The present invention relates to a spark plug, and more particularly to a spark plug in which a noble metal tip is provided on at least one of a center electrode and a ground electrode.
A spark plug used for ignition in an internal combustion engine (e.g., an automobile engine) generally includes a tubular metallic shell; a tubular insulator provided in an inner hole of the metallic shell; a center electrode provided in an inner hole of the insulator on the front end side thereof; and a ground electrode, one end of which is bonded to the front end of the metallic shell and the other end of which forms a gap with the center electrode. There has also been known a spark plug in which a tip formed of a noble metal alloy is provided on an end surface of a center electrode or a ground electrode for the purpose of, for example, improving spark erosion resistance.
Recent internal combustion engines for automobiles, etc. have been required to exhibit high output and high ignition performance. In connection with such a requirement, there have been developed an internal combustion engine having a supercharger in which high pressure is achieved in a combustion chamber, and an internal combustion engine employing a high-energy coil. Since a spark plug of such an internal combustion engine is used under severe environmental conditions, demand has arisen for development of a spark plug exhibiting excellent spark erosion resistance and separation resistance, as well as oxidation resistance.
For example, Japanese Patent Application Laid-Open (kokai) No. 2005-353606 discloses a spark plug including a noble metal tip which is formed of a material containing Pt and Rh, Ir, Ni, Pd, or the like, and which exhibits improved erosion resistance. Meanwhile, Japanese Patent Application Laid-Open (kokai) No. 2004-165165 discloses a spark plug characterized by including an electrode having an electrode segment located at one end segment of the electrode, the electrode segment including an alloy containing copper, which spark plug can be produced at low cost, wherein only minimal thermomechanical stresses occur between the electrode segment and an electrode base body.
In addition, there have been disclosed many spark plugs in which a tip formed of a noble metal alloy is provided on a center electrode and/or a ground electrode.
However, hitherto known tips formed of noble metal alloys have both advantages and disadvantages, and a spark plug satisfying all performance criteria has not yet been provided. For example, a noble metal tip formed of a Pt—Rh alloy or a Pt—Ir alloy exhibits particularly good spark erosion resistance, but the noble metal tip exhibits poor breakage resistance and poor resistance against separation of the tip from an electrode matrix when used in a combustion chamber (i.e., under high-temperature environmental conditions and cooling cycle conditions). Meanwhile, a noble metal tip formed of a Pt—Ni alloy exhibits particularly good separation resistance, but poor spark erosion resistance.
In order to solve the aforementioned problems, an object of the present invention is to provide a spark plug including a noble metal tip exhibiting intended durability. Specifically, an object of the present invention is to provide a spark plug including a noble metal tip exhibiting excellent erosion resistance, separation resistance, and breakage resistance.
Means for solving the aforementioned problems is (I) a spark plug comprising a center electrode; a ground electrode provided so as to form a gap between the ground electrode and the center electrode; and a noble metal tip provided on at least one of the center electrode and the ground electrode, characterized in that the noble metal tip contains Mp (Mp is an element group consisting of Pt or Pt and Pd, and the amount of Pd is 20 mass % or less with respect to the mass of the noble metal tip), Cu, and M (M is at least one element selected from the element group consisting of Rh, Ir, Ru, Re, and W) in a total amount of 95 mass % or more; and the proportions by mass of Mp, Cu, and M (Mp, Cu, M) in a Mp-Cu-M ternary composition diagram fall within a region defined by a line connecting point D (95, 5, 0), point E (94.5, 5, 0.5), point F (87, 5, 8), point G (80, 12, 8), point H (79.5, 20, 0.5), point I (80, 20, 0), and point D (95, 5, 0) in this order (the region including the line).
A preferred mode of (I) above is characterized in that (II) the proportions by mass (Mp, Cu, M) in the noble metal tip in the Mp-Cu-M ternary composition diagram fall within a region defined by a line connecting point E (94.5, 5, 0.5), point F (87, 5, 8), point G (80, 12, 8), point H (79.5, 20, 0.5), and point E (94.5, 5, 0.5) in this order (the region including the line); or characterized by (III) a spark plug comprising an insulator having an axial hole; a center electrode provided in the axial hole; a ground electrode provided so as to form a gap between the ground electrode and the center electrode; and a noble metal tip provided on at least one of the center electrode and the ground electrode, wherein welding area S (mm2), tip protrusion height H (mm), covering length L (mm), and the distance between the tip and a welded portion (hereinafter may be referred to as “tip-welded portion distance”) h (mm) satisfy the following relations: (a) H≦0.13S+1.18, (b) S≦5, and (c) 0.1≦h or 0.03≦L, wherein
welding area S is defined as being the area of a region in which, when the noble metal tip is provided on an end surface or a peripheral side surface of the center electrode and/or the ground electrode, as viewed in a direction X—which is a direction perpendicular to a bonding surface of a mounting metallic body (the body corresponding to the center electrode, the ground electrode, or a base provided between each of these electrodes and the noble metal tip) to which the noble metal tip is bonded via a welded portion formed through fusion between the noble metal tip and the mounting metallic body, a projection region formed by projection of the mounting metallic body on a surface perpendicular to the direction X overlaps a projection region formed by projection of the noble metal tip on a surface perpendicular to the direction X (when the noble metal tip is bonded to the mounting metallic body via a plurality of surfaces of the mounting metallic body, welding area S is defined as being the total area of regions in which, as viewed in directions Y—which are perpendicular to the surfaces, the surfaces overlap one another);
tip protrusion height H is defined as being the distance between the bonding surface of the mounting metallic body and the end surface of the noble metal tip most distal from the bonding surface, the distance being determined in a direction in which the noble metal tip faces a facing metallic protrusion (the protrusion corresponding to the noble metal tip, a portion protruded from the front end of the center electrode, or portion protruded from the distal end of the ground electrode) (when the welded portion is provided between the noble metal tip and the mounting metallic body so as to cover the entire top surface of the mounting metallic body, tip protrusion height H is defined as being the distance between a point corresponding to ½ the thickness of the thinnest portion of the welded portion in a direction of an axis PX of the noble metal tip, and the surface of the noble metal tip most distal from the point in the direction of the axis PX); and
covering length L and tip-welded portion distance h are defined as follows: in the case where the axial hole extends in a direction of an axis AX of the center electrode,
(1) when the noble metal tip and the facing metallic protrusion are arranged so as to face each other in the direction of the axis AX, and the noble metal tip does not project from the mounting metallic body in a direction perpendicular to the axis AX, covering length L is defined as being the minimum distance, as viewed in the direction of the axis AX, between a straight line group which includes a point k1 on a peripheral side surface corresponding to the maximum diameter of the noble metal tip and which is parallel to the axis AX, and a straight line group which includes a point k2 on a peripheral side surface corresponding to the maximum diameter of the facing metallic protrusion and which is parallel to the axis AX; and tip-welded portion distance h is defined as being the distance in the direction of the axis AX as measured, on a surface of the noble metal tip which includes the point k1 and is parallel to the axis AX, from the end of the noble metal tip to the boundary between the tip and the welded portion; or
(2) when the noble metal tip projects from the ground electrode in a direction perpendicular to the axis AX, and the front end surface of the facing metallic protrusion faces the noble metal tip in the direction of the axis AX, covering length L is defined as being the minimum distance, as viewed in the direction of the axis AX, between a point k3 on a projection region formed by projection of the front end surface of the facing metallic protrusion on a virtual surface perpendicular to the direction of the axis AX, and an intersection point k4 provided by intersection of the contour of a projection region formed by projection of the ground electrode on the virtual surface with the contour of a projection region formed by projection of the noble metal tip on the virtual surface; and
(i) in the noble metal tip, tip-welded portion distance h is defined as being the distance as measured, on a surface of the noble metal tip which includes the point k4 and is parallel to the axis AX, from the end of the noble metal tip to the boundary between the tip and the welded portion; or
(ii) when the facing metallic protrusion is the noble metal tip provided on the center electrode, tip-welded portion distance h is defined as being the distance in the direction of the axis AX as measured, on a surface of the noble metal tip which includes the point k3 and is parallel to the axis AX, from the end of the noble metal tip to the boundary between the tip and the welded portion.
Another means for solving the aforementioned problems is (IV) a spark plug comprising an insulator having an axial hole; a center electrode provided in the axial hole; a ground electrode provided so as to form a gap between the ground electrode and the center electrode; and a noble metal tip provided on at least one of the center electrode and the ground electrode, characterized in that the noble metal tip contains Mp (Mp is an element group consisting of Pt or Pt and Pd, and the amount of Pd is 20 mass % or less with respect to the mass of the noble metal tip), Cu, and M (M is at least one element selected from the element group consisting of Rh, Ir, Ru, Re, and W) in a total amount of 95 mass % or more; the proportions by mass of Mp, Cu, and M (Mp, Cu, M) fall within a region defined by a line connecting point A (97, 3, 0), point B (80, 3, 17), point C (75, 25, 0), and point A (97, 3, 0) in this order (the region including the line); and welding area S (mm2), tip protrusion height H (mm), covering length L (mm), and tip-welded portion distance h (mm), which are defined above in (III), satisfy the following relations: (a) H≦0.13S+1.18, (b) S≦5, and (c) 0.1≦h or 0.03≦L.
A preferred mode of (I) or (IV) above is characterized in that (V) Mp is Pt and Pd; (VI) the noble metal tip contains at least one element selected from the element group A consisting of Ni, Co, Fe, and Mn, and/or the element group B consisting of Ti, Hf, Y, and rare earth elements, the total mass of the element group A is 5 mass % or less, the total mass of the element group B is 1.5 mass % or less, and the total mass of the element group A and the element group B is 5 mass % or less; (VII) M is Rh; (VIII) the noble metal tip has a hardness of 140 Hv or more; (VIIII) the noble metal tip has a hardness of 200 Hv or more; (X) the center electrode is fixed in the axial hole of the insulator so as to be exposed through one end of the axial hole, a terminal shell is fixed in the axial hole so as to be exposed through the other end of the axial hole, a resistor is provided between the center electrode and the terminal shell in the axial hole, and the resistor has a resistance of 10 kΩ or less; or (XI) the noble metal tip is provided only on the ground electrode.
According to the spark plug described above in (I), the noble metal tip provided on at least one of the center electrode and the ground electrode contains Mp, Cu, and M in a total amount of 95 mass % or more, and the proportions by mass of Mp, Cu, and M fall within specific ranges. Therefore, the noble metal tip of the spark plug exhibits excellent durability; in particular, excellent erosion resistance, separation resistance, and breakage resistance.
According to the spark plug described above in (IV), the noble metal tip provided on at least one of the center electrode and the ground electrode contains Mp, Cu, and M in a total amount of 95 mass % or more; the proportions by mass of Mp, Cu, and M fall within specific ranges; and the noble metal tip has specific dimensions. Therefore, the noble metal tip of the spark plug exhibits excellent durability; in particular, excellent erosion resistance, separation resistance, and breakage resistance.
When the noble metal tip further contains at least one element selected from the element group A consisting of Ni, Co, Fe, and Mn, and/or the element group B consisting of Ti, Hf, Y, and rare earth elements in a specific amount, the spark plug is further excellent in terms of at least one of separation resistance and tip breakage resistance.
When the hardness of the noble metal tip is equal to or higher than a specific level, the noble metal tip exhibits further excellent impact resistance. Thus, even when the noble metal tip comes into contact with and is impacted by a jig during a production process, deformation of the noble metal tip can be suppressed.
Even when the resistor of the spark plug has a resistance of 10 kΩ or less, and high energy is applied to a spark discharge gap during spark discharge, since the noble metal tip exhibits excellent erosion resistance, etc., the spark plug can maintain its performance.
In addition, when the noble metal tip is provided on the ground electrode, which is exposed to high temperature and severe environmental conditions, as compared with the case of the center electrode, more effective performance is achieved.
These and other features and advantages of the present invention will become more readily appreciated when considered in connection with the following detailed description and appended drawings, wherein like designations denote like elements in the various views, and wherein:
shows a position at which the hardness of a noble metal tip of a spark plug is measured.
a) is a cross-sectional view of an ignition portion of one embodiment of the spark plug of the present invention. FIG. 4(b) shows a main portion of a ground electrode as viewed in a direction X shown in
a) is a cross-sectional view of an ignition portion of another embodiment of the spark plug of the present invention.
b) shows a main portion of a ground electrode as viewed in a direction X2 shown in
a) is a cross-sectional view of an ignition portion of yet another embodiment of the spark plug of the present invention.
a) is a cross-sectional view of an ignition portion of yet another embodiment of the spark plug of the present invention.
b) shows a main portion of a ground electrode as viewed in a direction X4 shown in
a) is a cross-sectional view of an ignition portion of yet another embodiment of the spark plug of the present invention.
b
1) shows a main portion of a ground electrode as viewed in a direction Y1 shown in
b
2) shows the main portion of the ground electrode as viewed in a direction Y2 shown in
b
3) shows the main portion of the ground electrode as viewed in a direction Y3 shown in
a) is a cross-sectional view of an ignition portion of yet another embodiment of the spark plug of the present invention.
b) shows a main portion of a ground electrode as viewed in a direction X6 shown in
a) to 11(d) are representations illustrating a test for evaluating the separation resistance of a noble metal tip provided in a spark plug.
The spark plug of the first invention includes a center electrode and a ground electrode, wherein one end of the center electrode faces one end of the ground electrode via a gap, and a noble metal tip is provided on at least one of the center electrode and the ground electrode. No particular limitation is imposed on the configuration of a portion other than a main portion of the spark plug of the first invention, so long as the main portion of the spark plug has the aforementioned configuration. That is, the portion other than the main portion may have any known configuration.
As shown in
The metallic shell 2 has a generally circular columnar shape, and is formed so as to hold the insulator 3 provided therein. The metallic shell 2 has a threaded portion 10 on an outer peripheral surface on the front end side. By means of the threaded portion 10, the spark plug 1 is attached to a non-illustrated cylinder head of an internal combustion engine. The metallic shell 2 may be formed of an electrically conductive steel material such as low-carbon steel.
The insulator 3 is held by the inner wall of the metallic shell 2 via, for example, talc 11 or packing 12, and the center electrode 4, the resistor 5, and the terminal shell 6 are held in the axial hole 20 of the insulator 3. The insulator 3 is fixed to the metallic shell 2 such that the front end portion of the insulator 3 projects from the front end surface of the insulator 2. The insulator 3 is preferably formed of a material exhibiting, for example, mechanical strength, thermal strength, and electrical strength. Examples of such a material include a sintered ceramic material mainly containing alumina.
The center electrode 4 is formed of an outer member 13, and an inner member 14 which is concentrically buried in an axial core portion of the outer member 13. The center electrode 4 is fixed in the axial hole 20 of the insulator 3 such that the front end portion of the electrode 4 projects from the front end surface of the insulator 3, and the center electrode 4 is insulated from the metallic shell 2. The outer member 13 is preferably formed of a material exhibiting, for example, thermal conductivity and mechanical strength, such as an Ni-based alloy (e.g., Inconel (trade name)). The inner member 14 may be formed of a metal material exhibiting excellent thermal conductivity, such as Cu or Ag.
The shape and structure of the ground electrode 7 are designed such that, for example, the electrode 7 has a generally rectangular columnar shape; one end of the electrode 7 is bonded to the front end surface of the metallic shell 2; the electrode 7 is bent in a generally L-shape at a middle portion thereof; and the distal end portion of the electrode 7 is located on the front end side of the axis AX of the center electrode 4. With this design, one end of the ground electrode 7 faces the center electrode 4 via a gap. The ground electrode 7 is formed of a material similar to that forms the center electrode 4.
The terminal shell 6 is fixed in the axial hole 20 of the insulator 3 such that the rear end portion of the shell 6 projects from the rear end surface of the insulator 3, and the terminal shell 6 is insulated from the metallic shell 2. The terminal shell 6 is formed of, for example, low-carbon steel, and an Ni metal layer is formed on the surface of the shell 6 through plating or a similar technique.
The resistor 5 is fixed between the center electrode 4 and the terminal shell 6 in the axial hole 20 of the insulator 3. The resistor 5 may be formed of glass powder, ceramic powder, non-metallic electrically conductive powder, and/or a mixture of metal powder, etc. The resistor 5 generally has a resistance of 15 kΩ or less. When the resistance is 10 kΩ or less, particularly, the energy applied to the spark discharge gap G increases during spark discharge, and thus spark erosion occurs considerably. Therefore, when the resistor 5 has a resistance of 10 kΩ or less, the noble metal tip formed of the below-described tip material further exhibits its effects.
The ground electrode tip 8 has, for example, a circular columnar shape, and is provided at the distal end portion of the ground electrode 7 such that the tip 8 faces the center electrode tip 9 provided on the front end surface of the center electrode 4. The ground electrode tip 8 may be formed of the below-described tip material, or any known material other than the tip material. However, the ground electrode tip 8 is preferably formed of the below-described tip material, since the ground electrode tip 8 is generally exposed to a higher temperature, as compared with the center electrode tip 9.
The center electrode tip 9 has, for example, a circular columnar shape, and is provided on the front end surface of the center electrode 4. The center electrode tip 9 is formed of the below-described tip material, or any known material other than the tip material.
The ground electrode tip 8 and the center electrode tip 9 are provided so as to face each other via the gap (i.e., the spark discharge gap G). In the spark plug 1 of the first invention, the noble metal chip 8 or 9 may be provided on at least one of the center electrode 4 and the ground electrode 7. When, for example, the noble metal tip 8 is provided only on the ground electrode 7, the spark discharge gap corresponds to a gap between the center electrode 4 and the ground electrode tip 8. The spark discharge gap is generally adjusted to 0.3 to 1.5 mm.
In the spark plug 1, at least one of the ground electrode tip 8 and the center electrode tip 9 is formed of the below-described tip material. Preferably, the ground electrode tip 8, which is heated to a higher temperature, is formed of the below-described tip material.
The tip material forming each of these noble metal tips contains Mp (Mp is an element group consisting of Pt or Pt and Pd, and the amount of Pd is 20 mass % or less with respect to the mass of the noble metal tip), Cu, and M (M is at least one element selected from the element group consisting of Rh, Ir, Ru, Re, and W) in a total amount of 95 mass % or more, wherein the proportions by mass of Mp, Cu, and M (Mp, Cu, M) in the Mp-Cu-M ternary composition diagram shown in
When the tip material contains Mp, Cu, and M in an amount of 95 mass % or more, and, the proportions by mass of the three components (Mp, Cu, M) in the Mp-Cu-M ternary composition diagram fall within a region defined by a line connecting points D, E, F, G, H, I, and D in this order (the region includes the line), the noble metal tip of the spark plug exhibits excellent erosion resistance, separation resistance, and breakage resistance.
In the aforementioned tip material, preferably, the proportions by mass of the three components (Mp, Cu, M) in the ternary composition diagram fall within a region defined by a line connecting point E (94.5, 5, 0.5), point F (87, 5, 8), point G (80, 12, 8), point H (79.5, 20, 0.5), and point E (94.5, 5, 0.5) in this order (the region includes the line).
When the amount of Cu is 5 mass % or more in the ternary composition diagram, the tip material exhibits excellent separation resistance, as compared with the case of a Pt—Rh alloy or a Pt—Ir alloy, since the difference in thermal expansion coefficient decreases between the tip material and an Ni-based alloy employed as a material for forming the center electrode or the ground electrode. Since the tip material can suppress lowering of melting point, as compared with a Pt—Ni alloy, which is known as a material for effectively improving separation resistance, the tip material exhibits excellent spark erosion resistance, as well as excellent separation resistance. In addition, in the tip material, crystal grain size is less likely to increase, as compared with the case of a Pt—Rh alloy, in which crystal grain size tends to increase. Since internal oxidation is suppressed in the tip material, as compared with the case of a Pt—Ir alloy, the tip material exhibits excellent breakage resistance.
When the amount of Cu is less than 5 mass % in the ternary composition diagram, the aforementioned effects may fail to be attained. When the amount of Cu exceeds 25 mass % in the ternary composition diagram; i.e., when the amount of Cu, which is easily oxidized, increases, oxidation resistance may be lowered, and internal oxidation may occur in crystal grain boundaries, resulting in breakage or separation of the tip. In addition, such a problem may cause impairment of thermal conductivity, which may adversely affect erosion resistance.
When the tip material contains M (particularly when the amount of M is 0.5 mass % or more in the ternary composition diagram), the tip material exhibits excellent spark erosion resistance, since M has a high melting point. Also, since crystal grain size decreases, falling of crystal grains, which is caused by breakage in the tip, can be suppressed. In addition, since the tip material exhibits high strength, even when it comes into contact with and is impacted by a jig during a production process, deformation of the noble metal tip can be suppressed. Thus, the tip material exhibits excellent impact resistance.
However, when the amount of M exceeds 8 mass % in the ternary composition diagram, embrittlement may occur, and thus proccessability is impaired, and breakage of the tip, which is caused by thermal stress or internal corrosion, is likely to occur. Since M has a low thermal expansion coefficient, when a large amount of M is incorporated, the difference in thermal expansion coefficient increases between the tip material and an Ni-based alloy employed as an electrode material, which adversely affects separation resistance. Therefore, the amount of M is 8 mass % or less in the ternary composition diagram.
The effects of Cu and M in the tip material have been described above. Needless to say, the tip material is greatly affected not only by the proportion by mass of a single component, but also by the proportions by mass of three components (Mp, Cu, M). When the total amount of Cu and M contained in the tip material is equal to or greater than a specific level; i.e., when the proportions by mass of Cu and M exceed levels corresponding to line GH in the ternary composition diagram, at least one of separation resistance, erosion resistance, and tip breakage resistance is deteriorated. Therefore, the proportions by mass of Cu and M are equal to or lower than levels corresponding to line GH in the ternary composition diagram.
M is at least one element selected from the element group consisting of Rh, Ir, Ru, Re, and W. Each of Rh, Ir, Ru, Re, and W has a high melting point, and is difficult to sputter. When Pt is employed in combination with each of these elements, strength is improved, and crystal grain size can be reduced. Therefore, when the amount of at least one element selected from the element group falls within a region shown in the ternary composition diagram, the noble metal tip of the spark plug exhibits excellent separation resistance, erosion resistance, and breakage resistance. Among the elements of this group, Rh is particularly preferred, since Rh itself is oxidized to form a dense oxide film, whereby further oxidation thereof can be suppressed.
Mp is an element group consisting of Pt or Pt and Pd, and the amount of Pd is 20 mass % or less with respect to the mass of the noble metal tip. Pt is preferably employed as a main component of the tip material, since it exhibits excellent oxidation resistance, spark erosion resistance, and proccessability. Incorporation of a specific amount of Pd is advantageous in terms of separation resistance, since Pd exhibits excellent oxidation resistance similar to the case of Pt, and has a thermal expansion coefficient greater than that of Pt. Therefore, when the amount of Pd is 20 mass % or less with respect to the entire mass of the noble metal tip formed of the tip material, the noble metal tip of the spark plug exhibits further excellent separation resistance. However, when the amount of Pd exceeds 20 mass %, the melting point of the tip material is lowered, resulting in impairment of erosion resistance.
Preferably, the tip material contains at least one element selected from the element group A consisting of Ni, Co, Fe, and Mn, and/or the element group B consisting of Ti, Hf, Y, and rare earth elements; the total mass of the element group A is 5 mass % or less with respect to the entire mass of the noble metal tip formed of the tip material; the total mass of the element group B is 1.5 mass % or less with respect to the entire mass of the noble metal tip formed of the tip material; and the total mass of the element group A and the element group B is less than 5 mass % with respect to the entire mass of the noble metal tip formed of the tip material.
When the total mass of the element group A is more than 0 mass % and 5 mass % or less in the tip material, the tip material exhibits further excellent separation resistance and breakage resistance. Since the element group A has a high thermal expansion coefficient, the difference in thermal expansion coefficient decreases between the tip material and an electrode material, and generation of thermal stress can be suppressed. In addition, since crystal grain size is reduced, the breakage resistance of the tip material is effectively improved.
When the total mass of the element group B is more than 0 mass % and 1.5 mass % or less (particularly 0.01 mass % to 1 mass %) in the tip material, since crystal grain size is reduced, the tip material exhibits excellent breakage resistance.
When the amount of the element group A or the element group B is excessively large in the tip material, the melting point of the tip material may be lowered, resulting in poor erosion resistance. Therefore, the total mass of the element group A and the element group B is preferably 5 mass % or less with respect to the mass of the noble metal tip.
The tip material contains Mp, Cu, and M in a total amount of 95 mass % or more, and substantially contains the element group A consisting of Ni, Co, Fe, and Mn, and the element group B consisting of Ti, Hf, Y, and rare earth elements, as desired. The tip material contains these components such that the amounts of the components fall within the aforementioned ranges, and the total amount of these components and an inevitable impurity is 100 mass %. The tip material may contain a very small amount of a component other than the aforementioned components; i.e., an inevitable impurity such as Ag, B, Ca, Al, Si, or Mg. Preferably, the amount of such an inevitable impurity is reduced to a minimum possible level. However, the tip material may contain such an impurity, so long as the object of the present invention can be achieved. Preferably, the amount of any one of the aforementioned inevitable impurities is 0.1 parts by mass or less, and the total amount of all the inevitable impurities contained in the tip material is 0.2 parts by mass or less, on the basis of 100 parts by mass of the total mass of the aforementioned components.
The amount of each component contained in the noble metal tip formed of the aforementioned tip material may be determined as follows. Specifically, the noble metal chip 8 or 9 is subjected to cutting, and a cross section thereof is exposed. By means of EPMA, WDS (wavelength dispersive X-ray spectrometer) analysis is performed on a plurality of points (e.g., five points) of the cross section of the noble metal tip 8 or 9, to thereby determine the mass composition of each point. Subsequently, the values as determined at the points are averaged, and the thus-obtained average value is regarded as the composition of the noble metal tip. Notably, measurement is not carried out on a welded portion 15, which is formed when the noble metal tip 8 or 9 is fusion-bonded to the center electrode 4, the ground electrode 7, and/or a mounting metallic body (e.g., a base).
The tip material is produced through the below-described method by mixing specific raw materials in specific proportions. The composition of the thus-produced tip material generally corresponds to that of the raw materials. Therefore, the amount of each component contained in the tip material may be conveniently calculated on the basis of the proportions of the raw materials incorporated.
The noble metal tip formed of the aforementioned tip material preferably has a hardness of 140 Hv or more, particularly preferably 200 Hv or more.
In the case where the hardness of the noble metal tip falls within the above range, even when the tip comes into contact with a jig during a production process, deformation of the noble metal tip can be prevented.
The hardness of the noble metal tip is measured as follows. As shown in
The hardness of the noble metal tip may be adjusted by varying, for example, the composition of the tip material, the processing conditions for producing the noble metal tip, the thermal treatment temperature and time before and after this processing, the thermal load during welding of the noble metal tip to the ground electrode or the center electrode, the amount of deformation of the noble metal tip (in the case of resistance welding), or the thermal treatment conditions for bonding of the resistor, the insulator, the metallic terminal, and the center electrode (in the case where the noble metal tip is provided on the center electrode). Specifically, processing strain is increased by increasing the percent processing during production of the noble metal tip, lowering the thermal treatment temperature or shortening the thermal treatment time after processing, lowering the temperature for welding of the noble metal tip to the ground electrode or the center electrode or shortening the welding time, and/or increasing the amount of deformation of the noble metal tip (in the case of resistance welding), whereby high deformation resistance is achieved, resulting in high hardness.
When the noble metal tip of the spark plug of the first invention, which is formed of the aforementioned tip material, has the below-described dimensions, the noble metal tip of the spark plug exhibits further excellent erosion resistance, breakage resistance, and separation resistance.
Preferably, the below-defined welding area S (mm2), tip protrusion height H (mm), covering length L (mm), and tip-welded portion distance h (mm) satisfy the following relations: (a) H≦0.13S+1.18, (b) S≦5, and (c) 0.1≦h or 0.03≦L.
In the noble metal tip, preferably, the below-defined tip cross-sectional area A (mm2) satisfies the following relation: (d) 0.2≦A≦1.8.
When, in the noble metal tip, welding area S and tip protrusion height H satisfy the following relation: (a) H≦0.13S+1.18, the noble metal tip of the spark plug exhibits further excellent erosion resistance. In order to improve the erosion resistance of the noble metal tip, preferably, the heat dissipation of the noble metal tip is increased. Hitherto, it has been considered that when welding area S is small, the contact area between the noble metal tip and the electrode is reduced, and thus heat received by the noble metal tip is less likely to be transferred to the electrode, resulting in poor heat dissipation. However, the present inventors have found that heat dissipation is affected not only by welding area S, but also by tip protrusion height H. That is, even in the case where welding area S is small, when tip protrusion height H is smaller than a specific value, overheating of the noble metal tip can be suppressed, and favorable erosion resistance is achieved. Conversely, even in the case where tip protrusion height H is large, when welding area S is large, favorable heat dissipation is achieved, and thus overheating of the noble metal tip can be suppressed.
When, in the noble metal tip, welding area S, covering length L, and tip-welded portion distance h satisfy the following relations: (b) S≦5 and (c) 0.1≦h or 0.03≦L, the noble metal tip of the spark plug exhibits further excellent separation resistance. When welding area S is large, high thermal stress is generated particularly in an outer peripheral portion of the noble metal tip due to the difference in thermal expansion coefficient between the tip material forming the noble metal tip and the material forming the electrode, and thus the noble metal tip is likely to be detached from the electrode. Therefore, welding area S is preferably 5 or less. Since highly turbulent airflow occurs in a combustion chamber, when covering length L and tip-welded portion distance h fall outside the above ranges, discharge is likely to occur at a portion of the electrode in the vicinity of the outer periphery of the noble metal tip and/or at the welded portion. Since the electrode or the welded portion has a melting point lower than that of the noble metal tip, the electrode or the welded portion is easily eroded, and the boundary between the noble metal tip and the electrode or the welded portion is hollowed, resulting in poor separation resistance. In addition, when the electrode or the welded portion is eroded, welding area S is substantially reduced, which adversely affects erosion resistance. Therefore, tip-welded portion distance h is preferably 0.1 or more, or covering length L is preferably 0.03 or more.
In the noble metal tip, tip cross-sectional area A preferably satisfies the following relation: (d) 0.2≦A≦1.8. When tip cross-sectional are A falls within the above range, further excellent erosion resistance is achieved.
a) is a cross-sectional view of an ignition portion of one embodiment of the spark plug of the first invention.
The welding area Sg1 is determined as follows. Specifically, the ground electrode 7 is photographed from above in the direction X, and the area of a region defined by a boundary line 17 between the ground electrode tip 8 and the welded portion 15 is calculated by means of image analysis software (e.g., Photoshop). Also, the welding area Sc1 may be determined in a manner similar to that described above.
When the tip protrusion height of the ground electrode tip 8 of the spark plug 1 of this embodiment is represented by Hg1, the tip protrusion height Hg1 is the distance between the bonding surface 16 of the ground electrode 7 and the end surface of the ground electrode tip 8 most distal from the bonding surface 16, the distance being determined in a direction in which the ground electrode tip 8 faces the center electrode tip 9 (which may be referred to as “facing metallic protrusion”). Also, the tip protrusion height Hc1 of the center electrode tip 9 is defined in a manner similar to that of the tip protrusion height Hg1 of the ground electrode tip 8.
When the covering length in the spark plug 1 of this embodiment is represented by L1, the covering length L1 is defined as described below, since the axial hole 20 of the insulator 3 extends in the direction of the axis AX of the center electrode 4; the ground electrode tip 8 and the center electrode tip 9 are arranged so as to face each other in the direction of the axis AX; and the ground electrode tip 8 does not project from the ground electrode 7 in a direction perpendicular to the axis AX. Specifically, the covering length L1 is the minimum distance, as viewed in the direction of the axis AX, between a straight line group Ig1 which includes a point k1 on a peripheral side surface corresponding to the maximum diameter of the ground electrode tip 8 and which is parallel to the axis AX, and a straight line group Ic1 which includes a point k2 on a peripheral side surface corresponding to the maximum diameter of the center electrode tip 9 and which is parallel to the axis AX.
When the tip-welded portion distance of the ground electrode tip 8 of the spark plug 1 of this embodiment is represented by hg1, the tip-welded portion distance hg1 is the distance in the direction of the axis AX as measured, on a surface of the ground electrode tip 8 which includes the point k1 and is parallel to the axis AX, from the end of the ground electrode tip 8 to the boundary between the tip 8 and the welded portion 15. Also, the tip-welded portion distance hc1 of the center electrode tip 9 is defined in a manner similar to that of the tip-welded portion distance hg1 of the ground electrode tip 8.
When the tip cross-sectional area of the ground electrode tip 8 of the spark plug 1 of this embodiment is represented by Ag1, and the tip cross-sectional area of the center electrode tip 9 is represented by Ac1, as shown in
In the case where the aforementioned noble metal tip is provided on at least one of the center electrode and the ground electrode of the spark plug (particularly on the ground electrode), even when the spark plug of the first invention is employed under severe environmental conditions (e.g., an internal combustion engine having a supercharger, or an internal combustion engine employing a high-energy coil), the spark plug can maintain its intended performance, since the noble metal tip exhibits excellent erosion resistance, breakage resistance, and separation resistance.
The spark plug 1 is produced through, for example, the following procedure. The noble metal tip 8 or 9 may be produced through, for example, a process in which a tip material is prepared by mixing components so that the proportions thereof fall within the aforementioned ranges; the material is melted, and the molten material is processed into a plate material through hot rolling or a similar technique; and the plate material is formed into tips having a specific shape through hot punching; or a process in which an alloy is processed into a wire-like or rod-like material through hot rolling, hot casting, or hot wire drawing, and the thus-processed material is longitudinally cut into tips having a specific length.
The center electrode 4 and/or the ground electrode 7 may be produced through, for example, the following process: a molten alloy having an intended composition is prepared by means of a vacuum melting furnace; a cast ingot is prepared from the molten alloy through vacuum casting; and the cast ingot is appropriately processed to have specific shape and dimensions through, for example, hot working or wire drawing. The center electrode 4 may be formed by inserting the inner member 14 into the outer member 13 formed to have a cup shape, followed by a plastic working process such as extrusion. When the ground electrode 7 is formed of an outer layer and an axial member provided in a core portion of the outer layer (not illustrated), the axial member is inserted into the outer layer having a cup shape, and then the resultant product is subjected to a plastic working process (e.g., extrusion), followed by plastic working for forming the product into a generally rectangular columnar shape.
Subsequently, one end portion of the ground electrode 7 is bonded, through electric resistance welding, laser welding, or a similar technique, to the end surface of the metallic shell 2 formed to have a specific shape through, for example, plastic working. The metallic shell having the ground electrode bonded thereto is subjected to Zn plating or Ni plating. Trivalent chromate treatment may be carried out after Zn plating or Ni plating.
Next, the above-produced noble metal tip 8 or 9 is fusion-bonded to the ground electrode 7 or the center electrode 4 through, for example, resistance welding and/or laser welding. When the noble metal tip 8 or 9 is bonded to the ground electrode 7 and/or the center electrode 4 through resistance welding, for example, the noble metal tip 8 or 9 is placed on a specific position of the ground electrode 7 and/or the center electrode 4, and resistance welding is carried out while the noble metal tip is pressed onto the specific position. When the noble metal tip 8 or 9 is bonded to the ground electrode 7 and/or the center electrode 4 through laser welding, for example, the noble metal tip 8 or 9 is placed on a specific position of the ground electrode 7 and/or the center electrode 4, and a laser beam is radiated in an obliquely downward direction with respect to the noble metal tip 8 so that the laser beam is applied to a portion or the entirety of the contact portion between the noble metal tip 8 or 9 and the ground electrode 7 and/or the center electrode 4. Laser welding may be carried out after resistance welding.
Separately, the insulator 3 having a specific shape is formed through firing of, for example, a ceramic material. The center electrode 4 having the noble metal tip 9 bonded thereto is inserted into the axial hole 20 of the insulator 3, and glass powder for forming a glass seal, a resistor composition for forming the resistor 5, and the aforementioned glass powder are sequentially charged into the axial hole 20 under preliminary compression. Subsequently, while the metallic terminal 6 is pressed into the axial hole 20 through its end, the resistor composition and the glass powder are pressure-heated. Thus, the resistor composition and the glass powder are sintered, to thereby form the resistor 5 and a glass seal layer. Next, the insulator 3 having the center electrode 4, etc. fixed thereto is assembled into the metallic shell 2 having the ground electrode 7 bonded thereto. Finally, the distal end portion of the ground electrode 7 is bent toward the center electrode 4 such that one end of the ground electrode 7 faces the front end portion of the center electrode 4, to thereby produce the spark plug 1.
The spark plug 201 of this embodiment has the same configuration as the spark plug 1 shown in
Therefore, in the ground electrode tip 208 of the spark plug 201 of this embodiment, a welding area Sg2, a tip protrusion height Hg2, a covering length L2, a tip-welded portion distance hg2, and a tip cross-sectional area Ag2 are defined in a manner similar to the case of the spark plug 1. Since the center electrode 204 is not provided with a noble metal tip 209, welding area, tip protrusion height, tip-welded portion distance, and tip cross-sectional area are not defined in the center electrode 204.
The spark plug 301 of this embodiment has the same configuration as the spark plug 1 shown in
Therefore, in the ground electrode tip 308 of the spark plug 301 of this embodiment, a welding area Sg3, a covering length L3, a tip-welded portion distance hg3, and a tip cross-sectional area Ag3 are defined in a manner similar to the case of the spark plug 1. Also, in the center electrode tip 309, a welding area Sc3, a tip protrusion height Hc3, a tip-welded portion distance hc3, and a tip cross-sectional area Ac3 are defined in a manner similar to the case of the spark plug 1.
In the spark plug 301 of this embodiment, since the welded portion 315 is provided between the ground electrode tip 308 and the base 318 so as to cover the entire top surface of the base 318, the ground electrode tip 308 is not in direct contact with the base 318. Therefore, the tip protrusion height Hg3 is the distance between a point corresponding to ½ the thickness of the thinnest portion of the welded portion 315 in a direction of an axis PX3 of the ground electrode tip 308, and the end surface of the ground electrode tip 308 most distal from the point in the direction of the axis PX3.
The spark plug 401 of this embodiment has the same configuration as the spark plug 301 shown in
Therefore, in the ground electrode tip 408 of the spark plug 401 of this embodiment, a welding area Sg4, a covering length L4, a tip-welded portion distance hg4, and a tip cross-sectional area Ag4 are defined in a manner similar to the case of the spark plug 1. Also, in the center electrode tip 409, a welding area Sc4, a tip protrusion height Hc4, a tip-welded portion distance hc4, and a tip cross-sectional area Ac4 are defined in a manner similar to the case of the spark plug 1.
In the spark plug 401 of this embodiment, since the welded portion 415 is provided between the ground electrode tip 408 and the base 418 so as not to cover the entire top surface of the base 418, the tip protrusion height Hg4 is the distance between a bonding surface 416 of the base 418 to which the ground electrode tip 408 is bonded, and the surface of the ground electrode tip 408 most distal from the bonding surface 416, the distance being determined in a direction in which the ground electrode tip 408 faces the center electrode tip 409.
The spark plug 501 of this embodiment has the same configuration as the spark plug 1 shown in
Therefore, in the center electrode tip 509 of the spark plug 501 of this embodiment, a welding area Sc5, a tip protrusion height Hc5, a tip-welded portion distance hc5, and a tip cross-sectional area Ac5 are defined in a manner similar to the case of the spark plug 1.
In the spark plug 501 of this embodiment, since four of the six surfaces of the rectangular columnar ground electrode tip 508 are bonded to the four surfaces of the notch 519 of the ground electrode 507, the welding area Sg5 of the ground electrode tip 508 is the total of areas Sg51, Sg52, Sg53, and Sg54 (i.e., Sg51+Sg52, Sg53+Sg54), which are the areas of regions wherein, as viewed in directions Y1, Y2, Y3, and Y4 which are perpendicular to the four surfaces of the notch 519, projection regions Pg51, Pg52, Pg53, and Pg54 formed by projection of the ground electrode 507 on surfaces perpendicular to the directions Y1, Y2, Y3, and Y4 overlap projection regions Pt51, Pt52, Pt53, and Pt54 formed by projection of the ground electrode tip 508 on surfaces perpendicular to the directions Y1, Y2, Y3, and Y4 (see
The tip protrusion height Hg5 is the distance between a bonding surface 516 of the ground electrode 507 and the end surface of the ground electrode tip 508 most distal from the bonding surface 516, the distance being determined in a direction in which the ground electrode tip 508 faces the center electrode tip 509. The bonding surface 516 is the surface (exclusive of a portion on which the notch 519 is provided) of the ground electrode 507 in a direction in which the ground electrode tip 508 faces the center electrode tip 509.
The covering length L5 is defined as described below, since, unlike the case of the spark plug 1 shown in
In the ground electrode tip 508, the tip-welded portion distance hg5 is the distance as measured, on a surface of the ground electrode tip 508 which includes the point k41 and is parallel to the axis AX5, from the end of the ground electrode tip 508 to the boundary between the tip 508 and the welded portion.
In the center electrode tip 509, the tip-welded portion distance hc5 is the distance in the direction of the axis AX5 as measured, on a surface of the center electrode tip 509 which includes the point k3 and is parallel to the axis AX5, from the end of the center electrode tip 509 to the boundary between the tip 509 and the welded portion 521 of the center electrode 504.
Since the ground electrode tip 508 has a rectangular columnar shape, and each of the six surfaces thereof is a flat surface, the tip cross-sectional area Ag5 of the ground electrode tip 508 is the area of the surface of the ground electrode tip 508 that faces the center electrode tip 509.
The spark plug 601 of this embodiment has the same configuration as the spark plug 1 shown in
Therefore, in the ground electrode tip 608 of the spark plug 601 of this embodiment, a welding area Sg6, a tip protrusion height Hg6, a covering length L6, and a tip-welded portion distance hg6 are defined in a manner similar to the case of the spark plug 1. Also, in a center electrode tip 609, a welding area Sc6, a tip protrusion height Hc6, a tip-welded portion distance hc6, and a tip cross-sectional area Ac6 are defined in a manner similar to the case of the spark plug 1.
In the spark plug 601 of this embodiment, since the end surface of the ground electrode tip 608 is not flat, the tip cross-sectional area Ag6 of the ground electrode tip 608 is defined as follows. Specifically, the tip cross-sectional area Ag6 is the area of the base of a virtual cylinder having a height of 0.2 mm and a volume V6 which is equal to the volume V6 of a portion formed by the surface of the ground electrode tip 608 and a plane Mg6, the plane Mg6 being parallel to the front end surface of the center electrode tip 609 and being distant 0.2 mm away from a point f6 (which is the intersection point between the surface of the ground electrode tip 608 and a straight line KX6, the straight line KX6 corresponding to the minimum distance between the ground electrode tip 608 and the center electrode tip 609), and the plane Mg6 being on the side opposite, with respect to the point f6, a point g6 (which is the intersection point of the surface of the center electrode tip 609 and the straight line KX6) (see
Also, when the end surface of the ground electrode tip 608 is a flat surface, but the cross-sectional area of the ground electrode tip 608 in a direction perpendicular to the axis of the tip 608 varies along the axis (for example, when the ground electrode tip 608 has a tapered shape such that the diameter thereof increases toward the ground electrode 607), the cross-sectional area of the ground electrode tip 608 is not the area of the end surface thereof, but is defined as in the case of the aforementioned tip cross-sectional area Ag6.
The spark plug of the second invention includes a center electrode and a ground electrode, wherein one end of the center electrode faces one end of the ground electrode via a gap, and a noble metal tip is provided on at least one of the center electrode and the ground electrode. No particular limitation is imposed on the configuration of a portion other than a main portion of the spark plug of the second invention, so long as the main portion of the spark plug has the aforementioned configuration. That is, the portion other than the main portion may have any known configuration. The spark plug of the second invention has the same configuration as the spark plug 1 shown in
In the spark plug of the second invention, at least one of the ground electrode tip and the center electrode tip is formed of the below-described tip material. Preferably, the ground electrode tip, which is heated to a higher temperature, is formed of the below-described tip material.
The tip material forming each of these noble metal tips contains Mp (Mp is an element group consisting of Pt or Pt and Pd, and the amount of Pd is 20 mass % or less with respect to the mass of the noble metal tip), Cu, and M (M is at least one element selected from the element group consisting of Rh, Ir, Ru, Re, and W) in a total amount of 95 mass % or more, wherein the proportions by mass of Mp, Cu, and M (Mp, Cu, M) in the Mp-Cu-M ternary composition diagram shown in
When the tip material contains Mp, Cu, and M in an amount of 95 mass % or more; the proportions by mass of the three components (Mp, Cu, M) fall within a region defined by a line connecting points A, B, C, and A in this order (the region includes the line) in the Mp-Cu-M ternary composition diagram shown in
Next will be described the effect of the composition of the noble metal tip under assumption that the noble metal tip has a specific structure as shown below.
When the amount of Cu is 3 mass % or more (particularly 5 mass % or more) in the ternary composition diagram shown in
When the amount of Cu is less than 3 mass % in the ternary composition diagram, the aforementioned effects may fail to be attained. When the amount of Cu exceeds 25 mass % in the ternary composition diagram; i.e., when the amount of Cu, which is easily oxidized, increases, oxidation resistance may be lowered, and internal oxidation may occur in crystal grain boundaries, resulting in breakage or separation of the tip. In addition, such a problem may cause impairment of thermal conductivity, which may adversely affect erosion resistance.
When the tip material contains M (particularly when the amount of M is 0.5 mass % or more in the ternary composition diagram), the tip material exhibits excellent spark erosion resistance, since M has a high melting point. Also, since crystal grain size decreases, falling of crystal grains, which is caused by breakage in the tip, can be suppressed. In addition, since the tip material exhibits high strength, even when it comes into contact with and is impacted by a jig during a production process, deformation of the noble metal tip can be suppressed. Thus, the tip material exhibits excellent impact resistance.
However, when the amount of M exceeds 17 mass % in the ternary composition diagram, embrittlement may occur, and thus proccessability is impaired, and breakage of the tip, which is caused by thermal stress or internal corrosion, is likely to occur. Since M has a low thermal expansion coefficient, when a large amount of M is incorporated, the difference in thermal expansion coefficient increases between the tip material and an Ni-based alloy employed as an electrode material, which adversely affects separation resistance. Therefore, the amount of M is 17 mass % or less (preferably 8 mass % or less) in the ternary composition diagram.
The effects of Cu and M in the tip material have been described above. Needless to say, the tip material is greatly affected not only by the proportion by mass of a single component, but also by the proportions by mass of three components (Mp, Cu, M). When the total amount of Cu and M contained in the tip material is equal to or greater than a specific level; i.e., when the proportions by mass of Cu and M exceed levels corresponding to line BC in the ternary composition diagram, at least one of separation resistance, erosion resistance, and tip breakage resistance is deteriorated. Therefore, the proportions by mass of Cu and M are equal to or lower than levels corresponding to line BC (preferably line GH) in the ternary composition diagram.
M is at least one element selected from the element group consisting of Rh, Ir, Ru, Re, and W. Each of Rh, Ir, Ru, Re, and W has a high melting point, and is difficult to sputter. In addition, strength is improved through formation of a solid solution, and crystal grain size can be reduced. Therefore, when the amount of at least one element selected from the element group falls within a region shown in the ternary composition diagram, the noble metal tip of the spark plug exhibits excellent separation resistance, erosion resistance, and breakage resistance. Among the elements of this group, Rh is particularly preferred, since Rh itself is oxidized to form a dense oxide film, whereby oxidation of Cu, etc. can be suppressed.
Mp is an element group consisting of Pt or Pt and Pd, and the amount of Pd is 20 mass % or less with respect to the mass of the noble metal tip. Pt is preferably employed as a main component of the tip material, since it exhibits excellent oxidation resistance, spark erosion resistance, and proccessability. Incorporation of a specific amount of Pd is advantageous in terms of separation resistance, since Pd exhibits excellent oxidation resistance similar to the case of Pt, and has a thermal expansion coefficient greater than that of Pt. Therefore, when the amount of Pd is 20 mass % or less with respect to the entire mass of the noble metal tip formed of the tip material, the noble metal tip of the spark plug exhibits excellent separation resistance, erosion resistance, and breakage resistance. Pd is more inexpensive than Pt. However, when the amount of Pd exceeds 20 mass %, the melting point of the tip material is lowered, resulting in impairment of erosion resistance.
Preferably, the tip material contains at least one element selected from the element group A consisting of Ni, Co, Fe, and Mn, and/or the element group B consisting of Ti, Hf, Y, and rare earth elements; the total mass of the element group A is 5 mass % or less with respect to the entire mass of the noble metal tip formed of the tip material; the total mass of the element group B is 1.5 mass % or less with respect to the entire mass of the noble metal tip formed of the tip material; and the total mass of the element group A and the element group B is less than 5 mass % with respect to the entire mass of the noble metal tip formed of the tip material.
When the total mass of the element group A is more than 0 mass % and 5 mass % or less in the tip material, the tip material exhibits further excellent separation resistance and breakage resistance. Since the element group A has a high thermal expansion coefficient, the difference in thermal expansion coefficient decreases between the tip material and an electrode material, and generation of thermal stress can be suppressed. In addition, since crystal grain size is reduced, the breakage resistance of the tip material is effectively improved.
When the total mass of the element group B is more than 0 mass % and 1.5 mass % or less (particularly 0.01 mass % to 1 mass %) in the tip material, since crystal grain size is reduced, the tip material exhibits excellent breakage resistance.
When the amount of the element group A or the element group B is excessively large in the tip material, the melting point of the tip material may be lowered, resulting in poor erosion resistance. Therefore, the total mass of the element group A and the element group B is preferably less than 5 mass % with respect to the mass of the noble metal tip.
The tip material contains Mp, Cu, and M in a total amount of 95 mass % or more, and substantially contains the element group A consisting of Ni, Co, Fe, and Mn, and the element group B consisting of Ti, Hf, Y, and rare earth elements, as desired. The tip material contains these components such that the amounts of the components fall within the aforementioned ranges, and the total amount of these components and an inevitable impurity is 100 mass %. The tip material may contain a very small amount of a component other than the aforementioned components; i.e., an inevitable impurity such as Ag, B, Ca, Al, Si, or Mg. Preferably, the amount of such an inevitable impurity is reduced to a minimum possible level. However, the tip material may contain such an impurity, so long as the object of the present invention can be achieved. Preferably, the amount of any one of the aforementioned inevitable impurities is 0.1 parts by mass or less, and the total amount of all the inevitable impurities contained in the tip material is 0.2 parts by mass or less, on the basis of 100 parts by mass of the total mass of the aforementioned components.
The amount of each component contained in the noble metal tip formed of the aforementioned tip material may be determined in a manner similar to that described above in the first invention.
The noble metal tip formed of the aforementioned tip material preferably has a hardness of 140 Hv or more, particularly preferably 200 Hv or more.
In the case where the hardness of the noble metal tip falls within the above range, even when the tip comes into contact with a jig during a production process, deformation of the noble metal tip can be prevented.
The hardness of the noble metal tip may be measured in a manner similar to that described above in the first invention. Also, the hardness of the noble metal tip may be adjusted in a manner similar to that described above in the first invention.
In the noble metal tip provided in the spark plug of the second invention, the below-defined welding area S (mm2), tip protrusion height H (mm), covering length L (mm), and tip-welded portion distance h (mm) satisfy the following relations: (a) H≦0.13S+1.18, (b) S≦5, and (c) 0.1≦h or 0.03≦L.
In the noble metal tip, preferably, the below-defined tip cross-sectional area A (mm2) satisfies the following relation: (d) 0.2≦A≦1.8.
When, in the noble metal tip, welding area S and tip protrusion height H satisfy the following relation: (a) H≦0.13S+1.18, the noble metal tip of the spark plug exhibits excellent erosion resistance. In order to improve the erosion resistance of the noble metal tip, preferably, the heat dissipation of the noble metal tip is increased. Hitherto, it has been considered that when welding area S is small, the contact area between the noble metal tip and the electrode is reduced, and thus heat received by the noble metal tip is less likely to be transferred to the electrode, resulting in poor heat dissipation. However, the present inventors have found that heat dissipation is affected not only by welding area S, but also by tip protrusion height H. That is, even in the case where welding area S is small, when tip protrusion height H is smaller than a specific value, overheating of the noble metal Lip can be suppressed, and favorable erosion resistance is achieved. Conversely, even in the case where tip protrusion height H is large, when welding area S is large, favorable heat dissipation is achieved, and thus overheating of the noble metal tip can be suppressed.
When, in the noble metal tip, welding area S, covering length L, and tip-welded portion distance h satisfy the following relations: (b) S≦5 and (c) 0.1≦h or 0.03≦L, the noble metal tip of the spark plug exhibits excellent separation resistance. When welding area S is large, high thermal stress is generated particularly in an outer peripheral portion of the noble metal tip due to the difference in thermal expansion coefficient between the tip material forming the noble metal tip and the material forming the electrode, and thus the noble metal tip is likely to be detached from the electrode. Therefore, welding area S is 5 or less. Since highly turbulent airflow occurs in a combustion chamber, when covering length L and tip-welded portion distance h fall outside the above ranges, discharge is likely to occur at a portion of the electrode in the vicinity of the outer periphery of the noble metal tip and/or at the welded portion. Since the electrode or the welded portion has a melting point lower than that of the noble metal tip, the electrode or the welded portion is easily eroded, and the boundary between the noble metal tip and the electrode or the welded portion is hollowed, resulting in poor separation resistance. In addition, when the electrode or the welded portion is eroded, welding area S is substantially reduced, which adversely affects erosion resistance. Therefore, tip-welded portion distance h is 0.1 or more, or covering length L is 0.03 or more.
In the noble metal tip, tip cross-sectional area A preferably satisfies the following relation: (d) 0.2≦A≦1.8. When tip cross-sectional are A falls within the above range, further excellent erosion resistance is achieved.
In the second invention, the aforementioned welding area S, tip protrusion height H, covering length L, tip-welded portion distance h, and tip cross-sectional area A are defined in the same manner as described above in the first invention with reference to
The spark plug of the second invention may be produced in the same manner as in the case of the spark plug of the first invention.
The spark plug of the first or second invention is employed as an ignition plug of an internal combustion engine for an automobile (e.g., a gasoline engine). When in use, the spark plug is fixed to a specific position by screwing the threaded portion 10 into a threaded hole provided on a head (not-illustrated) for compartmenting the combustion chamber of the internal combustion engine. The spark plug of the first or second invention can be applied to any internal combustion engine. Particularly preferably, the spark plug is applied to an internal combustion engine having a supercharger or an internal combustion engine employing a high-energy coil, since the spark plug has a noble metal tip exhibiting excellent separation resistance, erosion resistance, and breakage resistance.
The spark plug of the first or second invention is not limited to the aforementioned embodiments, and various modifications may be made, so long as the object of the present invention can be achieved. For example, in the aforementioned spark plug 1, both the center electrode tip 9 and the ground electrode tip 8 are formed of the aforementioned tip material. However, in the present invention, only the center electrode tip 9 may be formed of the tip material, or only the ground electrode tip 8 may be formed of the tip material. In the case of the spark plug of the present invention, generally, the ground electrode is exposed to a higher temperature, as compared with the center electrode. Therefore, preferably, at least the ground electrode tip is formed of the aforementioned tip material.
An alloy having a composition shown in Tables 1 to 5 was melted to thereby prepare a molten material, and the molten material was processed into a wire-like material by means of at least one process selected from among hot or cold rolling, forging, wire drawing, and swaging. The thus-processed material was longitudinally cut, to thereby produce a circular columnar noble metal tip.
INC601 was subjected to a casting process, to thereby produce a center electrode and a ground electrode. The above-produced noble metal tip for center electrode was bonded to an end surface of the center electrode formed into a rod shape, through resistance welding and subsequent laser welding (hereinafter, the noble metal tip bonded to the center electrode may be referred to as the “center electrode tip”). The above-produced noble metal tip for ground electrode was bonded to a peripheral side surface of an end portion of the ground electrode formed into a generally rectangular columnar shape, through resistance welding and subsequent laser welding (hereinafter, the noble metal tip bonded to the ground electrode may be referred to as the “ground electrode tip”). The noble metal tip was bonded to the surface (width: 3.0 mm) of the ground electrode having a generally rectangular columnar shape (1.6×3.0 mm).
By means of a known technique, one end portion of the ground electrode to which the noble metal tip was not bonded was bonded to one end surface of a metallic shell. Then, the center electrode was assembled into a ceramic insulator, and the insulator was assembled into the metallic shell having the ground electrode bonded thereto. The distal end portion of the ground electrode was bent toward the center electrode so that one end of the ground electrode faced the front end of the center electrode, to thereby produce spark plug test sample A.
The thread diameter of the thus-produced test sample A was M14, and the spark discharge gap between the front end surface of the center electrode tip and the end surface of the ground electrode tip (facing the center electrode tip) was 1.1 mm. Each of the center electrode tip and the ground electrode tip assumed a circular columnar shape (welding area S: 0.2 mm2, tip protrusion height H: 1.4 mm, covering length L: 0 mm, tip-welded portion distance h: 1.0 mm, and tip cross-sectional area A: 0.2 mm2). In the spark plug test sample, the noble metal tip has a circular columnar shape, and is bonded to the electrode through resistance welding and laser welding, as in the case of the spark plug test sample shown in
Each of the noble metal tip bonded to the center electrode and the noble metal tip bonded to the ground electrode was found to have a hardness of 140 Hv or more as measured through the aforementioned method. A resistor provided between the center electrode and the terminal shell was found to have a resistance of 5 kΩ.
Spark plug test sample B was produced in the same manner as in the case of spark plug test sample A, except that ground electrode tip was bonded to the electrode through merely resistance welding (i.e., without laser welding), and the ground electrode tip was formed to assume a circular columnar shape (welding area Sg: 5.3 mm2, tip protrusion height Hg: 0.2 mm, covering length L: 0.02 mm, tip-welded portion distance hg: 0 mm, and tip cross-sectional area: 5.3 mm2). In the spark plug test sample, the noble metal tip has a circular columnar shape, and is bonded to the electrode through merely resistance welding, as in the case of the spark plug test sample shown in
Each of the noble metal tip bonded to the center electrode and the noble metal tip bonded to the ground electrode was found to have a hardness of 140 Hv or more as measured through the aforementioned method. A resistor provided between the center electrode and the terminal shell was found to have a resistance of 5 kΩ.
Spark plug test sample C including a ground electrode tip having a different hardness was produced in the same manner as in the case of spark plug test sample A, except that a ground electrode tip having a different hardness was formed by changing processing conditions (e.g., percent processing and processing temperature) for forming the ground electrode tip having a composition shown in Table 6, as well as conditions for welding of the noble metal tip to a ground electrode, and that the ground electrode tip was formed to assume a circular columnar shape (welding area Sg: 0.4 mm2, tip protrusion height Hg: 1 mm, tip-welded portion distance hg: 0.6 mm, and tip cross-sectional area Ag: 0.4 mm2). The ground electrode tip of spark plug test sample C has circular columnar shape I.
Spark plug test sample D (resistance of resistor: 10 kΩ or 15 kΩ) was produced by varying, for example, the mixing proportions of raw materials of a resistor in three spark plug test samples A.
The above-produced spark plug test sample A, B, or D was attached to a four-cylinder engine (2,000 cc) having a supercharger. Subsequently, engine rotation speed was maintained at 6,000 rpm in a full throttle state for three minutes, and then idling was performed at an engine rotation speed of 900 rpm. This operation cycle was repeatedly carried out for 300 hours. Thereafter, the erosion resistance, tip breakage resistance, and separation resistance of the spark plug test sample were evaluated as described below.
Before and after the aforementioned 300-hour durability test, the gap between the end surface of the center electrode tip and the end surface of the ground electrode tip in the spark plug test sample A or D was measured by means of a pin gauge, and an increase in the gap was calculated. Erosion resistance was evaluated according to the following criteria in terms of gap increase:
×: 0.2 mm or more;
◯: 0.15 mm or more and less than 0.2 mm;
⊚: 0.12 mm or more and less than 0.15 mm; and
⋆: less than 0.12 mm.
The results are shown in Tables 1 to 5 and 7.
After the aforementioned 300-hour durability test, the ground electrode having the noble metal tip bonded thereto was cut out of the spark plug test sample A, and the noble metal tip was observed under an SEM (magnification: ×250) in a direction along the spark discharge gap and in a direction perpendicular thereto (i.e., in a circumferential direction of the noble metal tip). Tip breakage resistance was evaluated according to the following criteria:
×: breakage was observed at 10 or more points on the surface of the noble metal tip, or falling of crystal grains was observed;
◯: breakage was observed at less than 10 points on the surface of the noble metal tip; and
⊚: no breakage was observed on the surface of the noble metal tip.
The results are shown in Tables 1 to 5.
After the aforementioned 300-hour durability test, the ground electrode having the noble metal tip bonded thereto was cut out of the spark plug test sample B, and then subjected to cutting so that the resultant cross section included the center of the noble metal tip and became parallel to the longitudinal direction of the ground electrode. The cross section was observed under a metallographic microscope for determining the presence or absence of oxide scale.
Oxide scale corresponds to a black portion observed under a metallographic microscope; specifically, an oxidized or detached portion at the boundary between the noble metal tip and the welded portion or the ground electrode. As shown in
×: oxide scale ratio was 60% or more;
◯: oxide scale ratio was 30% or more and less than 60%; and
⊚: oxide scale ratio was less than 30%.
The results are shown in Tables 1 to 5.
The ground electrode 7 having the noble metal tip 8 bonded thereto was cut out of the above-produced spark plug test sample X, and was placed on an apparatus shown in
The above-produced spark plug test sample X was subjected to the aforementioned deformation resistance test, and the amount of deformation of the noble metal tip was determined. Deformation resistance was evaluated according to the following criteria:
×: 250 μm or more;
◯: 210 μm or more and less than 250 μm;
⊚: 180 μm or more and less than 210 μm; and
⋆: less than 180 μm.
The results are shown in Table 6.
The comprehensive evaluation of each spark plug test sample (on the basis of the results of the durability test shown in Tables 1 to 5) was determined according to the following criteria:
×: at least one of the evaluation results of erosion resistance, tip breakage resistance, and separation resistance was X;
◯: all of the evaluation results of erosion resistance, tip breakage resistance, and separation resistance were ◯;
⊚: one of the evaluation results of erosion resistance, tip breakage resistance, and separation resistance was ⊚ or ⋆;
⋆: two of the evaluation results of erosion resistance, tip breakage resistance, and separation resistance were ⊚or ⋆; and
⋆⋆: all of the evaluation results of erosion resistance, tip breakage resistance, and separation resistance were ⊚or ⋆.
The proportions by mass of Pt, Cu, and Rh contained in a ground electrode tip having a composition shown in Tables 1 and 2 are shown in
As shown in Tables 2 to 7, a spark plug including a noble metal tip falling within the scope of the first invention exhibited excellent erosion resistance, separation resistance, and tip breakage resistance.
In contrast, in the case of a spark plug including a noble metal tip falling outside the scope of the first invention, as shown in Tables 1 and 4 to 7, at least one of erosion resistance, separation resistance, and tip breakage resistance was impaired.
As shown in Table 3, noble metal tips containing any of Rh, Ir, Ru, Re, and W exhibited similar performances. As shown in Table 4, the spark plug (No. 70 or 71) including a noble metal tip containing Pt, Cu, and Pd exhibited excellent separation resistance, as compared with the spark plug (No. 38) including a noble metal tip containing Pt and Cu. As shown in Table 5, the spark plugs (Nos. 73 to 75 and 82) each including a noble metal tip containing at least one of Ni, Co, and Mn exhibited further excellent separation resistance and tip breakage resistance, as compared with the spark plugs (Nos. 35 and 36) each including a noble metal tip not containing such an element. Also, the spark plugs (Nos. 77 to 82) each including a noble metal tip containing any of Hf, Ti, Y, and La exhibited further excellent tip breakage resistance, as compared with the spark plugs (Nos. 35, 46, and 36) each including a noble metal tip not containing such an element.
As shown in Table 6, a spark plug including a noble metal tip falling within the scope of the present invention exhibited further excellent deformation resistance when the hardness of the noble metal tip was 140 Hv or more (particularly 200 Hv or more). As shown in Table 7, a spark plug including a noble metal tip falling within the scope of the present invention exhibited excellent erosion resistance even when the resistance of a resistor was 10 kΩ or less.
Spark plug test sample E was produced in the same manner as in the case of spark plug test sample A, except that, in a ground electrode tip (noble metal tip) having a composition shown in Tables 8 to 12, tip protrusion height H was adjusted to 1.2 mm, and tip-welded portion distance h was adjusted to 0.8 mm. The noble metal tip of spark plug test sample E has circular columnar shape I.
Each of the center electrode tip and the ground electrode tip was found to have a hardness of 140 Hv or more as measured through the aforementioned method. A resistor provided between the center electrode and the terminal shell was found to have a resistance of 5 kΩ.
Spark plug test sample F was produced in the same manner as in the case of spark plug test sample B, except that, in a ground electrode tip (noble metal tip) having a composition shown in Tables 8 to 12, welding area S was adjusted to 5 mm2, covering length L was adjusted to 0.03 mm, and tip cross-sectional area A was adjusted to 5 mm2. The center electrode tip and ground electrode tip of spark plug test sample F have circular columnar shape I and circular columnar shape II, respectively.
Spark plug test sample G was produced in the same manner as in the case of spark plug test sample E, except that, in a ground electrode tip (noble metal tip) having a composition shown in Table 13, welding area Sg and tip protrusion height Hg were changed by varying the diameter and height of the ground electrode tip. The ground electrode tip of spark plug test sample G has circular columnar shape I. In Table 13, “Pt-18Cu-5Rh” refers to the case where the noble metal tip contains Pt in an amount of 77 mass %, Cu in an amount of 18 massa, and Rh in an amount of 5 mass % (the same shall apply hereinafter).
Spark plug test sample H was produced in the same manner as in the case of spark plug test sample E, except that the shape of a ground electrode tip (noble metal tip) having a composition shown in. Table 14 was changed without changing welding area Sg and tip protrusion height Hg of the ground electrode tip. Regarding the shape of the noble metal tip described in Table 14, “protruded shape” corresponds to a shape similar to that of a ground electrode tip shown in
Spark plug test sample I was produced in the same manner as in the case of spark plug test sample F, except that, in a ground electrode tip having a Composition shown in Table 15, welding area Sg was changed by varying the diameter of the ground electrode tip and welding conditions. In this test sample, covering length L was 0 mm, and tip-welded portion distance hg was 0.1 mm.
Spark plug test sample J was produced in the same manner as in the case of spark plug test sample F, except that, in a ground electrode tip having a composition shown in Table 16, covering length L and tip-welded portion distance hg were changed by varying the diameter of the ground electrode tip and welding conditions.
Spark plug test sample K was produced in the same manner as in the case of spark plug test sample F, except that the shape of a ground electrode tip having a composition shown in Table 17 was changed without changing welding area Sg, covering length L, and tip-welded portion distance hg of the ground electrode tip.
Spark plug test sample L including a ground electrode tip having a different hardness was produced in the same manner as in the case of spark plug test sample E, except that a ground electrode tip having a different hardness was formed by changing processing conditions (e.g., percent processing and processing temperature) for forming the ground electrode tip having a composition shown in Table 18, as well as conditions for welding of the noble metal tip to a ground electrode, and that the ground electrode tip was formed to assume a circular columnar shape (welding area Sg: 0.4 mm2, tip protrusion height Hg: 1 mm, tip-welded portion distance hg: 0.6 mm, and tip cross-sectional area Ag: 0.4 mm2). The ground electrode tip of spark plug test sample L has circular columnar shape I.
Spark plug test sample M (resistance of resistor: 10 kΩ or 15 kΩ) was produced by varying, for example, the mixing proportions of raw materials of a resistor in two spark plug test samples E.
Each of the above-produced spark plug test samples was evaluated through the aforementioned evaluation methods in a manner similar to that described above in the first invention. The comprehensive evaluation of each spark plug test sample (on the basis of the results of the durability test shown in Tables 8 to 12) was determined according to the criteria described above in the first invention. The results are shown in Tables 8 to 19 and
The proportions by mass of Pt, Cu, and Rh contained in a ground electrode tip having a composition shown in Tables 8 and 9 are shown in
As shown in Tables 9 to 19, a spark plug including a noble metal tip falling within the scope of the second invention exhibited excellent erosion resistance, separation resistance, and tip breakage resistance.
In contrast, in the case of a spark plug including a noble metal tip falling outside the scope of the present invention, as shown in Tables 8 and 12 to 19, at least one of erosion resistance, separation resistance, and tip breakage resistance was impaired.
As shown in Table 10, noble metal tips containing any of Rh, Ir, and Ru exhibited similar performances. As shown in Table 11, the spark plug (No. 121) including a noble metal tip containing Pt, Cu, and Rh exhibited a performance similar to that of the spark plug (No. 164) including a noble metal tip containing Pt, Cu, Rh, and Pd. As shown in Table 12, a spark plug including a noble metal tip containing at least one of Ni, Co, Ti, and La in a total amount of 5 mass % or less exhibited further excellent erosion resistance, separation resistance, and tip breakage resistance, as compared with a spark plug including a noble metal tip not containing such an element, or a spark plug including a noble metal tip containing such an element in a total amount of more than 5 mass %.
As shown in Table 15, a spark plug including a ground electrode tip having a welding area S of 5.0 or less exhibited favorable evaluation in terms of separation resistance. As shown in Table 16, a spark plug including a ground electrode tip having h of 0.1 (mm) or more or L of 0.03 (mm) or more exhibited excellent evaluation in terms of separation resistance. As shown in Table 17, a spark plug including a ground electrode tip having a welding area S (mm2) of 5.0 or less and h of 0.1 (mm) or more or L of 0.03 (mm) or more exhibited favorable evaluation in terms of separation resistance, regardless of the shape of the ground electrode tip.
As shown in Table 18, a spark plug including a noble metal tip falling within the scope of the present invention exhibited further excellent deformation resistance when the hardness of the noble metal tip was 140 Hv or more (particularly 200 Hv or more). As shown in Table 19, a spark plug including a noble metal tip falling within the scope of the present invention exhibited excellent erosion resistance even when the resistance of the resistor was 10 kΩ or less.
Number | Date | Country | Kind |
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2010-134045 | Jun 2010 | JP | national |
This application is a U.S. National Phase Application under 35 U.S.C. §371 of International Patent Application No. PCT/JP2011/000612, filed Feb. 3, 2011, and claims the benefit of Japanese Patent Application No. 2010-134045, filed Jun. 11, 2010, all of which are incorporated by reference herein. The International Application was published in Japanese on Dec. 15, 2011 as International Publication No. WO/2011/155101 under PCT Article 21(2).
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/000612 | 2/3/2011 | WO | 00 | 11/1/2012 |