This invention generally relates to spark plugs and other ignition devices for internal combustion engines and, in particular, to methods of manufacturing spark plug electrode materials that include ruthenium (Ru).
Spark plugs can be used to initiate combustion in internal combustion engines. Spark plugs typically ignite a gas, such as an air/fuel mixture, in an engine cylinder or combustion chamber by producing a spark across a spark gap defined between two or more electrodes. Ignition of the gas by the spark causes a combustion reaction in the engine cylinder that is responsible for the power stroke of the engine. The high temperatures, high electrical voltages, rapid repetition of combustion reactions, and the presence of corrosive materials in the combustion gases can create a harsh environment in which the spark plug must function. This harsh environment can contribute to erosion and corrosion of the electrodes that can negatively affect the performance of the spark plug over time, potentially leading to a misfire or some other undesirable condition.
To reduce erosion and corrosion of the spark plug electrodes, various types of precious metals and their alloys—such as those made from platinum and iridium—have been used. These materials, however, can be costly. Thus, spark plug manufacturers sometimes attempt to minimize the amount of precious metals used with an electrode by using such materials only at a firing tip or spark portion of the electrodes where a spark jumps across a spark gap.
A method of manufacturing a spark plug electrode material into a desired form is disclosed. In one embodiment, the method includes forming a ruthenium-based material core that has a length dimension and a cross-sectional area oriented perpendicular to the length dimension. An iridium-based material interlayer is then disposed over an exterior surface of the ruthenium-based material core and a nickel-based cladding is disposed over an exterior surface of the iridium-based material interlayer to form a layered structure. This layered structure is hot-formed to reduce the cross-sectional area of the ruthenium-based material core to form an elongated layered wire. The nickel-based cladding is eventually removed from the elongated layered wire to derive an elongated electrode material wire that includes the ruthenium-based material core encased in the iridium-based material. Electrode segments can be obtained from this elongated electrode material wire and incorporated into a spark plug in a variety of ways.
In another embodiment, the method includes providing a layered structure that includes (1) a core of a ruthenium-based material, (2) an interlayer of an iridium-based material disposed over an exterior surface of the ruthenium-based material core, and (3) a nickel-based cladding over an exterior surface of the iridium-based interlayer. The method also calls for hot-drawing and annealing the layered structure, and repeating those steps at least once, to form an elongated layered wire. The nickel-based cladding is eventually removed from the elongated layered wire to derive an elongated electrode material wire that includes the ruthenium-based material core encased in the iridium-based material. And, like before, electrode segments can be obtained from this elongated electrode material wire and incorporated into a spark plug in a variety of ways.
Also disclosed is an electrode segment for use in a spark plug that can be manufactured by any of the methods disclosed herein.
Preferred exemplary embodiments of the invention will hereinafter be described in conjunction with the appended drawings, wherein like designations denote like elements, and wherein:
The electrode material described herein may be used in spark plugs and other ignition devices including industrial plugs, aviation igniters, glow plugs, or any other device that is used to ignite an air/fuel mixture in an engine. This includes, but is certainly not limited to, the exemplary spark plugs that are shown in the drawings and are described below. Furthermore, it should be appreciated that the electrode material may be used in an electrode segment that is part of a firing tip attached to a center and/or ground electrode or it may be used in the actual center and/or ground electrode itself, to cite several possibilities. Other embodiments and applications of the electrode material are also possible. All percentages provided herein are in terms of weight percentage (wt %).
Referring to
In this particular embodiment, the first component 32 of the center electrode firing tip 20 and/or the ground electrode firing tip 30 may be made from the electrode material described herein; however, these are not the only applications for the electrode material. For instance, as shown in
Again, it should be appreciated that the non-limiting spark plug embodiments described above are only examples of some of the potential uses for the electrode material. For instance, the following components may be formed from the electrode material: center and/or ground electrodes; center and/or ground electrode firing tips that are in the shape of rivets, cylinders, bars, columns, wires, balls, mounds, cones, flat pads, disks, rings, sleeves, etc.; center and/or ground electrode firing tips that are attached directly to an electrode or indirectly to an electrode via one or more intermediate, intervening or stress-releasing layers; center and/or ground electrode firing tips that are located within a recess of an electrode, embedded into a surface of an electrode, or are located on an outside of an electrode such as a sleeve or other annular component; or spark plugs having multiple ground electrodes, multiple spark gaps or semi-creeping type spark gaps. These are but a few examples of the possible applications of the electrode material, as others certainly exist.
The electrode material is a ruthenium-based material core encased in a layer of iridium or an iridium alloy. The term “ruthenium-based material,” as used herein, broadly includes any material in which ruthenium (Ru) is the single largest constituent on a weight percentage (%) basis. This may include materials having greater than 50 wt % ruthenium, as well as those having less than 50 wt % ruthenium so long as the ruthenium is the single largest constituent. One or more additional precious metals (ruthenium is considered a precious metal too) may also be included in the ruthenium-based material. Some examples of suitable additional precious metals are rhodium (Rh), iridium (Ir), platinum (Pt), palladium (Pd), gold (Au), and combinations thereof. Another possible constituent of the ruthenium-based material may be one or more refractory metals. Several suitable refractory metals that may be included in the ruthenium-based material are rhenium (Re), tungsten (W), and a combination of rhenium and tungsten, among others. It is also possible for the ruthenium-based material to include one or more rare earth metals or active elements like yttrium (Y), hafnium (Hf), scandium (Sc), zirconium (Zr), lanthanum (La), cerium (Ce), and/or other constituents. Besides ruthenium, the rutheniun-based material does not necessarily have to include any or all of the types of metals just mentioned (e.g., the additional precious metals, refractory metals, and rare earth metals are optional); it may include only one of those types of metals, a combination of two or more of those types of metals, all of those types of metals, or none of those types of metals, as will be appreciated by a skilled artisan.
The following embodiments are examples of different ruthenium-based materials from which any of the electrodes or electrode components shown in
The ruthenium-based material may include ruthenium and an additional precious metal such as, for example, at least one of rhodium, iridium, platinum, palladium, gold, or a combination thereof. Any of the following alloy systems may be appropriate: Ru—Rh, Ru—Ir, Ru—Pt, Ru—Pd, Ru—Au, Ru—Rh—Ir, Ru—Rh—Pt, Ru—Rh—Pd, Ru—Rh—Au, Ru—Ir—Pt, Ru—Ir—Pd, and Ru—Ir—Au. Some specific non-limiting examples of potential compositions for the ruthenium-based material include: Ru-(1-45)Rh; Ru-(1-45)Ir; Ru-(1-45)Pt; Ru-(1-45)Pd; Ru-(1-45)Au; Ru-(1-20)Rh-(1-20)Ir; Ru-(1-20)Rh-(1-20)Pt; Ru-(1-20)Rh-(1-20)Pd; Ru-(1-20)Rh-(1-20)Au; Ru-(1-20)Ir-(1-20)Pt; Ru-(1-20)Ir-(1-20)Pd; Ru-(1-20)Ir-(1-20)Au; Ru-(1-20)Pt-(1-20)Pd; Ru-(1-20)Pt-(1-20)Au; and Ru-(1-20)Pd-(1-20)Au. In the above compositional format, as well as the similar formats used below, the numerical ranges are expressed in weight percentage and Ru constitutes the balance.
In another embodiment, the ruthenium-based material may include ruthenium and at least one refractory metal such as rhenium, tungsten, or a combination of rhenium and tungsten. Rhenium and tungsten have melting points that are appreciably higher than ruthenium; thus, adding one or both of them to the ruthenium-based material can increase the overall melting temperature of the material. The melting point of rhenium is approximately 3180° C. and that of tungsten is around 3410° C. As those skilled in the art will appreciate, electrode materials having high melting temperatures are generally more resistant to electrical erosion in spark plugs, igniters, and other applications that are exposed to similar high-temperature environments. Anywhere from about 0.1 wt % to 10 wt % of rhenium, anywhere from 0.1 wt % to 10 wt % of tungsten, or anywhere from 0.1 wt % to 10 wt % of rhenium and tungsten combined, if both are present, is preferably included in the rutheniun-based material.
The inclusion of rhenium and tungsten may also provide the ruthenium-based material with other desirable attributes—such as increased ductility and greater control of grain growth because of an increased recrystallization temperature. The inclusion of rhenium and/or tungsten may improve the ductility of the rutheniun-based material by increasing the solubility of some interstitial components (interstitials like nitrogen (N), carbon (C), oxygen (O), sulfur (S), phosphorus (P), etc.) with respect to ruthenium. Affecting the solubility of the interstitials in this way can help keep the interstitials from congregating at low-energy grain boundaries which, in turn, can render the ruthenium-based material more ductile and workable—particularly during high-temperature metal forming processes—and less susceptible to erosion through grain cleavage. Although ruthenium-based materials could be produced that include one of rhenium or tungsten, but not both, the co-addition of rhenium and tungsten in the ruthenium-based material may have a synergistic effect that contributes to an improvement in ductility.
The presence of rhenium and tungsten can increase the recyrstallization temperature of the ruthenium-based material by 50° C.-100° C. due to the relatively high melting points of those two metals. An increase in the recrystallization temperature may be useful in controlling grain growth during certain hot forming processes like sintering, annealing, hot swaging, hot extruding, hot drawing, and even during use in a spark plug at high temperatures. For instance, the recyrstallization temperature of the ruthenium-based material, when at least one of rhenium or tungsten is added, may be found to be above 1400° C. Such an increase in the recyrstallization temperature provides a larger temperature window in which hot metal forming processes may be practiced—for example, to fabricate a wire from which any of the firing tips shown in
Some embodiments of a ruthenium-based material that comprise at least one refractory metal include from about 40 wt % to 99.9 wt % of ruthenium and from about 0.1 wt % to 10 wt % of rhenium, from about 0.1 wt % to 10 wt % of tungsten, or from about 0.1 wt % to 10 wt % of some combination of rhenium and tungsten. An exemplary alloy composition that may be particularly useful in the electrode material is Ru-(0.1-5)Re(0.1-5)W, such as Ru-1Re-1W, but of course others are certainly possible. In a number of the exemplary ruthenium-based materials just mentioned, as well as those described below, the ratio of rhenium to tungsten is 1:1. But this ratio is not required. Other ratios may indeed be used as well.
According to yet another embodiment, the ruthenium-based material may include ruthenium, an additional precious metal, and at least one refractory metal. The ruthenium-based material may include ruthenium from about 40 wt % to 99.9 wt %, an additional precious metal—other than ruthenium—from about 0.1 wt % to 40 wt %, and at least one refractory metal from about 0.1 wt % to 10 wt %, provided that ruthenium is the largest single constituent. A few exemplary alloy compositions that may be particularly useful in the electrode material are Ru(0.5-5)Rh-(0.1-5)Re, such as Ru-5Rh-1Re, Ru-(0.5-5)Rh-(0.1-5)W, such as Ru-5Rh-1W, and Ru-(0.5-5)Rh-(0.1-5)Re/W, such as Ru-5Rh-1Re-1W. The symbol Re/W as used herein refers to a combination of rhenium and tungsten. Thus, in the exemplary alloy “Ru-(0.5-5)Rh-(0.1-5)Re/W” set forth above, the combined weight percentage of rhenium and tungsten in the alloy ranges from 0.1 to 5.
In yet another embodiment, the ruthenium-based material may include ruthenium, a first additional precious metal, a second additional precious metal, and at least one refractory metal. The ruthenium-based material may include ruthenium from about 40 wt % to 99.9 wt %, a first additional precious metal—other than ruthenium—from about 0.1 wt % to 40 wt %, a second additional precious metal—other than ruthenium and the first additional precious metal—from about 0.1 wt % to 40 wt %, and a refractory metal from about 0.1 wt % to 10 wt %, provided that ruthenium is the largest single constituent. Some exemplary compositions that may be particularly useful in the electrode material are Ru-(0.5-5)Rh-(0.1-5)Ir-(0.5-5)Re, Ru-(0.5-5)Rh-(0.1-5)Ir-(0.5-5)W, Ru-(0.5-5)Rh-(0.1-5)Ir-(0.5-5)Re/W, and Ru-(1-10)Rh-(1-10)Ir-(0.5-5)Re-(0.5-5)W.
Depending on the particular properties that are desired, and as demonstrated above, the amount of ruthenium in the ruthenium-based material may be: greater than or equal to 40 wt %, 50 wt %, 65 wt %, or 80 wt %; less than or equal to 99.9 wt %, 95 wt %, 90 wt %, or 85 wt %; or between 40-99.9 wt %, 50-99.9 wt %, 65-99 wt %, or 80-99 wt %, to cite a few examples. The amount of each additional precious metal (e.g., the first, second, third additional precious metal), moreover, so long as ruthenium is the single largest constituent, may be: greater than or equal to 0.1 wt %, 0.5 wt %, 1 wt %, or 2 wt %, less than or equal to 40%, 20%, 10%, or 5%; or between 0.1-40%, 0.1-10%, 0.5-10%, or 1-5%. Likewise, the amount of each refractory metal, so long as ruthenium is the single largest constituent and the total weight percentage of any combination of refractory metals does not exceed 10 wt %, may be: greater than or equal to 0.1 wt %, 0.5 wt %, 1 wt %, or 2 wt %; less than or equal to 10 wt %, 8 wt %, 6 wt %, or 5 wt %; or between 0.1-10 wt %, 0.5-9 wt %, 0.5-8 wt %, or 0.5-5 wt %. The preceding amounts, percentages, limits, ranges, etc. are only examples of the wide variety of ruthenium-based material compositions that are possible; they are not meant to limit the scope of the ruthenium-based material.
One or more rare earth metals may be added to any of the various ruthenium-based materials described above. The rare earth metal(s) employed may be any one of, or some combination of, yttrium (Y), hafnium (Hf), scandium (Sc), zirconium (Zr), lanthanum (La), or cerium (Ce), to name but a few. Those skilled in the art will appreciate that such metals can trap interstitial components in much the same way as the refractory metal(s). This trapping capability helps keep the interstitial components and other impurities from accumulating—due to their low solubility in ruthenium—as fine precipitates at the grain boundaries of the ruthenium-based material. And reducing the amount of interstitial compounds at the grain boundaries is thought to increase the ductility of the ruthenium-based material through several mechanisms including, most notably, pinning of the grain boundaries and grain growth inhibition during hot forming processes. The content of these rare earth metals in the ruthenium-based material preferably ranges from about 1 ppm to about 0.3 wt %.
The several embodiments of the ruthenium-based material described above exhibit favorable oxidation, corrosion, and erosion resistance that is desirable in certain ignition applications including, for instance, spark plugs designed for an internal combustion engine. The relatively high melting temperature (2334° C.) of ruthenium is believed responsible, at least in part, for some of these physical and chemical characteristics. But these embodiments also have a tendency to possess less-than-desirable room-temperature ductility—which affects how easily they can be fabricated or manufactured into a useable piece. For this reason, the ruthenium-based material might have to be clad with a more ductile material to accommodate fabrication, as desired, by a wide variety of hot metal forming processes and to avoid thermal shock.
A cladding that has been used before with other types of precious metal-based materials (e.g., Ir- and Pt-based) is a nickel-based material such a nickel-chromium-aluminum (Ni—Cr—Al) alloy or a nickel-iron-aluminum (Ni—Fe—Al) alloy. But while encasing a core of the ruthenium-based material with a nickel-based cladding and then hot-forming the structure can help fabricate the ruthenium-based material with greater ease, it can also promote structural defects on the surface of the ruthenium-based material core, which are generally undesirable for spark plug applications. Surface cracking of the ruthenium-based material core to a depth of up to about 25 μm is one particular structural defect that has been observed. Such surface cracking is believed to be caused by the diffusion of certain low-melting point alloy constituents—namely, aluminum—from the nickel-based cladding into the ruthenium-based material core at elevated temperatures. More specifically, the diffused alloy constituents are thought to react with the ruthenium-based material to produce an intermetallic phase that is present within the ruthenium-based material core adjacent to the interface between the core and the cladding. This intermetallic phase is relatively brittle, and thus, susceptible to cracking when the types of stresses normally associated with hot forming are applied. For example,
A method of manufacturing the electrode material into a desired form that is suitable to derive a firing tip, a spark plug electrode and/or some other firing end component is graphically and schematically illustrated in
The disclosed method helps avoid the diffusion of low-melting point alloy constituents into the ruthenium-based material core 80 during hot-forming and, additionally, may be practiced in a way that improves the high-temperature erosion resistance of the resultant elongated electrode material wire 94 by generating a “fibrous” grain structure in the ruthenium-based material core 80, as will be further explained below. The term “iridium-based material,” as used herein, broadly includes any material in which iridium (Ir) is the single largest constituent on a weight percentage (%) basis. This may include materials having greater than 50 wt % iridium, as well as those having less than 50 wt % iridium so long as the iridium is the single largest constituent. Similarly, the term “nickel-based material,” as used herein, broadly includes any material in which nickel (Ni) is the single largest constituent on a weight percentage (%) basis. This may include materials having greater than 50 wt % nickel, as well as those having less than 50 wt % nickel so long as the nickel is the single largest constituent.
The forming step 210 is preferably carried out by a powder metallurgy process, as graphically illustrated in
Next, in step 214, the powders may be blended together to form a powder mixture. In one embodiment, for example, the powder mixture includes from about 40 wt % to 99.9 wt % of ruthenium, from about 0.5 wt % to 5 wt % of rhodium, from about 0.1 wt % to 5 wt % iridium, and from about 0.1 wt % to 5 wt % rhenium and/or tungsten, regardless of whether a pre-alloyed base powder was formed or not. This mixing step may be performed with or without the addition of heat.
The sintering step 216 transforms the powder mixture into the ruthenium-based material core 80 through the application of heat. The sintering step 216 may be performed according to a number of different metallurgical embodiments. For instance, the powder mixture may be sintered for up to several hours at an appropriate sintering temperature in a vacuum, in a reduction atmosphere such as in a hydrogen-contained environment, or in some type of protected environment. Oftentimes an appropriate sintering temperature lies somewhere in the range of about 1350° C. to about 1650° C. for the ruthenium-based powder mixture. It is also possible for the sintering step 216 to apply pressure in order to introduce some type of porosity control. The amount of pressure applied may depend on the precise composition of the powder mixture and the desired attributes of the ruthenium-based material core 80.
The ruthenium-based material core 80 that results following the sintering step 216 is preferably shaped as a bar or other elongated structure. The length L of the bar represents the longitudinal—and largest—dimension of the bar, and the cross-sectional area CA is the planar surface area of an end 98 of the bar when sectioned perpendicular to the length L dimension, as depicted generally in
The forming step 210 may also be practiced using other forming procedures besides powder metallurgy, if desired. For example, the ruthenium-based material core 80 may be formed by spray forming. Spray forming broadly refers to a wide variety of metallurgical procedures in which an alloy liquid of the ruthenium-based material is sprayed onto a shaped substrate to form the ruthenium-based material core 80. Other procedures known to skilled artisans may also be employed to form the ruthenium-based material core 80, despite not being described in more detail here.
The exterior surface 84 of the ruthenium-based material core 80 may now be prepared, if desired, to receive the interlayer 82, as indicated by optional step 280. Such preparation is generally directed to cleaning and smoothing the exterior surface 84 so that a strong retention capacity can be realized at the interface of the interlayer 82 and the core 80. The exterior surface 84 of the ruthenium-based material core 80 may be polished, sanded, ground, acid washed, or subjected to any other surface treatment that can remove grease and other undesirable surface contaminants from the exterior surface 84.
Following the forming step 210 (and the preparation step 280 if practiced), the iridium-based interlayer 82 is disposed over, and preferably into direct contact with, the exterior surface 84 of the ruthenium-based material core 80, as graphically depicted in step 220. The iridium-based interlayer 82 may be comprised entirely (100 wt %) of iridium, or it may be an iridium alloy that includes greater than about 50 wt %, greater than about 75 wt %, or greater than about 90 wt % iridium. A few preferred compositions of the iridium-based interlayer 82 are about 100 wt % iridium, an iridium alloy that includes rhodium (Rh), such as Ir-(1-10)Rh, an iridium alloy that includes platinum (Pt), such as Ir-(2-20)Pt, an iridium alloy that includes palladium (Pd), such as Ir-(5-20)Pd, an iridium alloy that includes ruthenium (Ru), such as Ir-(0.5-10)Ru, and an Ir—Pt—Rh—Ru—Pd alloy in which iridium is the largest element on a weight percent basis. Again, as before, the numerical ranges in the compositional formats recited above are expressed in weight percentage with Ir constituting the balance.
The iridium-based interlayer 82 has a thickness T1 that typically ranges from about 50 μm to about 2 mm—more preferably from about 50 μm to about 500 μm—when initially applied. Disposing the iridium-based interlayer 82 over the exterior surface 84 of the ruthenium-based material core 80 at this thickness establishes a diffusion barrier that keeps low-melting point elements (e.g., aluminum) that may be present in the nickel-based cladding 88 from diffusing into the ruthenium-based material core 80. The interlayer 82 can function as a diffusion barrier because the iridium-based material—which has a relatively high melting point—renders it heat-, wear-, and chemically-resistant at the types of temperatures encountered during the hot-forming step 240. As such, low-melting point alloy constituents that may diffuse from the nickel-based cladding 86 during hot-forming are unable to infiltrate the interlayer 82 and diffuse into the ruthenium-based material core 80 in quantities sufficient to produce a brittle intermetallic phase. Perhaps equally noteworthy is the fact that the iridium-based interlayer 82 does not make the underlying ruthenium-based material core 80 exceedingly difficult to hot-form. The thickness T1 of the interlayer 82, while sufficient to serve as a diffusion barrier, is also moderate enough that hot-forming the layered structure 90 is not overly cumbersome.
Any suitable procedure may be used to dispose the iridium-based interlayer 82 over the exterior surface 84 of the ruthenium-based material core 80. Some available procedures that may be employed include co-extrusion, laser cladding, electroplating, electroless plating, plasma spray physical vapor deposition, magnetron sputtering, microwave assisted chemical vapor deposition, plasma enhanced chemical vapor deposition, mechanically inserting the core 80 into a pre-formed hollow interlayer 82, or any other type of extrusion, electrodeposition, physical vapor deposition, chemical vapor deposition, or other procedure that is able to situate the interlayer 82 over the core 80.
The nickel-based cladding 86 is disposed over, and preferably into direct contact with, the exterior surface 88 of the iridium-based interlayer 82 to form the layered structure 90, as graphically depicted in step 230. The nickel-based cladding 86 may be a nickel-chromium-aluminum (Ni—Cr—Al) alloy or a nickel-iron-aluminum alloy (Ni—Fe—Al). Any suitable procedure may be used to dispose the nickel-based cladding 86 over the exterior surface 88 of the interlayer 82. For example, the nickel-based cladding 86 may be extruded or otherwise fabricated into a hollow tube, and the combination core 80 and interlayer 82 structure may be inserted into the hollow tube to achieve a tight fit, thus producing the layered structure 90 shown in
The layered structure 90 is then hot-formed, as graphically represented by step 240, to reduce the cross-sectional area CA of the ruthenium-based material core 80—and, coincidentally, to increase its length L—to form the elongated layered wire 92. The cross-sectional area CA of the ruthenium-based material core 80 may be reduced by at least 60%, at least 80%, or at least 95%, with cross-sectional area reductions greater than 99% not being uncommon. The hot-forming step 240, as further described below, preferably includes a hot-swaging step 242, at least one hot-drawing step 244, and at least one annealing step 246, as shown graphically in
The hot-swaging step 242 involves radially hammering or forging the layered structure 90 at a temperature above the ductile-brittle transition temperature of the ruthenium-based material. A temperature that lies in the range of about 900° C. to about 1500° C. is usually sufficient for this purpose. The heated compressive metalworking that takes place during hot-swaging reduces the cross-sectional area CA of the ruthenium-based material core 80 and, consequently, effectuates work-hardening of the entire layered structure 90. The cross-sectional area CA of the ruthenium-based material core 80 may be reduced by about 30% to about 80%. For example, the exemplary ruthenium-based cylindrical bar preferably formed as the core 80 by the powder metallurgy process (steps 212-216) may, following a 75% reduction in cross-sectional area by hot-swaging, have a cross-sectional area CA of about 79 mm2 (about 10 mm diameter) and a length of about 4 m.
The hot-drawing step 244 includes drawing the layered structure 90—after hot-swaging—through an opening defined in a heated draw plate. The draw plate opening is appropriately sized to further reduce the cross-sectional area CA of the ruthenium-based material core 80. The temperature of the draw plate may be maintained at a temperature that heats the ruthenium-based material above its ductile-brittle transition temperature. Heating the draw plates so that the temperature of the ruthenium-based material core 80 ranges from about 900° C. to about 1300° C. is typically sufficient for conducting hot-drawing of the layered structure 90. The hot-drawing step 244 may further reduce the cross-sectional area of the ruthenium-based material core 80 by up to about 75%, preferably from about 20% to about 50%, with each pass through the draw plate. For example, the exemplary ruthenium-based cylindrical bar preferably formed by the powder metallurgy process (steps 212-216) and the hot-swaging process (step 242) may, following another 75% cross-sectional area reduction by a single hot-drawing pass, have a cross-sectional area of about 20 mm2 (about 5 mm diameter) and a length of about 16 m.
The hot-drawing step 244 may generate a “fibrous” grain structure in the ruthenium-based material core 80 along its length L dimension (i.e., the elongation axis of the layered structure 90) as the layered structure 90 is pulled through the heated die plate opening. An example of the “fibrous” grain structure (or elongated grain structure) is shown generally and schematically in
The “fibrous” grain structure 130 may improve the room-temperature ductility and high-temperature durability of the ruthenium-based material compared to other grain structures. The improved ductility makes the ruthenium-based material core 80 more workable and, thus, easier to fabricate into the elongated layered wire 94, while the improved durability helps mitigate erosion if the ruthenium-based material core 80 is exposed to high-temperature environments when used as part of a spark plug. The “fibrous” grain structure 130 is believed to improve ductility and reduce inter-granular grain loss by inhibiting crack propagation transverse to the axial dimensions 132A of the grains 132. This so-called “crack blunting” phenomenon is illustrated in
The cross-sectional area reductions achieved during the hot-swaging step 242 and the hot-drawing step 244 generally require annealing of the layered structure 90, as graphically represented in step 246, to permit further hot-forming. Annealing the layered structure 90 involves heating it for a period of several seconds to several minutes to relieve material stresses. Heating the layered structure 90 to a temperature above about 1000° C., for example, is generally sufficient. The layered structure 90 may be annealed at least once for every 75% reduction—more preferably at least once for every 50% reduction—in the cross-sectional area CA of the ruthenium-based material core 80. This means that the layered structure 90 may be annealed after each of the hot-swaging step 242 and the hot-drawing step 244, or after the hot-drawing step 244 only, depending on the cross-sectional area reduction attained during hot-swaging.
The layered structure 90 is preferably annealed during hot-forming—in particular after the hot-drawing step 244—in a manner that preserves the “fibrous” grain structure 130. This may involve annealing the layered structure 90 at a temperature below the recrystallization temperature of the ruthenium-based material that comprises the core 80. An annealing temperature between about 1000° C. to about 1500° C. is generally sufficient to prevent loss of the “fibrous” grain structure 130. The inclusion of the refractory metal(s) (Re and/or W, for example) in the ruthenium-based material, moreover, makes preserving the “fibrous” grain structure 130 that much easier on account of those metals' ability to increase the recrystallization temperature of the ruthenium-based material. Any annealing that may be required after the hot-swaging step 242, but before the hot-drawing step 244, may be performed with less attention paid to the effects of recrystallization since the “fibrous” grain structure 130 sought to be preserved is likely not present at that time.
The hot-drawing step 244 and the annealing step 246 may be repeated one or more times to derive the elongated layered wire 92. That is, the layered structure 90 may be hot-drawn, then annealed to relieve internal stress, then hot-drawn again, then annealed again, and so on, until the elongated layered wire 92 has reached the desired size, with annealing being performed at least once for every 75% reduction in the cross-sectional area CA of the ruthenium-based material core 80. Multiple hot-drawing operations—in which the layered structure 90 is drawn through successively smaller heated die plate openings—may have to be performed in conjunction with intermittent annealing because the ruthenium-based material core 80 may only be able to withstand a certain amount of cross-sectional area reduction during a single pass before suffering undesirable structural damage. The cross-sectional area CA of the ruthenium-based material core 80 in the elongated layered wire 92 may vary widely. For example, the exemplary ruthenium-based cylindrical bar preferably formed by the powder metallurgy process (steps 212-216), the hot-swaging process (step 242), and a single hot-drawing process (step 244), following another 98% cross-sectional area reduction by several hot-drawing processes (step 244), may have a cross-sectional area of about 0.4 mm2 (about 0.7 mm diameter) and a length of about 816 m, assuming the layered structure 90 was not severed into smaller portions along the way.
After the elongated layered wire 92 is produced by the hot-forming step 240, the nickel-based cladding 86 may be removed from the iridium-based interlayer 82 and the ruthenium-based material core 80, as graphically represented in step 250, to derive the elongated electrode material wire 94. Any suitable physical and/or chemical procedure may be practiced to remove the nickel-based cladding 86. Chemical etching is one particular way in which the cladding 86 may be removed. The nickel-based cladding 86 may be etched with an acid. A few examples of acids that may be used are HCl and HNO3. The use of known mechanical measures to separate and peel overlying nickel-based cladding 86 away from the interlayer 82 may also be practiced in addition to, or in lieu of, chemical etching. Of course other procedures that can remove the nickel-based cladding 86 may be practiced as well despite not being mentioned here.
The elongated electrode material wire 94 may now be cut to form one or more electrode segments 96 as graphically represented in step 260. The electrode segment 96—many of which may be cut from the elongated electrode material wire 94—may be sized and shaped for use as any of the electrodes or firing tips configurations shown in
The electrode segment 96 obtained from the elongated electrode material wire 94 may be incorporated into spark plug in step 270. Following hot-forming (step 240) and removal of the nickel-based cladding 86 (step 250), for example, the ruthenium-based material core 80 of elongated electrode material wire 94 may have a cross-sectional area between 0.031 mm2 and 3.14 mm2 (about 0.2 mm and 2.0 mm diameter if cylindrical), preferably 0.07 mm2 (about 0.30 mm diameter if cylindrical) to about 0.95 mm2 (about 1.1 mm diameter if cylindrical), with the thickness T1 of the iridium-based interlayer 82 now ranging from about 1 μm to about 200 μm. One specific embodiment of the elongated electrode material wire 94 that may be useful is a cylindrical-shaped wire characterized by a cross-sectional area of the ruthenium-based material core 80 of about 0.4 mm2 (0.70 mm diameter). An individual electrode segment 96 of a desired length may be cut from the wire 94 of this general size (0.07 mm2≦CA≦0.95 mm2), as indicated in step 260, and then be directly used as a firing tip component attached to a center electrode, a ground electrode, an intermediate component, etc. In particular, the individually cut electrode segment 96 may be used as the firing tip component 32 attached to the intermediate component 34 on the center electrode 12 depicted in
If the ruthenium-based material core 80 of the elongated electrode material wire 94 includes the “fibrous” grain structure 130, as discussed earlier, then the electrode segment 96 (shown here without the iridium-based material cladding) is preferably employed in any of the spark plugs shown in
It is to be understood that the foregoing is a description of one or more preferred exemplary embodiments of the invention. The invention is not limited to the particular embodiment(s) disclosed herein, but rather is defined solely by the claims below. Furthermore, the statements contained in the foregoing description relate to particular embodiments and are not to be construed as limitations on the scope of the invention or on the definition of terms used in the claims, except where a term or phrase is expressly defined above. Various other embodiments and various changes and modifications to the disclosed embodiment(s) will become apparent to those skilled in the art. All such other embodiments, changes, and modifications are intended to come within the scope of the appended claims.
As used in this specification and claims, the terms “for example,” “e.g.,” “for instance,” “such as,” and “like,” and the verbs “comprising,” “having,” “including,” and their other verb forms, when used in conjunction with a listing of one or more components or other items, are each to be construed as open-ended, meaning that the listing is not to be considered as excluding other, additional components or items. Other terms are to be construed using their broadest reasonable meaning unless they are used in a context that requires a different interpretation.
This application claims the benefit of U.S. Provisional Application No. 61/780,254, filed on Mar. 13, 2013, the contents of which are hereby incorporated by reference in their entirety.
Number | Date | Country | |
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61780254 | Mar 2013 | US |