

  The center electrode 4 has an upper end portion 41 that functions as an electrical connection terminal of the spark plug 1 and a lower end portion 42 (tip portion) that generates a spark discharge between the side electrode 5. An upper end portion 41 of the center electrode 4 is provided so as to protrude upward from the insulator 3 and is connected to a power source (not shown). The lower end portion 42 of the center electrode 4 is formed in a needle shape, and is provided so as to protrude below the insulator 3 (that is, in the combustion chamber 17).

  The side electrode 5 (ground electrode) extends from one end 51 coupled to the tapered portion 25 of the housing 2 toward the lower end 42 of the center electrode 4. The other end 52 of the side electrode 5 intersects the central axis O below the lower end 42 of the center electrode 4 and is provided at a position slightly shifted from the central axis O. A needle-shaped electrode piece 53 protrudes toward the lower end portion 42 of the center electrode 4 at a position intersecting the center axis O in the side pole 5. A gap G for discharge is provided between the electrode piece 53 and the lower end portion 42 of the center electrode 4.

  The side pole 5 is formed in a shape bent in an L shape in a side view. That is, the side pole 5 has a part extending downward from the one end 51 and a part extending substantially perpendicular to the part. The lateral cross section of the side electrode 5 (the cross section orthogonal to the direction from the one end 51 to the other end 52) is formed in a substantially uniform rectangular shape. Hereinafter, the surface of the side electrode 5 facing the lower end portion 42 of the center electrode 4 is referred to as an inner surface 5A (first surface), and the surface opposite to the inner surface 5A is referred to as an outer surface 5B (second surface). In addition, a surface orthogonal to the inner surface 5A and the outer surface 5B in the other end portion 52 of the side pole 5 is referred to as a tip surface 5C, and the remaining two surfaces are referred to as a side surface 5D.

  As shown by patterns in FIGS. 3A and 3B, a heat insulating film that blocks heat from entering and exiting is formed on a part of the surface of the spark plug 1. In the present embodiment, the inner wall surfaces 24b and 25b of the housing 2, the outer wall surface 25a of the tapered portion 25 of the housing 2, the outer peripheral surface 33a of the leg portion 33 of the insulator 3, and the inner surface 5A of the side pole 5, A heat insulating film is formed. That is, in the side electrode 5 of this embodiment, only the inner surface 5A is a heat insulating surface on which a heat insulating film is formed, and the outer surface 5B, the tip surface 5C, and the side surface 5D are exposed surfaces on which a heat insulating film is not formed.

  The heat insulating film is formed of a material having a smaller heat capacity and lower thermal conductivity than the material of the surface to be insulated. That is, the heat insulating film has a property (so-called swing characteristic) in which the temperature of the heat insulating film easily follows the ambient temperature while blocking heat from entering and exiting the surface to be insulated. For example, when the material of the surface to be insulated is iron, aluminum can be applied as the material of the heat insulating film. Further, when the material of the surface to be insulated is aluminum, tin or bismuth can be applied as the material of the heat insulating film. Furthermore, when the material of the heat-insulated surface is aluminum, an anodized film described in JP-A-2015-31226 may be applied as the heat insulating film. However, the film (heat insulating film) formed on the outer peripheral surface 33a of the leg portion 33 of the insulator 3 needs to be made of a highly insulating material.

  As shown in FIGS. 1 and 2, the spark plug 1 is attached so that the inner surface 5A faces the exhaust side. That is, the side pole 5 is provided with the inner surface 5A facing the exhaust opening 11b (the opposite side of the intake opening 11a). More specifically, as shown in FIG. 2, a straight line L1 obtained by extending the center line of the side pole 5 in the bottom view of the cylinder head 11 passes through the center axis O from each center point P of the two intake openings 11a. The direction of the spark plug 1 is set so as to enter the region A on the exhaust side sandwiched between the straight lines L2.

[1-2. Action, effect]
When a spark discharge occurs between the center electrode 4 and the side electrode 5 of the spark plug 1 (that is, the discharge gap G), the air-fuel mixture in the combustion chamber 17 is ignited and a flame is generated. This flame spreads from the gap G. At this time, the inner surface 5A of the side electrode 5 adjacent to the gap G in the spark plug 1 is warmed by the flame. In other words, the thermal energy of the flame is taken away by the inner surface 5A of the side pole 5.

  Further, high-temperature gas flows from the combustion chamber 17 into the gap S opened to the combustion chamber 17. Therefore, the inner wall surfaces 24b, 25b of the housing 2 facing the gap S in the spark plug 1 and the outer peripheral surface 33a of the insulator 3 are warmed by this high-temperature gas. In other words, the heat energy in the combustion chamber 17 is taken away by the inner wall surfaces 24 b and 25 b of the housing 2 and the outer peripheral surface 33 a of the insulator 3.

  (1) According to the spark plug 1 described above, a heat insulating film is formed on the inner surface 5A of the side electrode 5 facing the lower end portion 42 of the center electrode 4 (the inner surface 5A is a heat insulating surface). Heat transfer into the side electrode 5 can be suppressed. Thereby, when the flame produced between the center electrode 4 and the side electrode 5 spreads, the thermal energy of the flame taken away by the side electrode 5 can be reduced. Therefore, a decrease in the flame growth rate can be suppressed, and the initial combustion period can be shortened. Therefore, the combustion fluctuation rate can be reduced, and the output of the engine 10 can be stabilized.

  In addition, if there is a portion where the flame spreads slowly in the combustion chamber (if the flame spread is biased), the arrival of the flame at the end of the combustion chamber is delayed, causing auto-ignition with the end gas. On the other hand, according to the spark plug 1, the thermal energy lost to the side electrode 5 can be reduced as described above, so that the side where the side electrode 5 extends in the spark plug 1 and the opposite side (this embodiment) In the embodiment, it is possible to make it difficult for the spread of the flame to be made uneven on the intake side and the exhaust side), and to suppress the occurrence of self-ignition by the end gas.

  (2) In the spark plug 1 described above, since the side electrode 5 is provided with the inner surface 5A facing the opposite side of the intake opening 11a, the fuel droplets in the air-fuel mixture sucked from the intake opening 11a are insulated from the inner surface 5A. It can suppress adhering to. Therefore, the heat insulation performance of the heat insulation film formed on the inner surface 5A of the side electrode 5 can be appropriately maintained, and the initial combustion period can be more reliably shortened.

  (3) Since the above-described spark plug 1 has no heat insulating film formed on the outer surface 5B of the side electrode 5 (the outer surface 5B is an exposed surface), the outer surface is compared with the case where the heat insulating film is formed on the outer surface 5B. The temperature of 5B can be easily raised, and the vaporization of the fuel droplets adhering to the outer surface 5B can be promoted. As a result, combustion of the engine 10 can be stabilized, and the spark plug 1 can be prevented from turning and deposit formation on the spark plug 1, and the exhaust gas performance of the engine 10 can be enhanced.

  Further, in the spark plug 1 described above, since the side electrode 5 is provided with the outer surface 5B facing the intake opening 11a, the outer surface 5B can be easily contacted with the intake air, and the outer surface 5B is cooled by using the intake air. Can do. That is, by not forming the heat insulating film on the outer surface 5B, the heat of the side electrode 5 can be released appropriately, and the occurrence of knocking can be suppressed.

  (4) Since the heat insulating films are formed on the inner wall surfaces 24b, 25b of the housing 2 and the outer peripheral surface 33a of the insulator 3 (the inner wall surfaces 24b, 25b and the outer peripheral surface 33a are heat insulating surfaces), the inner wall surfaces 24b, Heat transfer from 25b into the housing 2 and heat transfer from the outer peripheral surface 33a into the insulator 3 can be suppressed. Thereby, the thermal energy in the combustion chamber 17 taken away by the housing 2 and the insulator 3 can be reduced, and the temperature rise in the combustion chamber 17 can be promoted. Therefore, a decrease in the flame growth rate can be further suppressed, and the initial combustion period can be further shortened.

  (5) Since the material of the heat insulating film described above has a smaller heat capacity and lower thermal conductivity than the material of the heat-insulated surface (for example, the inner surface 5A of the side electrode 5), the temperature of the heat-insulated surface is set to the ambient temperature. The surface to be insulated can be appropriately insulated. Therefore, the occurrence of knocking can be suppressed and the initial combustion period can be shortened.

[2. Second embodiment]
As shown in FIGS. 4A and 4B, the spark plug 1 ′ according to the present embodiment is different from the spark plug 1 according to the first embodiment described above in the part where the heat insulating film is formed. In the following description, elements that are the same as or correspond to those described in the first embodiment are assigned the same reference numerals, and redundant descriptions are omitted.

  4 (a) and 4 (b), the spark plug 1 'of the present embodiment includes the entire surface of the side pole 5, the inner wall surfaces 24b and 25b of the housing 2, and the outer peripheral surface of the leg portion 33 of the insulator 3. Each of 33a is provided as a heat insulating surface on which a heat insulating film is formed. That is, in the spark plug 1 ′ according to the present embodiment, the heat insulating film is not formed on the outer wall surface 25 a of the taper portion 25 (the outer wall surface of the taper portion 25 is different from the spark plug 1 according to the first embodiment described above. 25a is an exposed surface) and a heat insulating film is formed on the outer surface 5B, tip surface 5C, and side surface 5D of the side pole 5 (the outer surface 5B, tip surface 5C, and side surface 5D are all heat insulating surfaces). Is different.

  According to the spark plug 1 'according to the present embodiment, a heat insulating film is formed on the outer surface 5B in addition to the inner surface 5A of the side electrode 5 (the outer surface 5B is a heat insulating surface). It is possible to suppress not only heat transfer to but also heat transfer from the outer surface 5B into the side electrode 5. Thereby, when the flame produced between the center electrode 4 and the side electrode 5 spreads, the thermal energy of the flame taken away by the side electrode 5 can be reduced more. Therefore, a decrease in the flame growth rate can be further suppressed, and the initial combustion period can be further shortened. In addition, according to the spark plug 1 ′, a heat insulating film is also formed on the front end surface 5C and the side surface 5D of the side pole 5 (the front end surface 5C and the side surface 5D are heat insulating surfaces), so the initial combustion period is further shortened. be able to.

  Further, according to the spark plug 1 ′, the heat insulating film is formed on the entire surface of the side electrode 5, and therefore, the work of forming the heat insulating film becomes easy. That is, when the heat insulating film is formed, it is not necessary to distinguish between the heat insulating surface on which the heat insulating film is formed and the exposed surface on which the heat insulating film is not formed in the side electrode 5, so that the spark plug 1 ′ can be easily manufactured.

  Further, according to the spark plug 1 ′, no heat insulating film is formed on the outer wall surface 25 a of the taper portion 25 of the housing 2 (the outer wall surface 25 a of the taper portion 25 is an exposed surface). Therefore, it is possible to easily dissipate heat from the one end 51 of the side electrode 5. Thereby, even if the heat insulating film is formed on the entire surface of the side electrode 5, the heat of the side electrode 5 can be appropriately released from the tapered portion 25, and the occurrence of knocking can be suppressed.

[3. Modified example]
Regardless of the embodiment described above, various modifications can be made without departing from the spirit of the invention. Each structure of this embodiment can be selected as needed, or may be combined appropriately.

  In the spark plugs 1, 1 ′ shown in the above-described embodiment, the portion (heat insulating surface) where the heat insulating film is formed is not limited to the above. The heat insulating film may be formed on at least the inner surface 5A of the side electrode 5 of the spark plug 1, 1 '. That is, in the above-described spark plugs 1 and 1 ′, the surfaces other than the inner surface 5 </ b> A of the side electrode 5 (for example, the inner wall surfaces 24 b and 25 b of the housing 2 and the outer peripheral surface 33 a of the leg portion 33 of the insulator 3) are exposed surfaces. Also good. In the above-described spark plugs 1, 1 ′, the outer surface of the side electrode 5, the inner wall surfaces 24 b and 25 b of the housing 2, the outer wall surface 25 a of the tapered portion 25 of the housing 2, and the leg portion 33 of the insulator 3. Each of 33a may be a heat insulating surface.

  The material of the heat insulating film may be at least one having a low thermal conductivity with respect to the material of the surface to be insulated. That is, the above-described heat insulating film may be formed of a material having a larger heat capacity than the material of the heat-insulated surface. The method for forming the heat insulating film on the heat insulating surface is not particularly limited. The heat insulating film may be formed, for example, by spraying or coating a liquid heat insulating material on the surface to be heat-insulated, or formed by immersing the surface to be heat-insulated in a liquid heat insulating material placed in a container. Good.

  The shaft center of the spark plugs 1 and 1 'and the mounting hole 11h for mounting the spark plugs 1 and 1' may not be provided coaxially with the center axis O of the cylinder. Further, the outer wall surface 25a of the tapered portion 25 of the spark plugs 1 and 1 'may not be formed in a tapered shape. Furthermore, the leg portion 33 of the insulator 3 of the spark plugs 1, 1 ′ may not be provided with a lower end projecting downward from the housing 2 (that is, the leg portion 33 of the spark plugs 1, 1 ′ is not provided). It may be included in the fixing part 24 of the housing 2). Further, the other end portion 52 of the side electrode 5 may not intersect the central axis O below the lower end portion 42 of the center electrode 4.

  The internal combustion engine to which the above-described spark plugs 1 and 1 ′ are applied is not limited to the engine 10 described above. For example, the above-described spark plugs 1 and 1 'may be applied to a direct injection engine that directly injects fuel into a cylinder. Further, the number of intake openings 11a, exhaust openings 11b, intake valves 14, and exhaust valves 15 shown in the above embodiment is not limited to two. For example, one intake opening 11a and one intake valve 14 may be provided for each cylinder. Further, the intake port 18 and the exhaust port 19 may not have a siamese shape.

1, 1 'Spark plug 2 Housing 3 Insulator 4 Center electrode 5 Side electrode (ground electrode)
5A Inner surface (first surface)
5B outer surface (second surface)
10 Engine (Internal combustion engine)
11 Cylinder head 11a Intake opening 17 Combustion chamber 24b Inner wall surface 25 Tapered part (end part)
25a outer wall surface 25b inner wall surface 33a outer peripheral surface 42 lower end (tip)
51 One end S gap

Claims (7)

A cylindrical housing attached to the cylinder head of the internal combustion engine;
A cylindrical insulator held in the housing;
A central electrode held in the insulator and having a tip projecting from a combustion chamber of the internal combustion engine;
A grounding electrode provided apart from the center electrode in the combustion chamber and extending from one end fixed to the housing toward the tip of the center electrode;
The spark plug according to claim 1, wherein a first surface of the ground electrode facing the tip portion of the center electrode is a heat insulating surface on which a heat insulating film that blocks heat in and out is formed. 2. The spark plug according to claim 1, wherein the ground electrode is provided with the first surface facing a side opposite to an intake opening for sucking an air-fuel mixture into the combustion chamber. The spark plug according to claim 2, wherein a second surface of the ground electrode facing away from the first surface is an exposed surface on which the heat insulating film is not formed. The spark plug according to claim 1 or 2, wherein a second surface of the ground electrode facing away from the first surface is a heat insulating surface on which the heat insulating film is formed. The housing has an inner wall surface provided between the outer peripheral surface of the insulator and a gap opened to the combustion chamber,
The spark plug according to any one of claims 1 to 4, wherein the inner wall surface of the housing and the outer peripheral surface of the insulator are heat insulating surfaces on which the heat insulating film is formed. The housing has an end coupled to the one end of the ground electrode and projecting into the combustion chamber;
The spark plug according to any one of claims 1 to 5, wherein an outer wall surface of the end portion of the housing is an exposed surface on which the heat insulating film is not formed. The spark plug according to any one of claims 1 to 6, wherein the material of the heat insulating film has a smaller heat capacity and a lower thermal conductivity than a material of the surface to be insulated.

Images