JP2016004748A - Spark plug - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an excellent spark plug achieving reduction of noise and suppression of electrode wear by decreasing electrostatic capacitance, without causing deterioration of withstand voltage, while satisfying requirements for a reduced diameter and achieving both suppression of preignition and suppression of smoldering.SOLUTION: In a spark plug 100, at least a diameter φDof a high heat conduction part 11 is smaller than a diameter φDof a resistive element 14, and a glass leg part 20 includes a glass leg vertical part 203 exposing from a projecting latching part 34 so as to extend vertically with a constant diameter φDbeing maintained.

Description

  The present invention relates to a spark plug used for ignition of an internal combustion engine.

  To ignite the air-fuel mixture introduced into the combustion chamber of the internal combustion engine, a shaft-shaped center electrode, a cylindrical insulator that holds the center electrode in a through hole provided inside, and a part of the outer periphery of the insulator are covered. A cylindrical housing that holds the insulator, and a ground electrode that extends to the front end of the housing and faces the front end of the center electrode with a predetermined discharge gap between the center electrode and the ground electrode. Spark plugs that generate spark discharge when a high voltage is applied between them are widely used.

  In Patent Document 1, in a spark plug using a high melting point metal tip having an outer diameter of a screw portion of 12 mm or less, the thickness of the tip portion of the insulator is 1.1 mm or more, and the value of the gas volume width E is appropriately set. By enlarging, the occurrence of lateral jump between the center electrode and the metal shell is prevented, the outer diameter at the position corresponding to the end surface of the insulator on the protruding side of the center electrode, and the axial direction of the packing at the base end The outer diameter at the position corresponding to the inner edge of the front end is set within a specific range, and the outer peripheral surface of the electrode extending from the base end of the center electrode to the position corresponding to the end face of the insulator is formed into a tapered surface that tapers. Thus, there has been disclosed a spark plug that prevents the overall diameter of the center electrode from being reduced even if the gas volume width is enlarged, and ensures heat extraction.

JP 2009-187654 A

However, as disclosed in Patent Document 1, when the electrode outer peripheral surface is formed in a tapered shape so that the proximal end side of the center electrode is thicker than the distal end side, a part of the housing protrudes inward, The distance between the projecting locking portion (also referred to as a jitz portion) that locks the enlarged diameter portion and the outer periphery of the center electrode is shortened.
As a result, the capacitance on the tip side of the resistor is increased, and there is a risk of electrode consumption due to capacitive discharge.
In addition, since the thickness of the insulator is relatively thin at the position where the distance between the inner peripheral edge of the protruding latching portion where the electric field tends to concentrate and the outer peripheral surface of the center electrode is the shortest, the withstand voltage is reduced. Easy to invite.
In particular, since the discharge voltage has increased with the increase in the supercharging and the compression ratio of the internal combustion engine, the problem of electrode wear due to capacitive discharge has become apparent.

On the other hand, in an internal combustion engine, it is desired to reduce the diameter of the spark plug. If the entire spark plug has a small diameter while maintaining the structure of the conventional spark plug, the center electrode is thinned, so that the heat absorption is reduced and preignition is likely to occur.
Further, if the length of the insulator leg is increased in order to ensure the heat value with respect to the decrease in heat absorption accompanying the reduction in the diameter of the center electrode, the smolderability may be deteriorated.

  Therefore, in view of such circumstances, the present invention is capable of reducing the capacitance without lowering the withstand voltage while satisfying the demand for reducing the diameter and achieving both suppression of preignition and suppression of smoldering. Thus, an object is to provide a spark plug capable of reducing noise and suppressing electrode consumption.

In the present invention, at least the axially extending central electrode (1) and the central electrode discharge part (10) provided at the distal end of the central electrode are exposed from one end, and the proximal end of the central electrode is exposed from the other end. A cylindrical insulator (2) for holding the center electrode so that the center electrode terminal portion (18) provided on the insulator is exposed, and an insulator leg (20) provided on one end of the insulator from the tip side Is exposed, and a housing (3) that accommodates and holds the insulator such that an insulator head (23) provided on the base end side of the insulator is exposed from the other end, and the central electrode discharge portion from the housing. A spark plug (100) having a ground electrode (31) extending toward the ground electrode, and a ground electrode discharge part (30) facing the center electrode discharge part with a predetermined discharge gap (40) at the tip of the ground electrode. ).
In the present invention, the center electrode includes, in order from the base end side, a middle shaft portion (17), a middle shaft embedded portion (16), and a base end side between the center electrode terminal portion and the center electrode discharge portion. An adhesive layer (15), a resistor (14), a tip side adhesive layer (13), a connecting portion (12), and a high heat conduction portion (11) are provided.

  The middle shaft portion is formed so that a proximal end side is connected to the center electrode terminal portion and extends in a columnar shape inside the insulator head portion. The middle shaft embedded portion is formed by expanding a part of the diameter on the tip side of the middle shaft portion. The resistor is connected to the embedded central shaft and is formed in a cylindrical shape.

  The connecting portion is formed so as to increase in diameter so as to increase in diameter toward the proximal end side at the distal end side. The high heat conduction part is connected to the central electrode discharge part on the tip side and is formed in a cylindrical shape.

The proximal end side adhesive layer is disposed on the proximal end side of the resistor, and makes electrical connection between the center shaft embedded portion and the resistor, and the center shaft embedded portion is placed inside the insulator. It is fixed.
The distal end side adhesive layer is disposed on the distal end side of the resistor, and makes electrical connection between the resistor and the connecting portion, and fixes the connecting portion to the inside of the insulator.

  In the present invention, the insulator is formed between the insulator head and the insulator leg, the insulator middle trunk (21) having a diameter larger than that of the insulator leg, and a part of the insulator middle trunk. A large-diameter portion (22) having a large diameter in a bowl shape, and the housing has a protruding locking portion (34) in which a part of the inner peripheral surface protrudes toward the center, and a proximal end The insulator middle body portion and the insulator large-diameter portion are caulked and fixed by a caulking portion (36) in which the side edge is caulked inward.

In the spark plug of the present invention, at least the diameter (φD ₁ ) of the high thermal conductivity portion at the base end position where the high thermal conductivity portion is connected to the connecting portion is larger than the diameter φD ₃ where the resistor is connected to the adhesive layer. And a lever leg vertical portion (203) exposed from the protruding locking portion so that the lever leg portion extends vertically while maintaining a constant diameter (φD ₂ ). The boundary between the conduction part and the connecting part is a high heat conduction part root part (120), and the vertical distance from the high heat conduction part root part to the root part (210) of the insulator leg part is defined as the insulator leg part insulation distance. When L ₃ (mm), 0.9 ≦ L ₃ ≦ 1.7 is set.

According to the present invention, by thinning the outer diameter of the high heat conduction portion, the thickness of the insulator leg portion is relatively increased, and the capacitance on the tip side of the resistor can be reduced.
In addition, by making the outer diameter of the insulator leg portion constant by a predetermined length, the capacitance can be made smaller than when the insulator leg portion is immediately reduced in diameter from the base portion.
As a result, it is possible to simultaneously realize reduction of noise and suppression of electrode consumption due to capacitive discharge.
In addition, the withstand voltage increases as the thickness of the insulator leg increases. In addition, since the vertical portion of the insulator leg portion is exposed from the protruding locking portion, electric field concentration around the protruding locking portion is suppressed, and the withstand voltage is further increased. .
Further, the axial insulation distance L ₃ is set in the range of the present invention, the heat radiation property is improved from the highly thermal conductive portion to the axial distance becomes shorter axial part to the resistor.
As described above, the pre-ignition can be suppressed by compensating for the decrease in heat absorption due to the diameter reduction of the high heat conducting portion.
And since the length of the said insulator leg part does not need to be changed, it does not worsen smoldering property.

Partial sectional view showing the overall outline of the spark plug of the present invention The principal part expanded sectional view which shows the characteristic of the ignition plug of this invention Characteristic diagram showing the effect of center electrode outer diameter / insulator leg outer diameter ratio on withstand voltage and capacitance Fig. 3 Relative characteristics Characteristic chart showing the effect of insulator leg vertical part length on withstand voltage Characteristic diagram showing the effect of axial insulation length on withstand voltage Characteristic diagram showing the effect of axial insulation length on pre-ignition suppression

An outline of the spark plug 100 in the embodiment of the present invention will be described with reference to FIGS. 1 and 2.
In the following description, a side connected to an external power supply (not shown) is referred to as a base end side, and a side facing the combustion chamber of the internal combustion engine is referred to as a front end side.
The spark plug 100 includes at least a center electrode 1, an insulator 2, and a housing 3.

The center electrode 1 is formed so as to extend in an axial shape, and a center electrode discharge portion 10 is provided at one end, and a center electrode terminal portion 18 is provided at the other end.
The insulator 2 is formed in a cylindrical shape, and holds the center electrode 1 so that the center electrode discharge portion 10 is exposed from one end and the center electrode terminal portion 18 is exposed from the other end.
An insulator leg portion 20 is provided on the distal end side of the insulator 2, and an insulator head portion 23 is provided on the proximal end side.

The housing 3 is formed in a cylindrical shape, and accommodates and holds the insulator 2 such that the insulator leg portion 20 is exposed from one end and the insulator head portion 23 is exposed from the other end.
The housing 3 is provided with a ground electrode 31 extending toward the center electrode discharge unit 10 and a ground electrode discharge unit 30 facing the center electrode discharge unit 10 with a predetermined discharge gap 40 at the tip of the ground electrode 31. Yes.

The spark plug 100 is provided in an internal combustion engine (not shown). When a high voltage is applied between the center electrode 1 and the ground electrode 31 from an external power source, the spark plug 100 is interposed between the center electrode discharge unit 10 and the ground electrode discharge unit 30. Spark discharge is generated, and the air-fuel mixture introduced into the combustion chamber of the internal combustion engine is ignited.
The spark plug 100 can be appropriately employed for any spark plug having a nominal diameter of the mounting screw portion 33 of M8, M9, M10, M11, M12, M13, and M14.

The center electrode 1 includes a center shaft portion 17, a center shaft embedded portion 16, an adhesive layer 15, a resistor 14, and an adhesive layer between the center electrode terminal portion 18 and the center electrode discharge portion 10 in this order from the base end side. 13, a connecting part 12, and a high heat conducting part 11.
The center electrode 1 is housed and held in a cylindrical insulator 2, the center electrode discharge portion 10 is exposed from the distal end side of the insulator 2 into the combustion chamber of an internal combustion engine (not shown), and is centered from the proximal end side of the insulator 2. The electrode terminal portion 18 is exposed and connected to an external power supply (not shown).

A known heat-resistant noble metal material such as Pt or iridium is used for the center electrode discharge portion 10.
For the high heat conduction part 11, a known heat-resistant metal material such as Fe, Ni, or an alloy thereof is used, and a known metal material with high heat conductivity such as Cu is used on the inside thereof, and is formed in a cylindrical shape. Embedded in the insulator leg 20.
The tip of the high heat conduction part 11 is exposed from the insulator leg part 20 and connected to the center electrode discharge part 10.
At the base end of the high heat conducting portion 11, a connecting portion 12 having an enlarged diameter is formed. The high heat conducting portion 11 prevents the insulator leg portion 20 from coming off.
The connecting portion 12 is connected to the high heat conducting portion 11 and the resistor 14 and is formed so as to increase in diameter toward the base end side, and is locked to the inner body inner peripheral inclined surface 213 of the insulator 2. The high heat conduction portion 11 prevents the insulator leg portion 20 from coming off.

For the distal end side adhesive layer 13 and the proximal end side adhesive layer 15, a mixture of glass powder and metal powder such as copper, iron, or an alloy thereof is used and filled and compressed at a predetermined position in the insulator 2. After being melted by heating.
The distal-end-side adhesive layer 13 hermetically seals and fixes the connecting portion 12 provided on the proximal end side of the high heat conducting portion 11 on the distal end side of the resistor 14 and electrically connects the connecting portion 12 and the resistor 14. I am trying.
The proximal end side adhesive layer 15 hermetically seals and fixes the proximal end side of the resistor 14 and the middle shaft embedded portion 16 inside the insulator 2 on the proximal end side of the resistor 14, and The electrical connection with the part 17 is aimed at.
The resistance values of the distal end side adhesive layer 13 and the proximal end side adhesive layer 15 are about several mΩ.

The resistor 14 includes B2O3-SiO2 type, BaO-SiO2-B2O type 3, ZnO-B2O3-SiO2 type, BaO-CaO-B2O3-SiO type 2, Na2O-SiO2-B2O3 type, K2O-SiO2-B2O3 type, Glass powder composed of at least one selected from Al2O3-B2O3-SiO2, BaO-B2O3, Bi2O-B2O3, SiO2-MgO-Al2O3, conductive powder such as carbon, Al2O3, SiO2 , Composed of an aggregate made of an insulating material containing at least one selected from SiC, Si3N4, and ZrO2, after being filled and compressed in the resistor accommodation holes 214 partitioned inside the insulator 2, It is configured by being melted by heating.
The resistor 14 is formed in a cylindrical shape following the inner diameter of the resistor housing hole 214.

The middle shaft pushing portion 16 is formed on the distal end side of the middle shaft portion 17 by being formed into a screw shape in which a part of the diameter is enlarged, and is pushed in with the adhesive layer 15 heated and melted.
The central shaft portion 17 is made of a metal such as iron, nickel, alloys thereof, or stainless steel, and is formed in a columnar shape.
The central shaft portion 17 is formed in a columnar shape, is embedded in the insulator head portion 23, is provided with a center electrode terminal portion 18 at a position exposed from the insulator 2 on the proximal end side, and is provided outside the center electrode 1. An electrical connection with an abbreviated power supply is intended.

The center electrode terminal portion 18 is made of metal such as iron, nickel, an alloy thereof, or stainless steel, and may be detachable from the central shaft portion 17 as necessary.
In the present invention, when the outer diameter φD ₃ (radius R ₃ ) of the resistor 14 and the outer diameter φD ₁ (radius R ₁ ) of the high heat conducting portion 11 are set, at least D ₃ > D ₁ (that is, R ₃ > R ₁ ) is established, and an insulator leg portion 20 where an insulator 2 described later is exposed to the gas pocket 41 has a constant insulator leg outer diameter φD so as to be parallel to the central axis C / L. _An insulator leg vertical portion 203 extending vertically at ₂ (radius R ₂ ) is formed.
By adopting such a structure, the electrostatic capacitance on the tip side of the resistor 14 is reduced, and the durability is improved by reducing noise and capacitive discharge.

Further, between the outer diameter φD ₂ (radius R ₂ ) of the insulator leg portion 20 and the outer diameter φD ₁ (radius R ₁ ) of the high heat conduction portion 11, 0.18 ≦ D ₁ / D ₂ (= R ₁ / R ₂ ) ≦ 0.32 is established.
By setting the radius ratio R ₁ / R ₂ in a specific range by an inventor's diligent test to be described later, the spark plug 100 has high durability by achieving both improvement in withstand voltage and reduction in capacity discharge. Was found to be feasible.

More desirably, the outer diameter φD ₃ (radius R ₃ ) of the resistor 14, the outer diameter φD ₁ (radius R ₁ ) of the high heat conducting portion 11, and the outer diameter φD ₄ (radius R ₄ ) of the middle shaft embedded portion 16. Are formed so that the relationship of D ₄ > D ₃ > D ₁ (ie, R ₄ > R ₃ > R ₁ ) is established, thereby promoting the densification of the resistor 14, The diameter can be reduced and the durability can be improved.

The insulator 2 is made of high-purity alumina and is formed in a cylindrical shape.
The center electrode 1 is inserted and held inside the insulator 2.
The insulator 2 includes an insulator leg portion 20, an insulator middle trunk portion 21, an insulator large diameter portion 22, and an insulator head portion 23.

The insulator leg portion 20 is exposed in a gas pocket 41 communicating with a combustion chamber (not shown) from the distal end side of a projecting locking portion 34 described later.
On the base end side of the insulator leg portion 20, an insulator middle trunk portion 21 having a diameter larger than that of the insulator leg portion 20 is provided.
The distal end of the insulator middle body portion 21 is in contact with the projecting locking portion 34 directly or via an annular seal member 42.

An insulator large diameter portion 22 is formed in a part of the insulator middle body portion 21 so as to project in a hook shape toward the outer diameter direction.
A known powder filling member 38 such as talc is disposed so as to cover the proximal end side of the insulator large diameter portion 22, and is fixed by caulking by a caulking portion 36 provided in the housing 3.
An insulator head 23 exposed from the housing 3 is provided on the proximal end side of the insulator large diameter portion 22.
In order to prevent leakage during discharge, a part of the insulator head 23 may be formed in a corrugated shape, and the creeping distance between the center electrode terminal portion 18 and the housing 3 may be increased.

The housing 3 is formed in a cylindrical shape using a known metal material such as iron, nickel, alloys thereof, carbon steel, and stainless steel.
The housing 3 includes a ground electrode discharge part 30, a ground electrode 31, a gas pocket peripheral wall part (side electrode part) 32, a mounting screw part 33, a projecting locking part 34 (also referred to as a jitz part), an insulator housing part 35, The fastening portion 36 and the hexagonal portion 37 are included.
The housing 3 is formed by a projecting locking portion 34 projecting a part of the inner peripheral surface thereof toward the center, and a crimping portion 36 whose base end side edge is crimped inward. The part 21 and the insulator large diameter part 22 are fixed by caulking.

The ground electrode discharge part 30 is disposed at a position facing the center electrode discharge part 10 with a predetermined discharge gap 40 therebetween.
The ground electrode discharge part 30 may use iridium, or a known noble metal such as iridium alloy, platinum, or platinum alloy in order to improve durability.

The ground electrode 31 is made of a metal having excellent conductivity and heat conductivity such as iron, nickel, nickel alloy.
The ground electrode 31 is provided so as to be curved in an L shape from the front end of the housing 3 to a position facing the center electrode discharge unit 10, and the ground electrode discharge unit 30 is disposed at the front end.
A part of the housing 3 surrounds the periphery of the insulator leg portion 20 and constitutes a gas pocket peripheral wall portion 32 that divides the gas pocket 41 inside.

A mounting screw portion 33 is formed on the outer peripheral side of the gas pocket peripheral wall portion 32 so that it can be fixed to an engine head of an internal combustion engine (not shown).
The mounting screw portion 33 thermally radiates heat generated in the gas pocket 41 to the engine head via the gas pocket peripheral wall portion 32.
The mounting screw portion 33 electrically grounds the ground electrode discharge portion 30 to the engine head of the internal combustion engine via the ground electrode 31 and the gas pocket peripheral wall portion 32.

Electrically, the gas pocket peripheral wall portion 32 also functions as a side electrode that generates an electric field with the high thermal conductivity portion 11. In order to accommodate and hold the insulator 2 inside the insulator accommodating portion 35, an insulator accommodating portion inner peripheral surface 350 capable of accommodating the insulator middle trunk portion 21 is provided.
A powder filling portion 351 having a diameter larger than that of the insulator large-diameter portion 22 is formed on the proximal end side of the insulator housing portion inner peripheral surface 350.

A protruding locking portion 34 is formed on the distal end side of the insulator housing portion inner peripheral surface 350.
The projecting locking portion 34 protrudes in an annular shape toward a center on a part of the inner peripheral surface of the housing 3, and locks the tip of the insulator middle barrel portion 21.
The insulator leg portion 20 is exposed in the gas pocket 41 partitioned on the distal end side of the protruding locking portion 34.

In a state where the distal end of the insulator middle body portion 21 is held by the projecting locking portion 34, the crimping portion 36 provided on the proximal end side of the housing 3 causes the insulator large diameter portion 23 to axially pass through the powder filling member 38. The airtightness between the housing 3 and the insulator 2 is maintained.
A hexagonal portion 37 for tightening the attachment screw portion 33 is provided on the outer periphery on the proximal end side of the housing 3.
A gasket 39 is disposed between the housing 3 and an unillustrated engine head to ensure airtightness between the spark plug 100 and the engine head.

Inside the insulator large diameter portion 22 and the insulator head portion 23, an intermediate shaft insertion hole 222 into which the intermediate shaft portion 17 and the intermediate shaft pushing portion 16 can be inserted is formed.
A resistor housing hole 214 having a diameter smaller than that of the middle shaft insertion hole 222 is formed inside the insulator middle body portion 21.

The central shaft insertion hole 222 and the resistor housing hole 214 are communicated with each other by a large-diameter inner peripheral inclined surface 221 that is reduced in diameter so as to decrease in diameter toward the tip.
An electrode insertion hole 201 having a diameter smaller than that of the resistor housing hole 214 is formed inside the insulator leg portion 20.
The resistor housing hole 214 and the electrode insertion hole 201 are communicated with each other by an insulator inner trunk inclined surface 213 whose diameter is reduced so as to decrease in diameter toward the tip.
The connecting part 12 is locked to the inner peripherally inclined surface 213 of the insulator middle body part, so that the high heat conducting part 11 is prevented from coming off.

The insulator middle barrel outer peripheral inclined surface 211 and the insulator leg perpendicular to the insulator middle barrel portion 21 provided between the insulator middle barrel portion 21 and the insulator leg outer portion 212 having a diameter smaller than that of the insulator middle barrel portion outer peripheral surface 212. A position where the portion 203 intersects is referred to as a lever leg root portion 210.
The insulator leg portion 20 is formed with an insulator leg portion vertical portion 203 extending vertically with a constant insulator leg outer diameter φD ₂ (radius R ₂ ) so as to be parallel to the central axis C / L.
Further, a locking portion inner peripheral surface 340 of the protruding locking portion 34 that extends vertically so as to be parallel to the central axis C / L with respect to the lever leg root portion 210 is formed.

The intensive study of the inventors, with reference to the position of the insulator leg portion base portion 210, the length of the locking portion in the peripheral surface 340, a projecting locking portion edge axial length L _1, the insulator leg It has been found that it is desirable to set L ₂ > L ₁ when the length of the vertical portion 203 is the length L ₂ (mm) of the insulator leg portion.
The boundary between the high heat conduction part 11 and the connecting part 12 is referred to as a high heat conduction part root part 120.
Desirably, 0.9 ≦ L3 ≦ 1.7 is set, where the vertical distance to the insulator leg base 210 is the insulator leg insulation distance L ₃ (mm) with the high heat conduction base 120 as a reference. It has been found.

The spark plug 100 has a diameter φD ₁ of the high heat conduction portion at a base end position where the high heat conduction portion 11 is connected to the coupling portion 12 at least smaller than a diameter φD ₃ where the resistor 14 is connected to the adhesive layer 13. while, is characterized in that it comprises an insulator leg vertical section 203 insulator leg portion is exposed from the protruding engaging portion so as to extend vertically while maintaining a constant diameter [phi] D _2.
In the spark plug 100 of the present invention, by making the outer diameter φD ₃ of the resistor 14 smaller than the outer diameter φD ₄ of the center shaft pushing portion 16, the filling density of the resistor 14 is homogenized and densified. The specific resistance is increased, and the spark plug 100 is further miniaturized by reducing the size of the resistor 14.
Furthermore, by making the outer diameter φD ₁ of the high heat conducting portion 11 smaller than the outer diameter φD ₃ of the resistor 14, compared to the case where the outer diameter of the conventional resistor and the outer diameter of the center shaft pushing portion are set equal, The high heat conduction part 11 is made thin, and the thickness of the portion of the insulator 2 covering the periphery from the insulator middle body part 21 to the insulator leg part 20 is made relatively thick so The electric capacity can be reduced.

As a result of the inventor's diligent test, the center electrode diameter insulator diameter ratio R ₁ / R _{2 is set} to 0.18 or more and 0.32 or less, so that the high heat conduction portion 11 is thinned and the thickness of the insulator leg portion 20 is increased. It has been found that by increasing the thickness relatively, the withstand voltage performance can be increased, the capacitance can be reduced, and electrode consumption due to capacitive discharge can be suppressed.
In addition, by reducing the outer diameter of the high heat conducting portion 11 as compared with the conventional case, the thickness of the insulator 2 covering the periphery thereof becomes relatively thick and the dielectric strength voltage in the radial direction becomes high. 11, the axial distance between the root portion 120 of the connecting portion 12 provided on the base end side and the root portion 210 diameter-changing from the insulator middle body portion 21 of the insulator 2 to the insulator leg portion 20, that is, Even if the axial insulation distance L ₃ is shortened, if it is set to 0.9 mm ≦ L ₃ ≦ 1.8 mm, the heat sink can be secured without causing a decrease in the insulation breakdown voltage, and pre-ignition is generated. It was found that it can be suppressed.

Referring to FIGS. 3 and 4, outer diameter φD ₁ (radius R ₁ ) of high heat conducting portion 11, outer diameter φD ₂ (radius R ₂ ) of insulator leg portion 20, withstand voltage DST (kV), and electrostatic capacitance The relationship with C (μF) will be described.
FIG. 3 shows that the outer diameter φD ₂ of the insulator leg portion 20 is fixed to 5.0 mm, 5.9 mm, and 6.9 mm for the nominal diameters M10, M12, and M14 of the mounting screw portion 33, respectively. Withstand voltage DST (kV) and capacitance C (μF) when the outer diameter φD ₁ is changed to 0.9 to 1.6 mm, 1.06 to 1.89 mm, and 1.24 to 2.21 mm, respectively. ).

The capacitance C is a value calculated by 2πε ₁ L / Ln (R ₂ / R ₁ ).
However, ε ₁ is the relative dielectric constant of alumina constituting the insulator 2, and L is the axial length of the range in which R ₂ is constant in the insulator leg 20 (corresponding to the insulator leg vertical portion length L ₂₎ . ).
Moreover, results of this study are those when the insulator legs insulation distance L ₃ was 2.5 mm.

In FIG. 4, the highest withstand voltage is set to 1, and the change in withstand voltage is expressed as a relative value.
In the conventional spark plug, the outer diameter of the high heat conduction portion is formed to be about half of the outer diameter of the insulator leg portion (that is, about D ₁ / D ₂ = R ₁ / R ₂ = 0.5).
When the outer diameter φD ₂ of the insulator leg portion 20 is made constant and the outer diameter φD ₁ of the high heat conducting portion 11 is changed, the withstand voltage gradually rises and then the withstand voltage starts to decrease and there is a peak value. There was found.
This is because if the outer diameter of the high heat conduction part 11 is made thinner, the thickness of the insulator leg part 20 is increased accordingly, so that the withstand voltage increases, but the outer diameter of the high heat conduction part 11 exceeds a certain range. If it is made thinner, it is considered that electric field concentration is caused and the withstand voltage is lowered.

On the other hand, diameter of the outer diameter [phi] D ₁ of the highly thermal conductive portion 11 (i.e., the center electrode径碍Ko diameter ratio decrease of R _{1 /} R ₂₎ with the order of increasing outer diameter [phi] D ₂ of the insulator leg portion 20 necessarily In particular, the capacitance C becomes small.
As described above, by setting the radius ratio R ₁ / R ₂ to 0.18 or more and 0.32 or less, while ensuring the withstand voltage between the resistor 14 and the projecting locking portion 34 provided in the housing 3, It was found that the capacitance C on the tip side than the resistor 14 can be reduced.

Referring to FIG. 5, the insulator leg portion 20 to the insulator 2 exposed from the projecting locking portion 34 in the gas pocket 41, the insulator leg vertical section 203 extending linearly in the axial direction in the outer diameter [phi] D ₂ constant effect will be described with respect to the length L ₂ and the insulator 2 in withstand voltage.
The present test result is set radius ratio _R 1 _{/ R 3} = 0.3 to _{(R 1 = 2.1mm, R 2} = 6.9mm), insulator legs insulation distance _L 3 = 2.5 mm, the insulator legs parts vertical section is obtained by changing the length L _2.

As shown in FIG. 5, the length L ₂ of the insulator leg vertical section 203 exceeds the length L ₁ of the vertical portion of the projecting locking portion 34, abruptly withstand voltage was found to be elevated.
This is because when the diameter of the insulator leg portion is gradually reduced from the base of the insulator leg portion without the vertical portion being provided in the conventional manner, the withstand voltage of the root portion is the highest, This is thought to be because the withstand voltage is lowered due to the concentration of the electric field.

On the other hand, if the electrode outer peripheral surface extending from the base end portion of the center electrode to the position corresponding to the end surface of the insulator is formed in a tapered tapered surface, as disclosed in Patent Document 1, regardless of the present invention, the insulator is relatively There is a possibility that the insulation distance at the base portion of the leg portion is shortened and the withstand voltage is lowered.
Therefore, in the present invention, by greater than the length L ₁ of the vertical portion of the projecting locking portion 34 having a length L ₂ of the insulator leg vertical portion 203 inside the housing 3, a high withstand voltage We obtained knowledge that a spark plug could be realized.

Referring to FIG. 6, the axial insulation length from the base end side root portion 120 of the high heat conducting portion 11 to the base end side root portion 210 of the insulator leg portion 20 with respect to the withstand voltage of the spark plug 100 of the present invention. It will be described the results of the examination of the effects of L _3.
The present test result is the result obtained when the radius ratio _{R 1 / R 3 = 0.3 (} R 1 = 2.1mm, R 2 = 6.9mm).

Since the thickness of the insulator leg portion 20 can be relatively increased by reducing the diameter of the high heat conducting portion 11, the withstand voltage is improved.
Therefore, when short axial insulating length L _3, was investigated limits to maintain the conventional withstand voltage equivalent to the withstand voltage.

As a result, even with a shorter direction insulating length _{L 3} from 2.5mm to 1.5 mm, the withstand voltage has been no change, when shorter than 0.9 mm, results in a possibility that below a predetermined withstand voltage lower limit Therefore, this was set as the lower limit.

7, with reference to Table 1, when the radius R ₁ of the highly thermal conductive portion 11 for the pre-ignition occurrence temperature of the spark plug 100 of the present invention has been reduced in diameter, the influence of the length in the axial direction insulation distance L ₃ Survey The test results will be described.
And the radius R ₁ of the high thermal conductive portion 11 and small diameter, but decrease in heat dissipation property is concerned, on the other hand, the diameter of the radius R ₁ of the highly thermal conductive portion 11, the thickness of the insulator leg portion 20 Since the thickness is increased, the voltage resistance is improved.

Therefore, while maintaining the withstand voltage performance, the axial insulation distance L ₃ is set to be lower than or equal 1.7 mm, and the high thermal conductive portion 11 to facilitate heat transfer to the center pole portion 17.
As a result, it has been found that the cooling effect via the center electrode 1 is improved, the pre-gage generation temperature can be increased to 940 ° C. or more, and the decrease in heat drawability can be compensated.
That is, due to the diameter of the high thermal conductive portion 11, can be suppressed the occurrence of pre-ignition is found a decrease in cooling effect is compensated by shortening the axial insulation distance L _3.
On the other hand, as described above, when the axial insulating distance _{L 3} and less than 0.9 mm, since the withstand voltage is lowered to obtain a knowledge that it is desirable to 0.9 mm ≦ _{L 3} ≦ 1.7 mm .

DESCRIPTION OF SYMBOLS 100 Spark plug 1 Center electrode 10 Center electrode discharge part 11 High heat conduction part 12 Connection part 13, 15 Adhesion layer 14 Resistor 16 Middle shaft embedding part 17 Middle shaft part 18 Center electrode terminal part 2 Insulator 20 Insulator leg part (exposed end side) Part)
203 Insulator leg vertical part 21 Insulator body trunk part 210 Insulator leg base part 23 Insulator head 3 Housing 30 Ground electrode discharge part 31 Ground electrode 34 Projection locking part (jitz part)
340 Gitz part inner peripheral vertical part 36 Clamping part 40 Discharge gap R ₁ High heat conduction part radius R ₂ Insulator leg radius R ₃ Resistor radius R ₄ Middle shaft pushing part radius L ₁ Protruding locking part edge axial length L ₂ Vertical length of insulator leg L ₃ Insulation length in the axial direction of the center electrode
φD ₁ High heat conduction part diameter φD ₂ Insulator leg diameter φD ₃ Resistor diameter φD ₄ Center shaft pushing part diameter

Claims (5)

At least the center electrode (1) extending in the shape of an axis and the center electrode discharge part (10) provided at the tip of the center electrode from one end are exposed, and the center provided at the base end of the center electrode from the other end A cylindrical insulator (2) that holds the center electrode so that the electrode terminal portion (18) is exposed, and an insulator leg portion (20) provided on one end of the insulator on the tip side of the insulator, are exposed, A housing (3) that accommodates and holds the insulator so as to expose an insulator head (23) provided on the base end side of the insulator from the other end, and extends from the housing toward the central electrode discharge portion A ground electrode (31), and a ground electrode discharge part (30) facing the center electrode discharge part at a tip of the ground electrode with a predetermined discharge gap (40),
The center electrode is between the center electrode terminal portion and the center electrode discharge portion,
A proximal end side connected to the central electrode terminal portion, and a middle shaft portion (17) extending in a cylindrical shape inside the insulator head;
A central shaft embedding portion (16) whose diameter is enlarged at the tip side of the central shaft portion;
A columnar resistor (14) connected to the central shaft embedded portion;
A connecting portion (12) having a diameter expanded so as to increase in diameter toward the base end side on the distal end side, and a columnar high heat conduction portion (11) connected to the central electrode discharge portion on the distal end side;
A base end side adhesive layer (15) for securing electrical connection between the middle shaft embedded portion and the resistor, and fixing the middle shaft embedded portion to the inside of the insulator,
A tip side adhesive layer (13) for securing electrical connection between the resistor and the connecting portion and fixing the connecting portion to the inside of the insulator,
The insulator has an insulator body trunk portion (21) having a diameter larger than that of the insulator leg portion between the insulator head and the insulator leg portion, and a part of the insulator intermediate trunk portion is formed in a bowl shape. And an expanded insulator large diameter portion (22),
The housing includes a projecting locking portion (34) in which a part of the inner peripheral surface projects toward the center, and a crimped portion (36) in which the proximal end edge is crimped inward. A spark plug in which the insulator middle body portion and the insulator large diameter portion are fixed by caulking,
At least the diameter (φD ₁ ) of the high heat conduction portion at the base end position where the high heat conduction portion is connected to the connecting portion is smaller than the diameter (φD ₃ ) where the resistor is connected to the adhesive layer. ,
A lever leg vertical portion (203) exposed from the projecting locking portion so that the lever leg portion extends to the tip side while maintaining a constant diameter (φD ₂ );
The boundary between the high heat conduction part and the connection part is defined as a high heat conduction part root part (120), and the vertical distance from the high heat conduction part root part to the root part (210) of the lever leg part is defined as a leg leg part. When the insulation distance is L ₃ (mm),
Spark plug (100), wherein 0.9 ≦ L ₃ ≦ 1.7 is set When the radius of the high heat conduction part is R ₁ and the radius of the insulator leg part is R ₂ ,
The spark plug according to claim 1, wherein 0.18 ≦ R ₁ / R ₂ ≦ 0.32. With reference to the position of the base portion of the insulator leg portion (210), the length of the inner peripheral surface of the projecting locking portion (340), a projecting locking portion edge axial length L _1, the when the length of the insulator leg vertical section and the insulator leg vertical portion length L _2,
Spark plug according to claim 1 or 2 is L _{2> L 1} The spark plug according to any one of claims 1 to 3, wherein a diameter (φD ₃ ) of the resistor is smaller than a diameter (φD ₄ ) of the central shaft embedded portion.   The spark plug according to any one of claims 1 to 4, wherein a nominal diameter of the screw portion is any one of M8, M9, M10, M11, M12, M13, and M14.

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