EP1413029B1 - Method for placing a precious metal tip on an electrode, electrode and spark plug - Google Patents

Description

State of the art

The invention is based on a method for mounting a noble metal tip on an electrode, an electrode and a spark plug according to the preamble of the independent claims.

From WO91 / 02393 it is already known to weld a noble metal tip to an electrode. The electrode may be a ground or center electrode of a spark plug.

Advantages of the invention

The inventive method for attaching a noble metal tip on an electrode, the electrode according to the invention and the spark plug according to the invention with the features of the independent claims have the advantage that the noble metal tip in a first region and the electrode in a second region adjacent to the first region , Is melted to form a mixed alloy in these areas, wherein the first region is chosen so that it is completely encased in a ring around the material of the noble metal tip. Due to the mixed alloy, the connection between the Precious metal tip and the electrode durable. Due to the approximately annular complete sheathing of the first region of the material of the noble metal tip, the noble metal tip and the connection between the noble metal tip and the electrode remain wear-resistant and resistant to corrosion and erosion.

The measures listed in the dependent claims advantageous refinements and improvements of the method and the electrode according to the independent claims are possible.

It is particularly advantageous that the two areas are melted by means of laser energy. In this way, the two areas for the formation of the mixed alloy defined and melt with high local precision, so that melting of the noble metal tip or the electrode outside the two areas can be prevented. In addition, the melting process in the two areas for forming the mixed alloy by using the laser energy with appropriate laser power can be realized very quickly.

Another advantage is that the laser energy is applied by a laser element by means of a laser pulse. In this way, the energy required to melt the two areas can be provided precisely and in a defined and predetermined manner by selecting the power and time of the laser pulse.

drawing

An embodiment of the invention is illustrated in the drawing and explained in more detail in the following description. FIG. 1 shows a first step, FIG. 2 shows a second step, FIG. 3 shows a third step, and FIG. 4 shows a fourth step of the method according to the invention for forming an electrode according to the invention, for example for a spark plug.

Description of the embodiment

The requirements for spark plugs with regard to their durability have steadily increased in recent years. Currently, replacement intervals for the spark plugs from 60,000.00 km to 100,000.00 km are specified by various car manufacturers. The trend is therefore to so-called Lifetime spark plugs whose durability should come as close as possible to the durability of the vehicle.

Such lifetime can be achieved at least for spark plugs with a ground electrode designed as a roof electrode only by the use of noble metal alloys on the center electrode and the opposite ground electrode. These precious metal alloys may be attached to the respective electrodes of the spark plug by, for example, extrusion, plating, resistance welding and laser welding or laser alloying. These electrodes are made of nickel alloys, for example.

The process technology for the preparation of the connection between the noble metal alloy and such an electrode high demands are made, because the Properties of the noble metal alloys in comparison to nickel alloys in terms of melting and boiling point and thermal expansion coefficient differ greatly. An inexpensive joining method is resistance welding. When the noble metal alloy is bonded to the nickel alloy by resistance welding, it may be heated in the region of its juxtaposition when this compound is heated due to the different coefficients of thermal expansion and diffusion zone thicknesses in the boundary region between the noble metal alloy and the nickel alloy Tearing open the connection. In the resulting gap corrosion occurs, especially when the electrode is inserted as a ground or center electrode in the combustion chamber of an internal combustion engine and is surrounded by the local gas mixtures. Thus, the life of such compounds is limited.

One method that results in a more stable bond between the noble metal alloy and the nickel alloy is to attach a weld between the noble metal alloy and the nickel alloy using a laser welding process. However, the attachment of such welds is relatively expensive and requires a relatively high cost of materials for the noble metal alloy.

By contrast, a simpler method is the so-called laser alloying, in which the noble metal alloy and the nickel alloy in adjacent areas completely melted and thereby mixed, that is alloyed. However, the resulting noble metal-nickel alloy is less resistant to erosion and corrosion than pure precious metal alloys.

With the method according to the invention, the disadvantages mentioned, which result in the connection of the noble metal alloy with the nickel alloy by resistance welding, laser welding or laser alloying, should now be largely avoided. In this case, durable, wear-resistant electrodes are to be produced, wherein the connection between a noble metal or a noble metal alloy with the electrode should be feasible with little effort.

In Fig. 1, 5 denotes an electrode which may be, for example, the center electrode of a spark plug. The electrode 5 comprises a tip 20 which can form a depression according to FIG. 1, but need not. The electrode 5 is metallic and may for example be formed at least partially from nickel. In the following, it will be assumed by way of example that the electrode 5 is formed from a nickel alloy.

FIG. 1 furthermore shows a noble metal tip 1, which may be formed from a pure noble metal or from a noble metal alloy. As pure precious metals can be used, for example, gold, platinum or iridium. When using precious metal alloys, this can also be done using gold, platinum or iridium. Under noble metal alloys are understood to mean alloys containing only precious metals. In this example, the noble metal tip 1 should be formed as a noble metal alloy and contain a proportion of platinum. According to FIG. 1, the noble metal tip 1 is shaped on its underside 35 such that it can be received as accurately as possible from the tip 20 of the electrode 5. According to Figure 1, the noble metal tip 1 on its underside 35 a highlighting, which corresponds to the recess 20 at the top of the electrode 5. The diameter of the precious metal tip is 1 It is about the same size as the diameter of the electrode 5 in the region of its tip 20. However, it could also be chosen larger or smaller.

According to FIG. 1, in a first method step, the noble metal tip 1 is now set accurately on the tip 20 of the electrode 5, as indicated by the arrow in FIG.

Subsequently, in a second method step according to FIG. 2, the noble metal tip 1 is welded to the electrode 5 in the region in which the noble metal tip 1 adjoins the electrode 5, for example by a resistance welding method. This area is identified by the reference numeral 40 in FIG. He is referred to below as the welding area.

The thickness of the resulting diffusion zone in the welding region 40 is usually a few microns and is thus prone to thermal stress cracks due to the different thermal expansion coefficients of the noble metal tip 1 and the nickel-containing electrode fifth

In a third method step, the noble metal tip 1 is melted in a first region 10 and the electrode 5 in a second region 15, which is adjacent to the first region 10, in order in these regions 10, 15 a mixed alloy of the material of the noble metal tip 1 and the Material of the electrode 5 to form, so a mixed alloy of the noble metal alloy of the noble metal tip 1 and the nickel alloy of the electrode 5 according to the example chosen here. In this case, the first region 10 is determined in such a way that it is completely surrounded by the material of the noble metal tip 1 approximately annularly, as can be seen in FIG. In all figures, like reference numerals designate like elements. The welding region 40 is in the region of a boundary region 25 of the first area 10 to the second area 15 in Figure 3 for clarity by hatching highlighted and indicated by the reference numeral 45. He is referred to below as the border welding area. When melting the first region 10 and the second region 15, the boundary welding region 45 is also melted, which after the second process step according to FIG. 2 as part of the welding region 40 resulted in the described diffusion zone between the noble metal tip 1 and the electrode 5. In the first region 10, in the second region 15 and in the boundary welding region 45, the complete mixing of the material of the noble metal tip 1 and of the material of the electrode 5 results in the third process step according to FIG. 3. Thus, according to the third method step according to FIG Area 10, in the second area 15 and in the boundary welding area 45, an approximately homogeneous noble metal-nickel alloy, the ring according to Figure 3 in the region of the noble metal tip 1 approximately annularly completely from the material of the noble metal tip 1, in the region of the electrode 5 completely from the material of the electrode 5 and is completely surrounded by the diffusion zone in the region of the welding region 40. It is crucial, above all, that the first region 10 is completely surrounded by the material of the noble metal tip 1 in a ring-shaped manner.

In this way, the mixed alloy is completely separated in the region of the noble metal tip 1 to its combustion chamber side face of the atmosphere surrounding the noble metal tip 1 and thus protected from environmental influences and not exposed to erosion and corrosion, especially in the combustion chamber of an internal combustion engine. According to FIG. 3, the mixed alloy forming in the first region 10, in the second region 15 and in the boundary welding region 45 is completely separated from the surrounding atmosphere in the region of the electrode 5, since the second region 15, with the exception of its boundary region 50, also reaches the boundary welding region 45 first Area 10 is completely surrounded by the material of the electrode 5.

By the mixed alloy, the connection between the noble metal tip 1 and the electrode 5 is made particularly stable and durable and is no longer subject to the risk of cracking in the region of the diffusion zone between precious metal tip 1 and electrode 5. By in the precious metal tip 1 approximately annular shield of resulting mixed alloy of noble metal fractions and nickel contents in front of the surrounding atmosphere is prevented, especially in the region of the connection between the noble metal tip 1 and the electrode 5 that the erosion and corrosion-prone mixed alloy is exposed to harmful environmental influences, so that the connection between the noble metal tip 1 and the electrode 5 particularly is durable.

The melting of the first region 10, the boundary welding region 45 and the second region 15 can be realized for example by means of laser energy. For this purpose, for example, by a laser element 30 as shown in Figure 3, the laser energy can be applied. In Fig. 3, reference numeral 55 denotes a laser beam. The laser beam is focused on the first region 10, the boundary welding region 45 and the second region 15 and ensures a locally precise melting of these regions and thus the formation of a homogeneous homogeneous mixed alloy which is as constant as possible in these regions. The laser energy can be applied, for example, by means of a laser pulse to a, in the case of a spark plug combustion chamber side, end face of the noble metal tip 1. The laser energy is not applied to the entire end face of the noble metal tip 1, but to an approximately circular area which is surrounded by an approximately annular region of the end face.

Only in the circular region of the end face and underneath is the precious metal tip 1 thus melted to give the first region 10, which is completely encased in an annular manner by the material of the noble metal tip 1. The use of a laser pulse enables a specific and defined provision of the energy required for the melting of the first region 10, the second region 15 and the boundary welding region 45. For example, the laser pulse may have a power of about 1 kW for a time of about 10 ms.

Thus, according to FIG. 4, after the third method step between the noble metal tip 1 and the electrode 5, the mixed alloy identified by the reference numeral 60 has a coefficient of thermal expansion between that of the noble metal alloy of the noble metal tip 1 and that of the nickel alloy of the electrode 5. Cracks due to thermal stresses are thereby avoided, especially in the area of the mixed alloy 60. The connection between the noble metal tip 1 and the electrode 5 is thus durable. This is all the more the greater the cross section of the mixed alloy 60 in the region of the weld region 40, ie the diffusion zone. Only a combustion chamber-side end face 100 of the mixed alloy 60 is not surrounded by the non-melted material of the noble metal tip 1 and thus exposed directly to the combustion chamber. Since, according to FIG. 3, the first region 10 is completely surrounded by non-molten material of the noble metal tip 1 approximately annularly, the mixed alloy 60 according to FIG. 4 is largely shielded from environmental influences in the region of the noble metal tip 1. Thus, with the exception of the combustion chamber end face 100 of the mixed alloy 60 on the surface of the noble metal tip 1, especially in the combustion chamber facing part of the weld region 40, the very good erosion and corrosion properties of the noble metal alloy used continue before. Thus, especially in the welding area 40, corrosion and erosion are prevented and the durability of the connection between the noble metal tip 1 and the electrode 5 is increased.

The formed electrode 5 with the noble metal tip 1 is thus durable with minimal use of precious metals under combustion chamber conditions as well as erosion and corrosion resistant. The second process step of the welded joint and the third process step of the laser alloy can be carried out in a short cycle time and simultaneously. Thus, the manufacturing time is not increased compared to a pure welded joint or laser alloy.

The electrode 5 is exemplified here as the center electrode of a spark plug. Similarly, a noble metal tip may also be attached to a ground electrode, such as a roof electrode or a side electrode. Thus, a spark plug can be provided in which both the center electrode and one or more ground electrodes each comprise a noble metal tip, the noble metal tip of the center electrode of the noble metal tip facing a ground electrode to form the spark gap to minimize electrode wear and extend the life of the spark plug , The spark plug is referenced in all figures by the reference numeral 65 and is for clarity only on the basis of a section of the electrode 5, which acts in this example as the center electrode of the spark plug 65, shown.

In all figures, like reference numerals designate like elements, and the electrode 5 and the noble metal tip 1 are shown in a longitudinal section.

Claims (13)

1. Method for placing a precious metal tip (1) on an electrode (5), in particular a spark plug electrode, wherein in one step the precious metal tip (1) is welded onto the electrode (5), characterized in that in a further step the precious metal tip (1), in a first region (10), and the electrode (5), in a second region (15) which is adjacent to the first region (10), are melted, in order to form a mixed alloy (60) in these regions (10, 15), wherein the first region (10) is selected in such a way that it is completely surrounded, approximately in the form of a ring, by the material of the precious metal tip (1).
2. Method according to Claim 1, characterized in that the welding method selected for the first step is a resistance welding method.
3. Method according to Claim 1 or 2, characterized in that the two regions are melted by means of laser energy.
4. Method according to Claim 3, characterized in that the laser energy is applied to an end face of the precious metal tip (1) by means of a laser pulse from a laser element (30).
5. Method according to Claim 4, characterized in that the laser pulse applies a power of approximately 1kW for a period of approximately 10ms.
6. Method according to one of the preceding claims, characterized in that the material selected for the electrode (5) is a non-precious metal, preferably nickel or a nickel alloy.
7. Method according to one of the preceding claims, characterized in that the material selected for the precious metal tip (1) is a precious metal alloy, in particular with a gold, iridium or platinum content.
8. Method according to one of Claims 1 to 6, characterized in that the material selected for the precious metal tip (1) is a pure precious metal, in particular gold, iridium or platinum.
9. Electrode (5), in particular for a spark plug (65), having a precious metal tip (1), wherein the precious metal tip (1) is welded to the electrode (5), characterized in that the precious metal tip (1), in a first region (10), and the electrode (5), in a second region (15) which is adjacent to the first region (10), form a mixed alloy (60), wherein the first region (10) is completely surrounded, approximately in the form of a ring, by the material of the precious metal tip (1).
10. Electrode (5) according to Claim 9, characterized in that the electrode (5) is formed from a non-precious metal, preferably nickel or a nickel alloy.
11. Electrode (5) according to Claim 9 or 10, characterized in that the precious metal tip (1) is formed from a precious metal alloy, in particular with a gold, iridium or platinum content.

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