DE10327596A1 - Spark plug for vehicle engine comprises hollow housing, an insulator fitting in the housing, central electrode fitting in the insulator and having front end section protruding over end section of the insulator and earth electrode - Google Patents

Abstract

Spark plug comprises housing (10) having hollow section, insulator (20) fitting in housing having axial bore, central electrode (30) fitting in insulator having front end section (31) protruding over insulator end section (21), and earth electrode (40) connected to end of housing having front end surface facing central electrode lateral surface to provide spark discharge gap. Earth electrode front end surface has area of 0.07-1.13 mm2>.

Description

The present invention relates on a spark plug especially for an internal combustion engine of the type with discharge on a lateral surface, at which is a spark discharge between a side surface of a Center electrode and a front end surface of a ground electrode is generated.

In a conventional technology, a flame out or a misfire, caused, for example, in a gasoline engine of an automobile are detected by detecting an ion current that is a spark plug happens, such as in Japanese Patent Application Laid-Open No. HEI 12-34969.

In the technology of this previously published publication becomes an improvement in the detection performance of an ion current by increasing of a surface area a center electrode of a spark plug achieved to thereby easily contact ions in cylinders of the internal combustion engine are present, with the surface of the Promote center electrode.

In such a spark plug however, combustion residues adhere to the increase in engine mileage the surface the center electrode, and therefore a portion of the Electrode surface, on which there are no combustion residues thereby deteriorating the ion current detection performance.

Furthermore, a case can be caused in which there is an insulation resistance between the center electrode and the ground electrode by adhering carbon or the like is reduced, and in such a case also the ion current detection power deteriorated, causing disadvantages or maladministration of the operation of the internal combustion engine occur.

An object of the present invention is to essentially eliminate mistakes or disadvantages that associated with the aforementioned prior art, and especially for an internal combustion engine, for for example an automobile, a spark plug to carry out a to create improved ion current detection.

These and other objects can be achieved in a main aspect according to the present invention by providing a spark plug, especially for an internal combustion engine, which:
a housing that has an inner hollow portion;
an insulator that is fitted into the housing and has an axial bore;
a center electrode fitted in the insulator
wherein the center electrode has a front end that projects over an end portion of the insulator; and
has at least one ground electrode connected to one end of the housing,
wherein the ground electrode has a front end surface facing a side portion of the center electrode so that a spark discharge gap is provided between the side surface of the center electrode and the front end surface of the ground electrode,
wherein the front end surface of the ground electrode has a surface in a range of 0.07 to 1.13 mm ² .

According to this aspect, therefore, by setting the area of the front end portion of the ground electrode to less (not more than) 1.13 mm ² , the field strength between the spark discharge gap and the ignition voltage is reduced. Therefore, the time interval receiving the arc voltage can be extended, and the flame growth time can also be extended. In addition, the combustion residue adhered to the surface of the center electrode is burned to thereby increase the intact surface of the center electrode and improve the ion current detection performance.

Furthermore, by setting this surface to more (not less than) 0.07 mm ^2, the oxidation resistance of the ground electrode can be maintained at a sufficiently suitable level, and the improved ion current detection can be obtained.

In a preferred embodiment of the the above aspect of the present invention has the ground electrode a leg portion having an end connected to the housing and has another end on which a protrusion is formed so that it extends to the center electrode side, the protrusion being a thickness thinner than that of the body of the leg portion and the protrusion has a protruding length of more than 0.3 mm and has less than 1.5 mm.

In this embodiment, by setting up the protruding length of the protrusion to more than 0.3 reduces the cooling function of the flame core and it can be the high ignitability can be ensured, and further, by setting up its protruding length to less than 1.5 mm the oxidation resistance of the Ground electrode can be obtained at the sufficiently suitable level.

In the other embodiments of the above aspect, the protrusion may be formed from a noble metal selected from the group consisting of Pt, Ir, Pt alloy or Ir alloy. The front end of the center electrode has an outer diameter in a range of 0.7 to 2.0 mm. The spark discharge gap has a dimension in a range of 0.7 to 1.1 mm. A relationship between the size G of the spark discharge gap and a size g of a gap between an inner peripheral surface of the end portion of the housing and an outer peripheral surface of the insulator is established to meet a condition of g 0,6 0.65 G.

According to this embodiment can be done by setting up sizes G and g of the column to g ≤ 0.65 G is a flying spark in the gap between the inner peripheral surface of the housing end and the outer peripheral portion of the insulator. So carbon or the like, which is adhered to the insulator to be burned thereby the insulation resistance restore and the ion current detection ability to improve.

Furthermore, a variety of Ground electrodes are arranged. The spark plug of the present invention is preferred for detecting an ion current of an internal combustion engine used.

The nature and other characteristic Features of the present invention will also be apparent from the following Description made with reference to the accompanying drawings.

In the accompanying drawings:

1 Fig. 14 is an elevational view in half section showing an overall structure of a spark plug according to a first embodiment of the present invention;

2 a representation in a half section of a spark discharge portion of the spark plug of 1 on a larger scale;

3 a diagram showing a relationship between a surface of a center electrode and an ion current of the spark plug;

4 a diagram showing a relationship between a travel distance of an automobile and an intact surface of the center electrode;

5 a diagram showing a relationship between a ratio (%) of a facing surface of a ground electrode and its intact surface after use in a durability test;

6 a diagram showing a relationship between a length of a discharge member and an ignition restricting air-fuel ratio;

7 one too 2 similar view illustrating a second embodiment of the present invention;

8th a view from an arrow VIII in 7 seen;

9 one too 2 similar view illustrating a third embodiment of the present invention;

10 one too 2 similar view illustrating a fourth embodiment of the present invention; and

it shows 11 various (second) discharge elements (A) to (E), which are shown in sections.

Preferred embodiments of the present invention are described here with reference to the accompanying drawings, in which a reference symbol 100 features a spark plug according to the present invention, a spark plug of the discharge type on a side surface in which a front end surface of a ground electrode faces a side surface of a center electrode.

Furthermore, the terms are "upper", "lower" or the like used here with reference to the illustrated states in the drawings.

First embodiment

The first embodiment of the spark plug 100 the present invention is hereby incorporated by reference 1 to 6 described.

Referring to 1 and 2 has the spark plug, generally indicated by the reference number 100 is characterized, a cylindrical housing 10 , which is made of metal, an insulator or an insulating element 20 , a center electrode 30 and a ground electrode 40 ,

The housing 10 has an inner hollow section and is with a mounting screw 11 for attaching the housing 10 on a cylinder block of an internal combustion engine, which is not shown. The isolator 20 is made of aluminum ceramic (Al ₂ O ₃ ) or the like, has an axial (shaft) bore and is inside the housing 10 fitted and fixed in a way that a front end portion 21 of the isolator 20 over an end section (lower end) 12 of the housing 10 projects.

The center electrode 30 This embodiment has a columnar shape and is in the axial bore of the insulator 20 fitted and affixed to it so that it insulates the housing 20 over the isolator 20 is supported. The center electrode 30 has a front end 31 , ie a bottom end in 1 seen that over the front end section 21 of the isolator 20 protrudes. The center electrode 30 has an inner member made of a metal material such as Cu, which has excellent thermal conductivity, and an outer member made of a metallic material, such as nickel-base alloy, which has excellent heat resistance and anti-corrosion property.

The center electrode 30 has a first discharge dung element 32 that is part of the center electrode 30 trains, which is connected to its lateral surface. The first discharge element 32 is made of a noble metal such as Pb alloy.

On the other hand, there are a variety of ground electrodes 40 (two in this embodiment) with the end portion 12 of the housing 10 connected for example by welding. Each of these ground electrodes 40 has a thigh section 41 that has one end, that with the case 10 is connected, and a second discharge element 42 that with the other end of the leg section 41 connected is. The leg section is formed from a Ni alloy and has a rectangular column shape in this exemplary embodiment.

The second discharge element 42 has a thin tubular structure that is thinner in thickness than a body portion of the leg portion 41 and extends from the other end of the leg portion 41 to the center electrode 30 so that it is the side surface of the center electrode 30 is facing, ie its first discharge element 32 is facing. The second discharge element 42 is made of a noble metal such as Pb alloy. This second discharge element 42 can only protruding portion of the ground electrode 40 to be named.

A spark discharge gap 50 is between the first discharge element 32 that is on the center electrode 30 is formed, and the second discharge element 42 defines that on the ground electrode 40 is trained.

A gap 60 is also between the inner peripheral surface of the end portion 12 of the housing and the outer peripheral surface of the insulator 20 educated.

Referring to the spark plug 100 With the above structure, a relationship between specifications of the related portions or elements and ion current detection characteristics will be described below.

(1) Specification of the center electrode 30

Ionic current values were measured in an idling operation of an internal combustion engine with 2000 cm ³ , in which four types of spark plugs A to D are each connected in four cylinders, which are arranged in series. The spark plugs A to D differ from one another in their surface sections of the center electrode 30 that over the insulator 20 protrude (which can be called the center electrode surface below). The results of the measurement are in 3 which reveals the fact that the ion current values become larger as the center electrode surface becomes wider.

In the next step, spark plugs that have been used for internal combustion engines of automobiles have been retrieved from the commercial market to establish a relationship between a running distance of an automobile and a surface of an intact portion of the center electrode 30 to be examined in which no combustion residues (which can be called intact surface below) adhere to the center electrode surface. The spark plugs obtained and examined were spark plugs of the type with discharge on a lateral surface, each having two ground electrodes.

4 Fig. 11 is a graph showing results of the above-mentioned study. As can be seen from this diagram, as the running distance increases, the center electrode becomes 30 broadly covered by combustion residues and reduced the intact surface. Assuming that an intact surface of a new product is represented by a symbol S ₀ and that an old (used) product is represented by a symbol S ₁ , however, it has been found experimentally that the intact surface S _{1 of} the used product in the Spark plug of the type with discharge on one side surface, the two ground electrodes 40 has, is not less than S ₀ × 0.7. This is because in the case of the spark plug of the discharge type on one side surface, the two ground electrodes 40 has the combustion residue that adheres to the surface of the center electrode, burned at the time of the spark discharge, and thereby its surface can be cleaned consistently and safely.

Furthermore, the inventor of the application in question found that in the case of the intact surface of more than 5 mm ^2, an ion current of a height that can detect a misfire with high precision could be obtained. Accordingly, in a case where the center electrode 30 has the protruding length of Lc with a general value of 3.4 mm, the intact surface S _{1 of} the used product by setting up the outer diameter (∅) Dc of the front end portion 31 the center electrode 30 to more than 0.7 mm larger than 5 mm ² , which ensures sufficient usable power for ion current detection. Furthermore, in an example in which the intact surface S _{1 is} more than 5 mm ² , the length Lc is selected with a value in the range from 3 to 4 mm.

Furthermore, it is noted that in the case where the outer diameter (∅) Dc of the front end portion 31 the center electrode 30 is made more than 2 mm, which is a current general value, the thickness of the front end portion 21 of the isolator 20 becomes thin and therefore a dielectric strength is reduced. Therefore, it is desirable that the center electrode 30 is constructed so that the outer diameter DC of the front end portion 31 the center electrode 30 has an upper limit of 2 mm.

(2) Specification of the ground electrode 40

A ratio (S ₁ / S ₀ × 100%) of the intact surface S ₁ after the durability test to an intact surface S ₀ before the durability test was investigated by preparing three types of spark plugs that have different front end faces of the ground electrodes 40 facing the side surface of the center electrode (hereinafter, facing surface S _g ) by mounting the spark plugs in a six-cylinder in-line engine of 2000 cm ³ and performing the durability test for 300 hours by setting a state in which the combustion residues are slightly attached, was carried out.

One of the spark plugs used in the durability test above was not with the second discharge element 42 provided and had a structure in which the front end portion of the leg portion 41 , which has a rectangular column side of 1.6 mm × 2.8 mm, that of the side surface of the center electrode 30 is facing. The other two spark plugs each had the second discharge elements, which have a diameter (∅) of 0.4 mm and 1.2 mm.

5 shows a result of the above-mentioned durability test, which was found to be when the diameter of the second output member 42 is made thin, ie when the facing surface S _g becomes narrow, the ratio of the intact surface is increased after use in the durability test. This is because by making the diameter of the second discharge element thin 42 the electric field strength in the spark discharge gap 50 has been increased, the discharge voltage has therefore been reduced, the arc voltage receiving time interval, ie the flame growth time, has been extended, and therefore the combustion residue on the center electrode could be burned in a wide range.

Through the above experiments, it has been found that by making the diameter of the second discharge element thin 42 the ratio of the intact surface after use for the durability test has been increased and the ion current detection performance has been improved. According to this experimental fact, in the next step, spark plugs became the second discharge elements 42 have different outer diameter Dg and lengths Lg have prepared, analyzed by air-fuel ratios at ignition limits by using four-cylinder internal combustion engines of 1600 cm ^3.

6 Fig. 12 is a graph showing the results of the investigation, in which it was found that a quenching function of a flame core was reduced and excellent ignitability by establishing the outer diameter Dg of the second discharge member 42 to less (no more) than 1.2 mm and setting its length Lg to more (no less) than 0.3 mm could be ensured.

In a case in which the outer diameter Dg of the second discharge element is less than 0.3 mm, or in a case in which its length is more than 1.5 mm, it was found that the second discharge element 42 itself was heated to a high temperature and was therefore easily oxidized and worn, which made it unusable.

Given the experimental results of 6 it is desirable that the second discharge element 42 has the outer diameter Dg of more than 0.3 mm and less than 1.2 mm, ie it is desirable that the second discharge element 42 has the facing surface S _g of more than 0.07 mm ² and less than 1.13 mm ² . In particular, it is desirable that the second discharge element 42 has the outer diameter Dg of more than 0.4 mm and less than 1.0 mm.

On the other hand, it is also desirable that the second discharge element 42 has a length Lg of more than 0.3 mm and less than 1.5 mm and more preferably of more than 0.5 mm and less than 1.0 mm.

By setting up the facing surface Sg and the length Lg of the second discharge element 42 to the above values, it was found that the improved ion current detection performance could be achieved while the oxidation resistance could be kept at a sufficiently convenient level.

(3) Dimension of the spark plug gap 50

According to the above-mentioned embodiment of the present invention, the ignitability can be made by making the diameter of the second discharge element thin 42 the ground electrode 40 be improved even when the dimension of the spark discharge gap 50 is set to 0.7 mm to 1.1 mm (which is a commonly used value). From this point of view, it is desirable to have the size G of the spark discharge gap 50 to be set up in a range of 0.7 to 1.1 mm.

In a case where this size G of the spark discharge gap 50 is made smaller than the above value, the field strength in the spark discharge gap 50 high, and therefore the discharge voltage will be reduced. Therefore, an arc voltage-keeping time interval becomes longer, and the combustion residue adhered to the surface of the center electrode can be burned safely in a wide range.

Second embodiment

The second embodiment of the present invention is by 7 and 8th represented, in which the same reference numerals for the sections or elements corresponding to these are inserted in the first embodiment.

With reference to 7 and 8th is a cone (cone) section in this second embodiment 43 at the end portion on the side of the second discharge member of the leg portion 41 formed so that it is thinner toward the side of the second discharge element. The formation of such a conical section 43 can improve the ignitability due to the cooling (quenching) function of the flame core. In particular, in the case where no cone section was formed, the ignition limit air-fuel ratio was 14.5 and, on the other hand, in the case of the cone section being formed, the air-fuel ratio was 14.7 ,

Third embodiment

The third embodiment of the present invention is by 9 represented, in which the same reference numerals are inserted on sections or elements corresponding to these in the first embodiment.

With reference to 9 is a creeping projection in this third embodiment 13 that on the inner peripheral side of one end portion 12 of the housing 10 to the isolator 20 protrudes, formed to thereby have a size g of a gap 60 between the inner peripheral surface of the creeping projection 13 and the outer peripheral surface of the insulator 20 fill.

Furthermore, in this embodiment, in a case where there is a relationship between the size g of the gap 60 and the size G of the spark discharge gap 50 is set up to meet a condition of g ≤ 0.65 G, flying sparks in the gap 60 between the inner peripheral surface of the creeping projection 13 and the outer peripheral surface of the insulator 20 be generated. Accordingly, carbon or the like may be attached to the front end portion 21 of the isolator 20 attached, burned to restore the proper insulation resistance and improve the ion current detection performance.

Fourth embodiment

The fourth embodiment of the present invention is by 10 shown, in which sections or elements corresponding to these are inserted in the first embodiment with the same reference numerals.

With reference to 10 is the leg portion in this fourth embodiment 41 from an inner material 41a , which has excellent thermal conductivity, such as Cu, and an outer material 41b , which has an excellent heat resistance property and anti-corrosion property such as Ni alloy. The inner material 41a , which is made of Cu, provides an improvement in thermal shrinkage, resulting in an improvement in the heat resistance property of the ground electrode 40 results.

Another embodiment

It is also noted that the present invention does not apply to the described embodiments limited is and many other modifications and changes without departing from the scope of the pendant Expectations deviate, executed can be.

For example, in the above-mentioned embodiments or examples, the second discharge element 42 that is a portion or part of the ground electrode 40 forms, formed so that it provides a tubular or columnar shape. The second discharge element 42 However, it can be designed in such a way that it provides different shapes in section, such as, for example, a square, rectangular, triangular, elliptical or similar shape, as in FIG 11 (A) to (E) is shown. In any case, in these examples the second discharge element 42 the power for ion current detection by setting up the facing surface Sg of the second discharge element 42 can be improved in a range of 0.07 to 1.13 mm ² .

Furthermore, the two ground electrodes mentioned in the above exemplary embodiments can 40 through a single ground electrode 40 be replaced.

Furthermore, the first and the second discharge element 32 and 42 , which are formed from Pt alloys in the exemplary embodiments described, are replaced by Pt, Ir or Ir alloy.

In addition, the spark plug of the present invention by applying positive or negative High voltage to be used on the center electrode.

A spark plug of an internal combustion engine has a housing that has an inner hollow portion, an insulator that fits in the axial bore of the housing and has an axial bore, a center electrode that fits in the insulator, the center electrode having a front end, which protrudes over an end portion of the insulator, and has ground electrodes each connected to one end of the housing. The ground electrode has a front end surface facing a side surface of the center electrode, so that a spark discharge gap between the side surface of the Center electrode and the front end surface of the ground electrode is provided. The front end surface of the ground electrode has a surface in a range of 0.07 to 1.13 mm ² .

Claims (8)

Spark plug comprising: a housing having an inner hollow portion; an insulator that is fitted in the housing and has an axial bore; a center electrode fitted in the insulator, the center electrode having a front end portion protruding over an end portion of the insulator; and at least one ground electrode connected to one end of the housing, the ground electrode having a front end surface facing a side surface of the center electrode so as to provide a spark discharge gap between the side surface of the center electrode and the front end surface of the ground electrode, wherein the front end surface of the ingot electrode has a surface in a range of 0.07 to 1.13 mm ² . spark plug of claim 1, wherein the ground electrode a leg portion has one end connected to the case and another Has an end at which a protrusion is formed to face the center electrode side to extend, with the projection a thickness of thinner than the leg portion and the protrusion has a protruding length of has more than 0.3 mm and less than 1.5 mm. spark plug The claim 2, wherein the protrusion is one of a group of Pt, Ir, Pt alloy or Ir alloy chosen Precious metal is formed. spark plug according to claim 1, wherein the front end of the center electrode has an outer diameter in a range of 0.7 to 2.0 mm. spark plug of claim 1, wherein the spark discharge gap is one size in one Has a range of 0.7 to 1.1 mm. spark plug according to claim 1, wherein a relationship between a size G of the Spark discharge gap and a size g of a gap between one inner peripheral surface of the end portion of the housing and an outer peripheral surface of the insulator to g ≤ 0.65 G is set up. spark plug of claim 1, wherein a plurality of ground electrodes are arranged is. spark plug of claim 1, wherein the spark plug is one for ion current detection.