US2783409A - Spark plug electrode and process for making same - Google Patents

Spark plug electrode and process for making same Download PDF

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US2783409A
US2783409A US279611A US27961152A US2783409A US 2783409 A US2783409 A US 2783409A US 279611 A US279611 A US 279611A US 27961152 A US27961152 A US 27961152A US 2783409 A US2783409 A US 2783409A
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sheath
electrode
core
spark plug
tip
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Taine G Mcdougal
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Motors Liquidation Co
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General Motors Corp
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01TSPARK GAPS; OVERVOLTAGE ARRESTERS USING SPARK GAPS; SPARKING PLUGS; CORONA DEVICES; GENERATING IONS TO BE INTRODUCED INTO NON-ENCLOSED GASES
    • H01T21/00Apparatus or processes specially adapted for the manufacture or maintenance of spark gaps or sparking plugs
    • H01T21/02Apparatus or processes specially adapted for the manufacture or maintenance of spark gaps or sparking plugs of sparking plugs

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  • This invention relates to spark plugs for internal combustion engines of the type consisting of a central electrode provided with a surrounding insulator of some suitable ceramic land a metal shell which carries a ground electrode positioned in spaced relationship to the end of the central electrode to form a spark gap. More particularly, this invention relates to an improved spark plug central electrode and to a process for making same.
  • spark plug electrodes are subject to wear and general deterioration due to both erosion and corrosion. Erosion is the mechanical wearing away and burning of thc electrodes caused by the action of the spark. Electrode corrosion is produced by the action of various carbon, lead, and sulfur compounds, oxygen, water, etc., which are present in the combustion gases land which, under the conditions of spark plug operation, react with the electrode material.
  • the problem of electrode wear with resulting spark plug failure is greatly increased by the development of modern high compression internal combustion engines which operate at higher temperatures than the older and more conventional types. Therefore, the development of these high operating temperature high compression engines, particularly for use in aircraft but also for use in automobiles and the like, has required a corresponding development in spark plug design and, Vin particular, in the choice of materials and design for the spark plug electrodes.
  • platinum is particularly suitable as an electrode material. Platinum, however, is a scarce metal and is therefore quite costly. Because of this high cost it has been the practice to utilize a composite centerwire electrode consisting of a silver or silver alloy positioned in the centerbore of the spark plug insulator and provided with a platinum firing tip. in this manner, the high heat conductivity of the silver ⁇ and the high wear resistance of platinum are utilized in combination. For such a structure, however, a considerable amount of platinum has to be used since the platinum ring tip must extend a good distance into the silver wi-re in order to be iirmly anchored. At the same time the silver alloy itself is quite expensive and thus the overall cost of the electrode is quite high. Even -aside ⁇ from the question of cost, however, such an electrode becomes quite impractical during times of scarcity of platinum and silver.
  • Another object of the invention is the provision of a spark plug electrode having a very long life and having a relatively low cost.
  • Still another object of the invention is the provision of a simple and economical method 'for making composite spark plug electrodes which have high wear resistance and excellent heat conductivity.
  • Figure l shows a spark plug vhaving a metal outer shell 6 carrying a ground electrode 8 of platinum or other suitable metal and enclosing and supporting an insulator 10 which is provided with a centerbore 12.
  • the lower end of the centerbore 12 is of reduced diameter as shown at 13, thereby providing an annular -shoulder 14 within the bore.
  • a metal gasket 11 is positioned between the insulator shoulder'and the outer shell ange to rmly secure the insulator in the shell and to seal the assembly.
  • the centerwire including the central electrode structure 16 to which this invention chiey relates.
  • the composite central electrode lo consists of a core 18 of a metal having a high heat conductivity enclosed by a tubular sheath 20 of a metal having a high resistance to the heat, corrosion and erosion, and a noble metal tiring tip 22. ⁇ secured to the base of the sheath 2# and in heat and electrical conducting contact with the core 18.
  • the tip 2?. consistsof 'the noble metal, platinum. it is to be understood that ⁇ by the term platinum I mean to inciude the various platinum rich alloys and by the term noble metal I mean to include the various noble metal rich alloys which may be used as electrode materials.
  • the firing tip 22 has a shank portion 24 which extends to the exterior of the sheath 2d, and the head portion 26 within the sheath 20.
  • a circumferential portion 2S of the bottom of the head 26 engages an inwardly extending annular flange 3i) on the base of 'the sheath Ztl, thus retaining Athe tiring tip in place.
  • the top of the tubular sheath is formed into a head portion 32, thereby providing an outwardly extending annular shoulder 3st which engages the shoulder 14 on the interior'ot" the centerbore of. the insulator 18.
  • a knurled surface 38 is provided on the exterior of the sheath for purposes set forth in United States Patent 2,350,396 granted .lune 6, i944, to Gretzinger et al.
  • the metal core is preferably alloyed to the sheath, thereby providing the optimum of heat and electrical conductivity.
  • slot 50 which serves to better secure the central electrode in position.
  • the slot 50 exposes a greater 'surface to the glass seal 40 thereby aiding thev dissipation of heat.
  • the glassseal 40 and resistor 42 are fused or softened in the bore by the application of heat, whereupon the centerwire screw 48 is pressed into place and top ofthe electrode head v32 isbifurcated to provide a the seal allowed to harden.
  • copper As the material for the electrode core 18.
  • copper i means to include also the various alloys which are predominantly copper and which are soft and have about the same functional characteristics of heat and electrical conductivity as copper.
  • the sheath may be either pure nickel or a nickel alloy. I have found that either pure nickel or an alloy containing from about 78 to 100% nickel, about 0 to 20% chromium, and about 0 to 2% manganese, is particularly suitable as a sheath material. The following will serve as examples of specific alloys within this range:
  • the use of small amounts of manganese is advantageous in that it facilitates the working of the metal. In general, the use of nickel with or without a small.
  • the shell 52 carrying a ground electrode 54 and enclosing andsupporting a ceramic insulator 55.
  • the insulator has a centerbore 56, the end of which is of reduced diameter as shown at S7, thus providing a shoulder 58 in the bore.
  • the composite electrode 60 which is positioned in the centerbore 56. consists of a headed platinum or other noble metal tip 62, a nickel or nickel alloy sheath 64 with an inwardly extending annular ange 65 to support the tiring tip, and a core 66 preferably of copper.
  • the surface of the core 66 is alloyed to the surface of the sheath 64.
  • the firing tip head 68 is not as thick as that shown in Figure 1 and thus does not require the use of as much metal.
  • the sheath head 70 has an upper portion of reduced diameter as ⁇ shown at 72.
  • the resulting annular shoulder 74 cooperates with the shoulder l58 in the insulator centerbore to retain the electrode in position.
  • the upper portion of the centerwise structure is conventional, 76 being a conductive glass seal, 78 a centerbore screw embedded in the glass seal 76, and 80 a cartridge-type resistor which is held against the centerbore screw by some means (not shown) and Which is in electrical contact with the lead from the ignition Wiring sys tcm.
  • the top of the head 7i? is provided with a slot 82 to give additional heat conducting surface contact between the core of the electrode and the conductive glass seal 7 6, and to better secure the central electrode in position.
  • the sheath is first formed by drilling a blind hole axially in a suitably dimensioned rod of the desired nickel or nickel alloy and then drilling a concentric second hole of smaller diameter in the end of the rod to receive the shank of the tiring tip.
  • the resulting tubularsheath will be provided with an inwardly extending annular flange at one end.
  • the sheath, firing tip, and core are then assembled as shown in Figure 2.
  • the ring tip 86 is inserted into the sheath 88 so that the tiring tip shank 90 extends through the smaller hole 92 and the tiring tip head 94 rests against the inwardly extending sheath ange 96.
  • the core 98 is inserted into the sheath.
  • the core rod 98 is of suflicient length to provide enough metal to completely lill the sheath during the steps of the process which follow.
  • the thus assembled electrode is then swaged in order to pack the core material and bind the parts into a unit.
  • This swaging operation may be performed by placing the assembly in a slightly tapered bore and applying blows to the end of the core rod. Some of the force from the -blows is utilized in pushing the entire assembly into the bore, thus forcing the sheath inwardly against the core. Most of the force is utilized in packing the core metal to force it intimately against the sheath and tiring tip head. When the swaging is complete, the thickness of the sheath walls will be reduced somewhat and the core will be firmly packed, no excess metal extending beyond the top of the sheath.
  • the unit is then heat treated in a reducing atmosphere, such as one consisting of hydrogen, at just below the melting point of the core metal.
  • a reducing atmosphere such as one consisting of hydrogen
  • a temperature of from about l850 to 1900 F. is suitable. This heating step causes the adjacent surfaces of the core and the nickel or nickel alloy sheath to alloy by diffusion.
  • a heading operation is used to form the top or head portion on the electrode.
  • the electrode is placed in a hole or die cavity, the contour of which matches the contour of the desired electrode shape.
  • the hole therefore, will have a top portion of increased diameter the same size as that of the desired head.
  • Pressure is applied to the top of the electrode by hammer blows or otherwise to force the metal against the walls of the cavity to form the sheath head.
  • a head of the type shown in Figure 4 that is, a head with a circumferentially relieved upper portion such as is shown at 72 in Figure 4, .
  • the required machining may be accomplished at this stage of the process. This machining can be performed by any method known in the art.
  • a circumferential knurled portion on the electrode as shown at 38 in Figure l this may be accomplished after the heading operation by any suitable means known in the metal working art.
  • the last step of the process is that of cutting the trans verse slot in the top of the head. This cutting operation may be performed in any suitable manner.
  • Figure 3 shows a finished electrode of the type shown in Figure l after completion of the above described process, 100 being the tubular sheath, 102 the core and 104 the tiring tip.
  • the improved electrode of this invention By the improved electrode of this invention, excellent heat conducting properties are attained.
  • the highly conductive core conducts heat away from the tiring tip and bei dissipates it through the sheath and the glass seal.
  • the sheath consisting of the aforementioned nickel alloys, affords excellent protection against electrode wear. Utilization can be made of a platinum or other noble metal firing tip without the need for relatively large amounts of the metal. At the same time there is ample protection against loosening of the firing tip and resulting igniter failure. By means of the cooperation of the headed tip and flanged sheath, a secure and permanent positioning of the firing tip is assured.
  • a composite spark plug electrode comprising a tubular sheath of a material consisting of from 78 to 100% nickel, from to 20% chromium, and from 0 to 2% manganese, said sheath having an inwardly extending annular flange at one end thereof, a platinum firing tip having a head portion within said sheath and abutting said ange and a shank portion extending to the exterior of said sheath, and a copper core packed into said sheath and contacting said firing tip, said copper core and said sheath being diffusion alloyed substantially throughout the interface therebetween.
  • a composite spark plug electrode comprising a tubu lar sheath of high heat and wear resistant metal, said sheath having an inwardly extending annular ange formed as an integral part and at one end thereof, a platinum firing tip having a head portion within said sheath and abutting said ange and a shank portion extending to the exterior of said sheath and a copper core packed into said sheath and contacting said firing tip, said copper core and said sheath being diffusion alloyed substantially throughout the interface therebetween.
  • a composite spark plug electrode comprising a tubu lar sheath of an alloy consisting of about 96% nickel, about 2% chromium, and about 2% manganese, the bottom of said sheath having an inwardly extending annular flange formed as an integral part thereof and the top of said sheath having an external annular shoulder, a platinum tiring tip having a head portion within said sheath and abutting said flange and a shank portion extending to the exterior of said sheath, and a copper core packed into said sheath and contacting said firing tip, said copper core and said sheath being diffusion alloyed substantially throughout the interface therebetween and the top of said electrode being bifurcated to expose a greater surface area of said copper core.
  • a spark plug comprising a metal shell having a ground electrode secured to the base thereof, an insulator surrounded and supported by said shell, a centerbore in said insulator having a lower end of "reduced diameter to dene a shoulder therein, a composite electrode having a head portion abutting said shoulder to retain said electrode in said centerbore, said electrode comprising a tubular sheath consisting of about 96% nickel, 2% chromium, and 2% manganese, said sheath having an inwardly extending annular ange formed as an integral part therewith at one end thereof, a copper core packed into said sheath and a platinum firing tip having a head portion within said sheath and abutting said flange and a shank portion extending outside said sheath and in spaced relationship to said ground electrode to form a spark gap therebetween, said copper core and said sheath being diffusion alloyed substantially throughout the interface therebetween.
  • the method of making a spark plug electrode eom prising the steps of: forming a tubular sheath from an alloy containing about 96% nickel, 2% chromium, and 2% manganese, to provide an inwardly extending annular ange at one end thereof, positioning in said sheath a platinum firing tip having a headed portion and a shank portion so that said headed portion engages said flange and said shank portion extends to the exterior of said sheath, inserting a copper core in said sheath, swaging said electrode to reduce the wall thickness of said sheath and pack said copper into said sheath, heat treating said electrode in a reducing atmosphere at from 1850 to 1900 F. to alloy the surface of said core to the surface of said sheath and forming a head on said electrode.
  • the method of making a spark plug electrode comprising the steps of: forming a tubular sheath from a high heat and wear resistant metal to provide an inwardly extending annular ange at one end thereof, positioning in said sheath a platinum firing tip having a headed portion and a shank portion so that .said headed portion engages said flange and said shank portion extends to the exterior of said sheath, inserting a copper core in said sheath, swaging said electrode to reduce the wall thickness of said sheath and pack said copper into said sheath, heat treating said electrode in a reducing atmosphere at from 1850 to 1900 F. to alloy the surface of said core to the surface of said sheath, and forming a. head on said electrode.

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Description

Feb. 26, 1957 T. G. McDoUGAL 2,783,409
SPARK PLUG ELECTRODE AND PROCESS P0P MAKING SAME Filed March s1, 1952 4l Z5@ am; @ai
@www SPARK PLUG ELECTRODE AND PROCESS FOR MAKING SAME Taine G. McDougal, Flint, Mich., assignor to General Motors Corporation, Detroit, Mich., a corporation of Delaware Application March 31, 1952, Serial No. 279,611
6 Claims. (Cl. 313-141) This invention relates to spark plugs for internal combustion engines of the type consisting of a central electrode provided with a surrounding insulator of some suitable ceramic land a metal shell which carries a ground electrode positioned in spaced relationship to the end of the central electrode to form a spark gap. More particularly, this invention relates to an improved spark plug central electrode and to a process for making same.
As is well known, spark plug electrodes are subject to wear and general deterioration due to both erosion and corrosion. Erosion is the mechanical wearing away and burning of thc electrodes caused by the action of the spark. Electrode corrosion is produced by the action of various carbon, lead, and sulfur compounds, oxygen, water, etc., which are present in the combustion gases land which, under the conditions of spark plug operation, react with the electrode material. The problem of electrode wear with resulting spark plug failure is greatly increased by the development of modern high compression internal combustion engines which operate at higher temperatures than the older and more conventional types. Therefore, the development of these high operating temperature high compression engines, particularly for use in aircraft but also for use in automobiles and the like, has required a corresponding development in spark plug design and, Vin particular, in the choice of materials and design for the spark plug electrodes.
Because of its very high resistance lto both erosion and corrosion under the most extreme temperatures, platinum is particularly suitable as an electrode material. Platinum, however, is a scarce metal and is therefore quite costly. Because of this high cost it has been the practice to utilize a composite centerwire electrode consisting of a silver or silver alloy positioned in the centerbore of the spark plug insulator and provided with a platinum firing tip. in this manner, the high heat conductivity of the silver` and the high wear resistance of platinum are utilized in combination. For such a structure, however, a considerable amount of platinum has to be used since the platinum ring tip must extend a good distance into the silver wi-re in order to be iirmly anchored. At the same time the silver alloy itself is quite expensive and thus the overall cost of the electrode is quite high. Even -aside `from the question of cost, however, such an electrode becomes quite impractical during times of scarcity of platinum and silver.
it is an object of this invention to provide a spark plug which is highly resistant to wear by corrosion and erosion and is `also resistant to the high temperatures at which modern internal combustion engines operate. Another object of the invention is the provision of a spark plug electrode having a very long life and having a relatively low cost. Still another object of the invention is the provision of a simple and economical method 'for making composite spark plug electrodes which have high wear resistance and excellent heat conductivity.
These objects are carried out in accordance with the nted States PatentN "t" 2,783,409 4 y Patented Feb. 261957 present invention by the provision lof a spark plug elecpear lmore clearly from `the following description of spe-` ciic embodiments of v.the invention and from `the accompanying drawings in which Figure l is a side view with parts broken away of an embodiment of the invention; Figure 2 is a side view With-parts broken away of the Yelectrode parts as they appear in an early stage in the process for producing the electrodes; Figure 3 is a side view with parts broken away of the completed electrode as lit appears `after the final step in the process; and Figure 4 is a side view with parts broken away of another embodiment of the invention.
Referring now to the drawing, Figure l shows a spark plug vhaving a metal outer shell 6 carrying a ground electrode 8 of platinum or other suitable metal and enclosing and supporting an insulator 10 which is provided with a centerbore 12. The lower end of the centerbore 12 is of reduced diameter as shown at 13, thereby providing an annular -shoulder 14 within the bore. A metal gasket 11 is positioned between the insulator shoulder'and the outer shell ange to rmly secure the insulator in the shell and to seal the assembly. Located v ithin the centerbore 12 is the centerwire including the central electrode structure 16 to which this invention chiey relates.
The composite central electrode lo consists of a core 18 of a metal having a high heat conductivity enclosed by a tubular sheath 20 of a metal having a high resistance to the heat, corrosion and erosion, and a noble metal tiring tip 22.` secured to the base of the sheath 2# and in heat and electrical conducting contact with the core 18. In the preferred embodiment or' the invention, the tip 2?. consistsof 'the noble metal, platinum. it is to be understood that` by the term platinum I mean to inciude the various platinum rich alloys and by the term noble metal I mean to include the various noble metal rich alloys which may be used as electrode materials.
The firing tip 22 has a shank portion 24 which extends to the exterior of the sheath 2d, and the head portion 26 within the sheath 20. A circumferential portion 2S of the bottom of the head 26 engages an inwardly extending annular flange 3i) on the base of 'the sheath Ztl, thus retaining Athe tiring tip in place. The top of the tubular sheath is formed into a head portion 32, thereby providing an outwardly extending annular shoulder 3st which engages the shoulder 14 on the interior'ot" the centerbore of. the insulator 18. in the modification shown in Figure l, a knurled surface 38 is provided on the exterior of the sheath for purposes set forth in United States Patent 2,350,396 granted .lune 6, i944, to Gretzinger et al. By
means of a heat treatment hereinafter described, the metal core is preferably alloyed to the sheath, thereby providing the optimum of heat and electrical conductivity.
I wish to call particular attention to Athe manner in which the firing tip 22 is secured to the sheath Ey lthe cooperation of the tiring tip head Z6 and the sheath flange 3i) there is complete assurance that the tip will remain securely in position. At the saine time a very small amount of platinum or other noble metal is required.
The remainder of the' centerwse construction follows conventional practices with 40 indicating an electrically conducting seal consisting of glass and a conducting powder; 42, a glass bonded resistance material; 44, a second electrically conducting seal; and 46, a third electrically conducting seal surrounding and gripping the lower threaded or grooved end of a centerwire screw 48, the
top of which (not shown) makes electrical contact with `the electrical lead from-the ignition wiring system. The
slot 50 which serves to better secure the central electrode in position. In addition, the slot 50 exposes a greater 'surface to the glass seal 40 thereby aiding thev dissipation of heat. The glassseal 40 and resistor 42 are fused or softened in the bore by the application of heat, whereupon the centerwire screw 48 is pressed into place and top ofthe electrode head v32 isbifurcated to provide a the seal allowed to harden. The various seal and resistance constructions are described and claimed in the following United States. patents: Schwartzwalder and Kirk, Patent 2,106,578 granted January 25, l938; Schwartzwalder and Rulka, Patent 2,248,415 granted July 8, 1941; and McDougal, Schwartzwalder and Rulka, Patent 2,459,282 granted January 18, 1949.
Because of its particularly high heat `and electrical conductivity and its relatively low cost, we prefer to use copper as the material for the electrode core 18. By the term copper, i means to include also the various alloys which are predominantly copper and which are soft and have about the same functional characteristics of heat and electrical conductivity as copper.
The sheath may be either pure nickel or a nickel alloy. I have found that either pure nickel or an alloy containing from about 78 to 100% nickel, about 0 to 20% chromium, and about 0 to 2% manganese, is particularly suitable as a sheath material. The following will serve as examples of specific alloys within this range:
98% nickel, 2% chromium, 98.5% nickel, 1% chromium, .5% manganese; and 96% nickel, 2% chromium, 2% manganese. The use of small amounts of manganese is advantageous in that it facilitates the working of the metal. In general, the use of nickel with or without a small.
shell 52 carrying a ground electrode 54 and enclosing andsupporting a ceramic insulator 55. The insulator has a centerbore 56, the end of which is of reduced diameter as shown at S7, thus providing a shoulder 58 in the bore. The composite electrode 60, which is positioned in the centerbore 56. consists of a headed platinum or other noble metal tip 62, a nickel or nickel alloy sheath 64 with an inwardly extending annular ange 65 to support the tiring tip, and a core 66 preferably of copper. The surface of the core 66 is alloyed to the surface of the sheath 64. It will be noted that the firing tip head 68 is not as thick as that shown in Figure 1 and thus does not require the use of as much metal. Also, in this embodiment, the sheath head 70 has an upper portion of reduced diameter as `shown at 72. The resulting annular shoulder 74 cooperates with the shoulder l58 in the insulator centerbore to retain the electrode in position. By the provision of this type of head, more surface contact is obtained between the electrode and the glass seal, thus facilitating the passage of heat away from the electrode.
The upper portion of the centerwise structure is conventional, 76 being a conductive glass seal, 78 a centerbore screw embedded in the glass seal 76, and 80 a cartridge-type resistor which is held against the centerbore screw by some means (not shown) and Which is in electrical contact with the lead from the ignition Wiring sys tcm. As in the embodiment shown in Figure l, the top of the head 7i? is provided with a slot 82 to give additional heat conducting surface contact between the core of the electrode and the conductive glass seal 7 6, and to better secure the central electrode in position.
To produce the composite electrode, the sheath is first formed by drilling a blind hole axially in a suitably dimensioned rod of the desired nickel or nickel alloy and then drilling a concentric second hole of smaller diameter in the end of the rod to receive the shank of the tiring tip. Thus, the resulting tubularsheath will be provided with an inwardly extending annular flange at one end.
The sheath, firing tip, and core, are then assembled as shown in Figure 2. The ring tip 86 is inserted into the sheath 88 so that the tiring tip shank 90 extends through the smaller hole 92 and the tiring tip head 94 rests against the inwardly extending sheath ange 96. Then the core 98 is inserted into the sheath. At this stage of the process there should be enough clearance between the parts to facilitate assembly. Thus, there is a slight clearance between the core and the sheath and in this regard it should be noted that the core rod 98 is of suflicient length to provide enough metal to completely lill the sheath during the steps of the process which follow.
The thus assembled electrode is then swaged in order to pack the core material and bind the parts into a unit. This swaging operation may be performed by placing the assembly in a slightly tapered bore and applying blows to the end of the core rod. Some of the force from the -blows is utilized in pushing the entire assembly into the bore, thus forcing the sheath inwardly against the core. Most of the force is utilized in packing the core metal to force it intimately against the sheath and tiring tip head. When the swaging is complete, the thickness of the sheath walls will be reduced somewhat and the core will be firmly packed, no excess metal extending beyond the top of the sheath.
The unit is then heat treated in a reducing atmosphere, such as one consisting of hydrogen, at just below the melting point of the core metal. When, as in the preferred embodiment, copper is used as the core metal, a temperature of from about l850 to 1900 F. is suitable. This heating step causes the adjacent surfaces of the core and the nickel or nickel alloy sheath to alloy by diffusion.
After the alloying step, a heading operation is used to form the top or head portion on the electrode. The electrode is placed in a hole or die cavity, the contour of which matches the contour of the desired electrode shape. The hole, therefore, will have a top portion of increased diameter the same size as that of the desired head. Pressure is applied to the top of the electrode by hammer blows or otherwise to force the metal against the walls of the cavity to form the sheath head.
If it is desired to form a head of the type shown in Figure 4, that is, a head with a circumferentially relieved upper portion such as is shown at 72 in Figure 4, .the required machining may be accomplished at this stage of the process. This machining can be performed by any method known in the art. Likewise, if it is desired to provide a circumferential knurled portion on the electrode as shown at 38 in Figure l, this may be accomplished after the heading operation by any suitable means known in the metal working art.
The last step of the process is that of cutting the trans verse slot in the top of the head. This cutting operation may be performed in any suitable manner.
Figure 3 shows a finished electrode of the type shown in Figure l after completion of the above described process, 100 being the tubular sheath, 102 the core and 104 the tiring tip.
While, for purposes of illustration of the various electrode parts, I have indicated in the drawing a distinct dividing line between the core and the sheath, it is to be understood that in the preferred embodiments the surface of the core is alloyed to the surface of the sheath, thus resulting in a unitary integral structure.
By the improved electrode of this invention, excellent heat conducting properties are attained. The highly conductive core conducts heat away from the tiring tip and bei dissipates it through the sheath and the glass seal. The sheath, consisting of the aforementioned nickel alloys, affords excellent protection against electrode wear. Utilization can be made of a platinum or other noble metal firing tip without the need for relatively large amounts of the metal. At the same time there is ample protection against loosening of the firing tip and resulting igniter failure. By means of the cooperation of the headed tip and flanged sheath, a secure and permanent positioning of the firing tip is assured.
Various changes and modifications of the embodiments of the invention described herein may be made by those skilled in the art without departing from the spirit and principles of the invention.
I claim:
1. A composite spark plug electrode comprising a tubular sheath of a material consisting of from 78 to 100% nickel, from to 20% chromium, and from 0 to 2% manganese, said sheath having an inwardly extending annular flange at one end thereof, a platinum firing tip having a head portion within said sheath and abutting said ange and a shank portion extending to the exterior of said sheath, and a copper core packed into said sheath and contacting said firing tip, said copper core and said sheath being diffusion alloyed substantially throughout the interface therebetween.
2. A composite spark plug electrode comprising a tubu lar sheath of high heat and wear resistant metal, said sheath having an inwardly extending annular ange formed as an integral part and at one end thereof, a platinum firing tip having a head portion within said sheath and abutting said ange and a shank portion extending to the exterior of said sheath and a copper core packed into said sheath and contacting said firing tip, said copper core and said sheath being diffusion alloyed substantially throughout the interface therebetween.
3. A composite spark plug electrode comprising a tubu lar sheath of an alloy consisting of about 96% nickel, about 2% chromium, and about 2% manganese, the bottom of said sheath having an inwardly extending annular flange formed as an integral part thereof and the top of said sheath having an external annular shoulder, a platinum tiring tip having a head portion within said sheath and abutting said flange and a shank portion extending to the exterior of said sheath, and a copper core packed into said sheath and contacting said firing tip, said copper core and said sheath being diffusion alloyed substantially throughout the interface therebetween and the top of said electrode being bifurcated to expose a greater surface area of said copper core.
4. A spark plug comprising a metal shell having a ground electrode secured to the base thereof, an insulator surrounded and supported by said shell, a centerbore in said insulator having a lower end of "reduced diameter to dene a shoulder therein, a composite electrode having a head portion abutting said shoulder to retain said electrode in said centerbore, said electrode comprising a tubular sheath consisting of about 96% nickel, 2% chromium, and 2% manganese, said sheath having an inwardly extending annular ange formed as an integral part therewith at one end thereof, a copper core packed into said sheath and a platinum firing tip having a head portion within said sheath and abutting said flange and a shank portion extending outside said sheath and in spaced relationship to said ground electrode to form a spark gap therebetween, said copper core and said sheath being diffusion alloyed substantially throughout the interface therebetween.
5. The method of making a spark plug electrode eom prising the steps of: forming a tubular sheath from an alloy containing about 96% nickel, 2% chromium, and 2% manganese, to provide an inwardly extending annular ange at one end thereof, positioning in said sheath a platinum firing tip having a headed portion and a shank portion so that said headed portion engages said flange and said shank portion extends to the exterior of said sheath, inserting a copper core in said sheath, swaging said electrode to reduce the wall thickness of said sheath and pack said copper into said sheath, heat treating said electrode in a reducing atmosphere at from 1850 to 1900 F. to alloy the surface of said core to the surface of said sheath and forming a head on said electrode.
6. The method of making a spark plug electrode comprising the steps of: forming a tubular sheath from a high heat and wear resistant metal to provide an inwardly extending annular ange at one end thereof, positioning in said sheath a platinum firing tip having a headed portion and a shank portion so that .said headed portion engages said flange and said shank portion extends to the exterior of said sheath, inserting a copper core in said sheath, swaging said electrode to reduce the wall thickness of said sheath and pack said copper into said sheath, heat treating said electrode in a reducing atmosphere at from 1850 to 1900 F. to alloy the surface of said core to the surface of said sheath, and forming a. head on said electrode.
References Cited in the file of this patent UNITED STATES PATENTS 1,315,298 Genn Sept. 9. 1919 1,422,439 Halvorson July 1l, 1922 2,001,888 Randolph May Z1, 1935 2,296,033 Heller Sept. 15, 1942 2,318,922 Carington May 11, 1943
US279611A 1952-03-31 1952-03-31 Spark plug electrode and process for making same Expired - Lifetime US2783409A (en)

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Cited By (12)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3119944A (en) * 1961-07-25 1964-01-28 Champion Spark Plug Co Spark plug electrode
US3278785A (en) * 1960-12-12 1966-10-11 Gen Motors Corp Spark plug having porcelain insulator protected by plasma-jet deposited refractory coating
US3356882A (en) * 1965-10-21 1967-12-05 Ford Motor Co Spark plug having the center electrode sheath with a nickel alloy
US3868530A (en) * 1973-07-05 1975-02-25 Champion Spark Plug Co Spark plug
US4093887A (en) * 1975-11-07 1978-06-06 Robert Bosch Gmbh Spark plug, particularly for internal combustion engines having composite center electrode
US4368166A (en) * 1979-10-17 1983-01-11 Champion Spark Plug Company Method for the production of a ceramic insulator
DE3335855A1 (en) * 1983-10-03 1985-04-11 G. Rau GmbH & Co, 7530 Pforzheim SPARK PLUG ELECTRODE
EP0401598A1 (en) * 1989-06-05 1990-12-12 G. Rau GmbH. & Co. Centre electrode for sparking plugs of internal combustion engines
US5273474A (en) * 1991-12-03 1993-12-28 Ngk Spark Plug Co., Ltd. Method of manufacturing a center electrode for a spark plug
US5310373A (en) * 1989-12-16 1994-05-10 Robert Bosch Gmbh Method for producing electrodes for spark plugs and spark plug electrodes
US5743777A (en) * 1993-08-02 1998-04-28 Cooper Industries, Inc. Method of manufacturing nickel core copper center electrodes
US20060286497A1 (en) * 2005-06-17 2006-12-21 Tursky John M Pilot tube assembly and method for gas appliance ranges

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1315298A (en) * 1919-09-09 John e
US1422439A (en) * 1922-07-11 Vorson
US2001888A (en) * 1932-05-06 1935-05-21 Gen Motors Corp Spark plug electrode
US2296033A (en) * 1941-01-18 1942-09-15 Gen Motors Corp Spark plug
US2318922A (en) * 1943-05-11 Sparking plug

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1315298A (en) * 1919-09-09 John e
US1422439A (en) * 1922-07-11 Vorson
US2318922A (en) * 1943-05-11 Sparking plug
US2001888A (en) * 1932-05-06 1935-05-21 Gen Motors Corp Spark plug electrode
US2296033A (en) * 1941-01-18 1942-09-15 Gen Motors Corp Spark plug

Cited By (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3278785A (en) * 1960-12-12 1966-10-11 Gen Motors Corp Spark plug having porcelain insulator protected by plasma-jet deposited refractory coating
US3119944A (en) * 1961-07-25 1964-01-28 Champion Spark Plug Co Spark plug electrode
US3356882A (en) * 1965-10-21 1967-12-05 Ford Motor Co Spark plug having the center electrode sheath with a nickel alloy
US3868530A (en) * 1973-07-05 1975-02-25 Champion Spark Plug Co Spark plug
US4093887A (en) * 1975-11-07 1978-06-06 Robert Bosch Gmbh Spark plug, particularly for internal combustion engines having composite center electrode
US4368166A (en) * 1979-10-17 1983-01-11 Champion Spark Plug Company Method for the production of a ceramic insulator
DE3335855A1 (en) * 1983-10-03 1985-04-11 G. Rau GmbH & Co, 7530 Pforzheim SPARK PLUG ELECTRODE
EP0401598A1 (en) * 1989-06-05 1990-12-12 G. Rau GmbH. & Co. Centre electrode for sparking plugs of internal combustion engines
US5310373A (en) * 1989-12-16 1994-05-10 Robert Bosch Gmbh Method for producing electrodes for spark plugs and spark plug electrodes
US5273474A (en) * 1991-12-03 1993-12-28 Ngk Spark Plug Co., Ltd. Method of manufacturing a center electrode for a spark plug
US5743777A (en) * 1993-08-02 1998-04-28 Cooper Industries, Inc. Method of manufacturing nickel core copper center electrodes
US20060286497A1 (en) * 2005-06-17 2006-12-21 Tursky John M Pilot tube assembly and method for gas appliance ranges
WO2006138704A3 (en) * 2005-06-17 2008-01-03 G & J Steel & Tubing Inc Pilot tube assembly and method for gas appliance ranges

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