Classifications

• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01T—SPARK GAPS; OVERVOLTAGE ARRESTERS USING SPARK GAPS; SPARKING PLUGS; CORONA DEVICES; GENERATING IONS TO BE INTRODUCED INTO NON-ENCLOSED GASES
  • H01T13/00—Sparking plugs
  • H01T13/50—Sparking plugs having means for ionisation of gap
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01T—SPARK GAPS; OVERVOLTAGE ARRESTERS USING SPARK GAPS; SPARKING PLUGS; CORONA DEVICES; GENERATING IONS TO BE INTRODUCED INTO NON-ENCLOSED GASES
  • H01T1/00—Details of spark gaps
  • H01T1/20—Means for starting arc or facilitating ignition of spark gap
  • H01T1/22—Means for starting arc or facilitating ignition of spark gap by the shape or the composition of the electrodes
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01T—SPARK GAPS; OVERVOLTAGE ARRESTERS USING SPARK GAPS; SPARKING PLUGS; CORONA DEVICES; GENERATING IONS TO BE INTRODUCED INTO NON-ENCLOSED GASES
  • H01T13/00—Sparking plugs
  • H01T13/20—Sparking plugs characterised by features of the electrodes or insulation
  • H01T13/36—Sparking plugs characterised by features of the electrodes or insulation characterised by the joint between insulation and body, e.g. using cement
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01T—SPARK GAPS; OVERVOLTAGE ARRESTERS USING SPARK GAPS; SPARKING PLUGS; CORONA DEVICES; GENERATING IONS TO BE INTRODUCED INTO NON-ENCLOSED GASES
  • H01T13/00—Sparking plugs
  • H01T13/20—Sparking plugs characterised by features of the electrodes or insulation
  • H01T13/39—Selection of materials for electrodes
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01T—SPARK GAPS; OVERVOLTAGE ARRESTERS USING SPARK GAPS; SPARKING PLUGS; CORONA DEVICES; GENERATING IONS TO BE INTRODUCED INTO NON-ENCLOSED GASES
  • H01T13/00—Sparking plugs
  • H01T13/40—Sparking plugs structurally combined with other devices
  • H01T13/44—Sparking plugs structurally combined with other devices with transformers, e.g. for high-frequency ignition
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01T—SPARK GAPS; OVERVOLTAGE ARRESTERS USING SPARK GAPS; SPARKING PLUGS; CORONA DEVICES; GENERATING IONS TO BE INTRODUCED INTO NON-ENCLOSED GASES
  • H01T21/00—Apparatus or processes specially adapted for the manufacture or maintenance of spark gaps or sparking plugs
  • H01T21/02—Apparatus or processes specially adapted for the manufacture or maintenance of spark gaps or sparking plugs of sparking plugs

Definitions

• This invention relates generally to a corona igniter for emitting a radio frequency electric field to ionize a fuel-air mixture and provide a corona discharge, and a method of forming the igniter.
• Corona discharge ignition systems include an igniter with a central electrode charged to a high radio frequency voltage potential, creating a strong radio frequency electric field in a combustion chamber.
• the electric field causes a portion of a mixture of fuel and air in the combustion chamber to ionize and begin dielectric breakdown, facilitating combustion of the fuel-air mixture.
• the electric field is preferably controlled so that the fuel-air mixture maintains dielectric properties and corona discharge occurs, also referred to as a non-thermal plasma.
• the ionized portion of the fuel-air mixture forms a flame front which then becomes self-sustaining and combusts the remaining portion of the fuel-air mixture.
• the electric field is controlled so that the fuel-air mixture does not lose all dielectric properties, which would create a thermal plasma and an electric arc between the electrode and grounded cylinder walls, piston, or other portion of the igniter.
• An example of a corona discharge ignition system is disclosed in U.S. Patent No. 6,883,507 to Freen.
• the corona igniter typically includes the central electrode formed of an electrically conductive material for receiving the high radio frequency voltage and emitting the radio frequency electric field to ionize the fuel-air mixture and provide the corona discharge.
• the electrode typically includes a high voltage corona-enhancing electrode tip emitting the electrical field.
• the igniter also includes a shell formed of a metal material receiving the central electrode and an insulator formed of an electrically insulating material is disposed between the shell and the central electrode.
• the igniter of the corona discharge ignition system does not include any grounded electrode element intentionally placed in close proximity to a firing end of the central electrode. Rather, the ground is preferably provided by cylinder walls or a piston of the ignition system.
• An example of a corona igniter is disclosed in U.S. Patent Application Publication No. 2010/0083942 to Lykowski and Hampton.
• One aspect of the invention provides a corona igniter comprising a central electrode, an insulator surrounding the central electrode, and a conductive component surrounding the insulator.
• the central electrode is formed of an electrically conductive material for receiving a high radio frequency voltage and emitting a radio frequency electric field.
• the insulator is formed of an electrically insulating material and extends longitudinally along a center axis from an insulator upper end to an insulator nose end.
• the insulator includes an insulator outer surface extending from the insulator upper end to the insulator nose end, and the insulator outer surface presents an insulator outer diameter extending across and perpendicular to the center axis.
• the insulator also includes an insulator body region and an insulator nose region.
• the insulator outer surface includes a lower ledge extending outwardly away from the center axis between the insulator body region and the insulator nose region.
• the lower ledge presents an increase in the insulator outer diameter.
• the conductive component is formed of electrically conductive material and surrounds at least a portion of the insulator body region such that the insulator nose region extends outwardly of the conductive component.
• the conductive component includes a shell surrounding at least a portion of the insulator body region and extending from a shell upper end to a shell firing end.
• the shell presents a shell inner surface facing the center axis and extending along the insulator outer surface from the shell upper end to the shell firing end.
• the shell inner surface also presents a shell inner diameter extending across and perpendicular to the center axis.
• the conductive component also includes an intermediate part surrounding a portion of the insulator body region and extending longitudinally from an intermediate upper end to an intermediate firing end.
• the intermediate part can be layer of metal which brazes the insulator to the shell.
• the intermediate part includes an intermediate inner surface facing the center axis and extending longitudinally along the insulator outer surface from the intermediate upper end to the intermediate firing end.
• the intermediate inner surface presents a conductive inner diameter extending across and perpendicular to the center axis, and the conductive inner diameter is less than the insulator outer diameter along a portion of the insulator located between the lower ledge and the insulator nose end.
• the intermediate part is disposed between the insulator upper end and the lower ledge.
• Another aspect of the invention provides a method of forming the corona igniter.
• the method comprises disposing the intermediate part between the insulator upper end and the lower ledge; and disposing a shell formed of an electrically conductive material around the intermediate part and the insulator.
• the corona igniter of the present invention provides exceptional electrical performance because the conductive inner diameter is less than the insulator outer diameter adjacent the insulator nose region.
• the corona igniter can also be reverse- assembled.
• Figure 1 is a cross-sectional view of a corona igniter manufactured using a forward-assembly method according to one exemplary embodiment of the invention
• Figure 1A is an enlarged view of a portion of the corona igniter of
• Figure 1 showing an intermediate part, an insulator nose region, and a portion of an insulator body region
• Figures 2-9 are cross-sectional views of corona igniters according to other exemplary embodiment of the invention.
• FIG. 1 Exemplary embodiments of a corona igniter 20 are shown in Figures 1-
• the corona igniter 20 includes a central electrode 22 for receiving a high radio frequency voltage.
• the central electrode 22 includes a corona-enhancing tip 24 for emitting a radio frequency electric field to ionize a fuel-air mixture and provide a corona discharge.
• An insulator 26 surrounds the central electrode 22.
• the insulator 26 includes an insulator body region 28 and an insulator nose region 30 presenting an insulator outer diameter Dj pharmaceutical.
• the corona igniter 20 also comprises a conductive component including a metal shell 34 and an intermediate part 36 presenting a conductive inner diameter D c .
• the insulator outer diameter Dj consumer along a portion of the insulator nose region 30 is greater than the conductive inner diameter D c .
• the insulator outer diameter Dj consumer increases in a direction moving away from the metal shell 34 and towards the high voltage corona enhancing tip 24, which provides the corona igniter 20 with an electrical benefit during operation.
• the central electrode 22 of the corona igniter 22 is formed of an electrically conductive material for receiving the high radio frequency voltage, typically in the range of 20 to 75 KV peak/peak.
• the central electrode 22 also emits a high radio frequency electric field, typically in the range of 0.9 to 1.1 MHz.
• the central electrode 22 extends longitudinally along a center axis A from a terminal end 38 to an electrode firing end 40.
• the central electrode 22 typically includes a corona enhancing tip 24 at the electrode firing end 40, for example a tip including a plurality of prongs, as shown in Figures 1-8.
• the insulator 26 of the corona igniter 20 is formed of an electrically insulating material.
• the insulator 26 surrounds the central electrode 22 and extends longitudinally along the center axis A from an insulator upper end 42 to an insulator nose end 44.
• the electrode firing end 40 is typically disposed outwardly of the insulator nose end 44, as shown in Figures 1-8.
• An insulator inner surface 46 surrounds an insulator bore receiving the central electrode 22.
• a conductive seal 47 is typically used to secure the central electrode 22 and an electrical contact 49 in the insulator bore.
• the insulator inner surface 46 also presents an insulator inner diameter
• the insulator 26 includes an insulator outer surface 50 extending from the insulator upper end 42 to the insulator nose end 44.
• the insulator outer surface 50 also presents the insulator outer diameter Dj celebrity extending across and perpendicular to the center axis A.
• the insulator inner diameter On is preferably 15 to 25% of the insulator outer diameter D io .
• the insulator 26 includes the insulator body region 28 and the insulator nose region 30.
• the insulator outer surface 50 includes a lower ledge 52 extending outwardly away from and transverse to the center axis A between the insulator body region 28 and the insulator nose region 30.
• the lower ledge 52 presents an increase in the insulator outer diameter Dj trademark.
• the insulator body region 28 and insulator nose region 30 can have various different designs and dimensions with the lower ledge 52 disposed therebetween, other than the designs and dimensions shown in the Figures.
• the conductive component of the corona igniter 20 surrounds at least a portion of the insulator body region 28 such that the insulator nose region 30 extends outwardly of the conductive component, as shown in the Figures.
• the conductive component includes the shell 34 and the intermediate part 36, both formed of electrically conductive metal.
• the shell 34 and the intermediate part 36 can be formed of the same or different electrically conductive materials.
• the shell 34 is typically formed of a metal material, such as steel, and surrounds at least a portion of the insulator body region 28.
• the shell 34 extends along the center axis A from a shell upper end 54 to a shell firing end 56.
• the shell 34 presents a shell inner surface 58 facing the center axis A and extending along the insulator outer surface 50 from the shell upper end 54 to the shell firing end 56.
• the shell 34 also includes a shell outer surface 60 facing opposite the shell inner surface 58 and presenting a shell outer diameter D so .
• the shell inner surface 58 presents a shell bore surrounding the center axis A and a shell inner diameter D si extending across and perpendicular to the center axis A.
• the shell inner diameter D S j is typically greater than or equal to the insulator outer diameter Dj administrat along the entire length 1 of the insulator 26 from the insulator upper end 42 to the insulator nose end 44, so that the corona igniter 20 can be forward-assembled.
• the length of the insulator 26 includes both the body region 28 and the nose region 30.
• the term "forward-assembled" means that the insulator nose end 44 can be inserted into the shell bore through the shell upper end 54, rather than through the shell firing end 56.
• the shell inner diameter D S j is less than or equal to the insulator outer diameter Di o along a portion of the length 1 of the insulator 26 from the insulator upper end 42 to the insulator nose end 44, and that the corona igniter 20 is reversed assembled.
• the term "reverse-assembled" means that the insulator upper end 42 is inserted into the shell bore through the shell firing end 56.
• the intermediate part 36 of the corona igniter 20 is disposed inwardly of the shell 34 and surrounds a portion of the insulator body region 28.
• the intermediate part 36 is disposed along the insulator body region 28 directly above the insulator nose region 30. It extends longitudinally from an intermediate upper end 64 to an intermediate firing end 66.
• the intermediate part 36 is rigidly attached to the insulator outer surface 50.
• the intermediate inner surface 68 is hermetically sealed to the insulator outer surface 50, to close the axial joint and avoid gas leakage during use of the corona igniter 20 in a combustion engine.
• the intermediate part 36 is typically formed of a metal or metal alloy containing one or more of nickel, cobalt, iron, copper, tin, zinc, silver, and gold.
• the metal or metal alloy can be cast into place on the insulator outer surface 50.
• the intermediate part 36 can be glass or ceramic based and made conductive by the addition of one or more of the above metals or metal alloys.
• the glass or ceramic based intermediate part 36 can be formed and sintered directly into place on the insulator outer surface 50.
• the intermediate part 36 can also be provided as a metal ring attached in place to the insulator outer surface 50 by soldering, brazing, diffusion bonding, high temperature adhesive, or another method.
• the intermediate part 36 is also attached to the shell inner surface 58, preferably by any suitable method, including soldering, brazing, welding, interference fit, and thermal shrink fit.
• the material used to form the intermediate part 36 is preferably conformable and is able to absorb stresses occurring during operation, without passing them to the insulator 26.
• the intermediate part 36 brazes the insulator
• the intermediate part 36 is a thin layer of metal containing one or more of nickel, cobalt, iron, copper, tin, zinc, silver, and gold.
• the metal is provided in liquid form and flows between the insulator 26 and the shell 34, and then allowed to solidify to braze the insulator 26 to the shell 34.
• the layer of metal can be applied before or after disposing the insulator 26 in the shell 34.
• the intermediate part 28 can be used to braze the insulator 26 to the shell 34 in either the forward or reverse assembly igniters 22.
• the intermediate part 28 is formed from a solid piece of metal, specifically a solid ring formed of a silver (Ag) and/or copper (Cu) alloy disposed around the insulator 26.
• the shell 34 is disposed around the insulator 26, and the assembly is heated at which time the solid ring, referred to as a braze, becomes liquid and is wicked into an area, referred to as a "braze area,” through capillary action.
• the liquid alloy solidifies to provide the intermediate part 36 brazed to the insulator 26 and to the shell 34. This process puts the ceramic insulator 26 in compression because of the differences in shrinkage of the components after the alloy solidifies and as the parts cool.
• the engine temperature does not reach the melting point of the braze alloy used to form intermediate part 36, so that it stays solid during engine operation.
• the intermediate part 36 could be formed by brazing the solid ring to the insulator 26 and shell 34 by another metal material, such as another metal having a lower melting point than the solid ring, using the brazing process described above.
• the intermediate inner surface 68 of the intermediate part 36 faces the center axis A and extends longitudinally along the insulator outer surface 50 from the intermediate upper end 64 to the intermediate firing end 66.
• the intermediate part 36 also includes an intermediate outer surface 70 facing opposite the intermediate inner surface 68 and extending longitudinally from the intermediate upper end 64 to the intermediate firing end 66.
• the intermediate outer diameter Dj trademark t is typically less than or equal to the shell outer diameter D so , as shown in Figures 1-7, but may be greater than the shell inner diameter D S j, as shown in Figure 8.
• the intermediate inner surface 68 presents a conductive inner diameter D c extending across and perpendicular to the center axis A.
• the conductive inner diameter D c is less than the insulator outer diameter Dj administrat at the lower ledge 52 of the insulator 26, which is between the insulator nose region 30 and the insulator body region 28.
• the insulator 26 also presents a thickness tj that increases adjacent the shell firing end 56 and adjacent the intermediate firing end 66.
• the insulator thickness tj increases in the direction toward the electrode firing end 40.
• the conductive inner diameter D c is typically equal to 75 to 90% of the shell inner diameter D S j along the intermediate part 36.
• the intermediate firing end 66 preferably engages the lower ledge 52 of the insulator 26 and is longitudinally aligned with the shell firing end 56.
• the insulator outer diameter Dj lender typically tapers from the lower ledge 52 along the insulator nose region 30 to the insulator nose end 44.
• the exemplary embodiments of the corona igniter 20 can include various different features.
• the insulator outer surface 50 of the insulator body region 28 presents an upper ledge 72 extending inwardly toward the center axis A such that the upper ledge 72 and the lower ledge 52 present a recess 74 therebetween.
• the intermediate part 36 is disposed in the recess 74 and typically extends along the entire length of the recess 74.
• the intermediate upper end 64 engages the upper ledge 72 and the intermediate firing end 66 engages the lower ledge 52 to restrict movement of the intermediate part 36 during assembly and in operation.
• the length of the recess 74 and intermediate part 36 can vary.
• the length of the recess 74 and intermediate part 36 can extend along one quarter or less of the length 1 of the insulator 26, as shown in Figures 1 , 3, and 6-8.
• the length of the recess 74 and intermediate part 36 can extend along greater than one quarter of the length 1 of the insulator 26, as shown in Figures 2 and 4. Extending the length intermediate part 36, as shown in Figures 2 and 4, improves thermal performance and removes any small air gaps within the assembly, which improves electrical performance.
• the shell inner surface 58 of the corona igniter 20 extends away from the insulator outer surface 50 adjacent the shell upper end 54 to present a crevice 76 between the shell inner surface 58 and the insulator outer surface 50.
• a filler material 88 at least partially fills the crevice 76 between the insulator outer surface 50 and the shell inner surface 58 adjacent the shell upper end 54.
• the filler material 88 is typically an adhesive attaching the insulator 26 to the shell 34 and prevents the insulator 26 from entering the combustion chamber, in the case of failure of the j oints at the intermediate part 36.
• the filler material 88 can also provide improved electrical and thermal performance, as well as increased stability.
• the filler material 88 may be electrically insulating, such as a ceramic-loaded adhesive, silicone, or epoxy-based filler, PTFE, a printable carrier, a paintable carrier, or tampered powder.
• the filler material 88 can alternatively be electrically conductive, such a metal-loaded epoxy, a printable carrier or paintable carrier including conductive materials, a solder, or a braze. If the filler material 88 provides adequate adhesion, mechanical strength, and thermal performance, it is possible to omit the step of rigidly attaching the intermediate part 36 to the insulator 26.
• the intermediate part 36 is attached to the shell 34, as before, and makes the insulator 26 captive.
• the filler material 88 can provide the gas-tight seal, instead of the j oints along the intermediate part 36.
• the intermediate inner surface 68 should still fit closely against the insulator outer surface 50, or against the ledges 52, 72 and recess 74, to restrict possible movement of the components during operation.
• the insulator outer diameter D io is constant from the upper ledge 72 along a portion of the insulator body region 28 toward the insulator upper end 42 and then increases gradually along a portion of the insulator body region 28 toward the insulator upper end 42.
• the insulator outer diameter Dj consultation is constant from the gradual increase to the insulator upper end 42. The gradual increase helps to achieve accurate assembly, supports the upper body region, improves thermal performance, and prevents the insulator 26 from entering into the combustion chamber in the case of failure of the joints along the intermediate part 36.
• a conformal element 78 can be placed between the insulator 26 and the shell 34 along the gradual increase.
• the conformal element 78 is typically formed of a soft metal gasket formed of copper or annealed steel, or a plastic or rubber material.
• the crevice 76 extends from the gradual transition toward the insulator upper end 42. [0030] In the exemplary embodiment of Figure 2, the insulator outer diameter
• Di o increases gradually from the upper ledge 72 toward the insulator upper end 42 and is constant from the gradual increase to the insulator upper end 42.
• the crevice 76 also extends from the gradual increase toward the insulator upper end 42.
• Di o is constant from the upper ledge 72 to the insulator upper end 42. This makes it easier to avoid putting the insulator 26 in tension during operation.
• the corona igniter 20 could be forward-assembled or reverse-assembled. However, it may be desirable to increase the insulator outer diameter Dj 0 along or above the crevice 76 to interface properly with other system components (not shown). Alternatively, a separate component (not shown) could be added to increase the insulator outer diameter Dj 0 along or above the crevice 76
• Figure 4 illustrates yet another exemplary embodiment, wherein the crevice 76 extends from the intermediate upper end 64 to the shell upper end 54.
• the insulator outer diameter D io is constant from the lower ledge 52 to the insulator upper end 42.
• the insulator outer diameter Dj 0 decreases slightly above the intermediate upper end 64, along the insulator body region 28 between the lower ledge 52 and the insulator upper end 42.
• FIGS 6 and 7 illustrate other exemplary embodiments wherein the insulator outer diameter Dj 0 is constant from the upper ledge 72 to a turnover region.
• the insulator 26 diameter increases at the turnover region and then decreases to present a turnover shoulder 82 for supporting and engaging the shell upper end 54.
• the insulator outer diameter Dj 0 is then constant from the turnover shoulder 82 to the insulator upper end 42.
• the shell upper end 54 turns over and engages the insulator outer surface 50 at the turnover shoulder 82 ad holds the insulator 26 captive in the shell 34.
• the intermediate inner surface 68 presents a conductive inner diameter D c extending across and perpendicular to the center axis A, and the conductive inner diameter D c is less than the insulator outer diameter Dj consumer directly below the lower ledge 52 of the insulator 26.
• the intermediate firing end 66 engages the lower ledge 52 of the insulator 26, as in the other embodiments.
• the intermediate outer surface 70 includes an intermediate seat 84 between the intermediate upper end 64 and the intermediate firing end 66, and the intermediate outer diameter Dj personally t decreases along the intermediate seat 84 toward the intermediate firing end 66.
• the shell inner surface 58 presents a shell seat 86 extending toward the intermediate outer surface 70.
• the shell seat 86 is aligned, parallel to, and engages the intermediate seat 84.
• the shell 34 has a thickness t s extending from the shell inner surface 58 to the shell outer surface 60 and the thickness t s increases at the shell seat 86.
• the shell 34 again includes the shell seat 86 facing the insulator 26 upper ledge 72.
• the shell inner diameter D S j decreases along the shell seat 86 toward the shell firing end 56.
• a gasket 80 is disposed between and separates the shell seat 86 and the insulator 26 upper ledge 72.
• the gasket 80 is compressed between the insulator outer surface 50 and the shell seat 86 to provide a seal.
• the intermediate part 36 does not need to seal against gas pressure or retain the insulator 26, and it may be press fit to the shell 34 during assembly.
• the insulator outer diameter D io at the upper ledge 72 is greater than the insulator outer diameter Dj consumer at the lower ledge 52.
• the shell 34 thickness t s increases at the shell seat 86.
• the intermediate outer diameter D int at the intermediate upper end 64 is greater than the insulator outer diameter D io of the upper ledge 72 of the insulator 26.
• the intermediate upper end 64 extends radially outwardly relative to the insulator outer surface 50, and the shell firing end 56 is disposed on the intermediate upper end 64.
• the conductive inner diameter D c from the intermediate upper end 64 to the intermediate firing end 66 is constant and the intermediate outer diameter Dj cale t tapers from the intermediate upper end 64 to the intermediate firing end 66.
• Another aspect of the invention provides a method of forming the corona igniter 20.
• the method can be a forward-assembly method, which includes inserting the insulator nose end 44 into the shell bore through the shell upper end 54, rather than the shell firing end 56 as in the reverse-assembly method.
• the method could alternatively comprise a reverse assembly method, wherein the shell inner diameter D si is less than or equal to the insulator outer diameter Djrug along a portion of the insulator 26, and the method includes inserting the insulator nose end 44 into the shell bore through the shell firing end 56.
• the method of forming the corona igniter 20 includes control of forces and material temperatures such that the insulator 26 is not placed in tension, either during assembly, or due to differential thermal expansion during operation.
• the method includes providing the insulator 26 formed of the electrically insulating material extending along the center axis A from the insulator upper end 42 to the insulator nose end 44.
• the insulator 26 includes the insulator outer surface 50 extending from the insulator upper end 42 to the insulator nose end 44.
• the insulator outer surface 50 presents the insulator outer diameter Djune and includes the lower ledge 52 extending outwardly away from and transverse to the center axis A between the insulator body region 28 and the insulator nose region 30.
• the method also includes disposing the intermediate part 36 formed of the electrically conductive material on the lower ledge 52 of the insulator 26. This step is typically conducted before the insulator 26 is inserted into the shell 34. However, if the intermediate outer diameter Dj coat t is greater than the shell inner diameter D S j, as in the corona igniter 20 of Figure 8, then the intermediate part 36 is disposed on the lower ledge 52 after inserting the insulator 26 into the shell 34.
• the method also includes rigidly attaching the intermediate part 36 to the insulator outer surface 50, typically before inserting the insulator 26 into the shell 34.
• the attaching step typically includes casting, sintering, brazing, soldering, diffusion bonding, or applying a high temperature adhesive between the intermediate part 36 and insulator outer surface 50. If the intermediate part 36 is a metal or metal alloy, the attaching step typically includes casting. If the intermediate part 36 is glass or ceramic based, the attaching step typically includes forming and sintering directly into place around the insulator outer surface 50. If the intermediate part 36 is a metal ring, then the attaching step typically includes soldering, diffusion bonding, or applying a high temperature adhesive between the intermediate part 36 and insulator outer surface 50.
• the method typically includes hermetically sealing the intermediate part 36 to the insulator 26 to close the axial joint and avoid gas leakage during use of the corona igniter 20.
• the method also includes providing the shell 34 formed of the electrically conductive material extending along and around the center axis A from the shell upper end 54 to the shell firing end 56.
• the shell 34 includes the shell inner surface 58 extending from the shell upper end 54 to the shell firing end 56, and the shell inner surface 58 presents the shell bore extending along the center axis A.
• the shell inner diameter D S j is greater than or equal to the insulator outer diameter Dj flirt.
• the method next includes inserting the insulator 26 into the shell 34 in the forward-assembly direction.
• This step is typically conducted after attaching the intermediate part 36 to the insulator 26, but may be done before.
• This step includes inserting the insulator nose end 44 through the shell upper end 54 into the shell bore.
• the insulator 26 should be moved along the shell inner surface 58 until the insulator nose end 44 extends outwardly of the shell firing end 56.
• this step includes aligning the shell firing end 56 with the lower ledge 52 of the insulator 26 and the intermediate firing end 66.
• the method includes inserting the insulator 26 into the shell 34 followed by disposing the intermediate part 36 along the insulator outer surface 50 such that the intermediate upper end 64 engages the shell firing end 56.
• the method may also include disposing the filler material 88 in the crevices 76 between the insulator 26 and shell upper end 54. This step may include filling at least a portion of the crevice 76 with the filler material 88.
• the filler material 88 can be applied to both the insulator outer surface 50 and shell inner surface 58 before inserting the insulator 26 into the shell 34, such that when the insulator 26 and shell 34 are connected, the filler material 88 at least partially fills the crevice 76. If the filler material 88 provides a gas-tight seal, then it is possible to omit the step of rigidly attaching the intermediate part 36 to the insulator 26.

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• Engineering & Computer Science (AREA)
• Manufacturing & Machinery (AREA)
• Power Engineering (AREA)
• Chemical & Material Sciences (AREA)
• Combustion & Propulsion (AREA)
• Spark Plugs (AREA)
• Ignition Installations For Internal Combustion Engines (AREA)

Applications Claiming Priority (2)

Publications (1)

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• 2017
  • 2017-08-11 EP EP17754985.4A patent/EP3501073A1/de active Pending
  • 2017-08-11 KR KR1020197007035A patent/KR20190034669A/ko active IP Right Grant
  • 2017-08-11 JP JP2019509466A patent/JP7086052B2/ja active Active
  • 2017-08-11 WO PCT/US2017/046420 patent/WO2018034952A1/en unknown
  • 2017-08-11 CN CN202111183481.0A patent/CN114024213B/zh active Active
  • 2017-08-11 CN CN201780064454.7A patent/CN109952687B/zh active Active

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