Spark plugs are employed in combustion chambers of combustion systems, such as within the cylinders of internal combustion engines of vehicles, for example, to ignite a pressurized air-fuel mixture therein. To increase the operational lifetime of spark plugs, hard metals, such as platinum and iridium, for example, have been increasingly used in place of nickel-copper alloys for spark plug electrodes. However, spark plugs employing such metals are costly and, in some cases, may reduce engine performance relative to so-called nickel spark plugs.
The accompanying drawings are included to provide a further understanding of embodiments and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments and together with the description serve to explain principles of embodiments. Other embodiments and many of the intended advantages of embodiments will be readily appreciated as they become better understood by reference to the following detailed description. The elements of the drawings are not necessarily to scale relative to each other. Like reference numerals designate corresponding similar parts.
In the following detailed description, reference is made to the accompanying drawings which form a part hereof, and in which is shown by way of illustration specific examples in which the disclosure may be practiced. It is to be understood that other examples may be utilized and structural or logical changes may be made without departing from the scope of the present disclosure. The following detailed description, therefore, is not to be taken in a limiting sense, and the scope of the present disclosure is defined by the appended claims. It is to be understood that features of the various examples described herein may be combined, in part or whole, with each other, unless specifically noted otherwise.
Spark plugs are employed in combustion chambers of combustion systems, to ignite a pressurized air-fuel mixture therein, such as within the cylinders of internal combustion engines of vehicles, for example. Spark plugs typically include a central electrode disposed within a generally cylindrical or tubular insulative core (e.g., ceramic), and a metal casing or shell concentrically disposed about a perimeter of at least a portion of the insulative core, wherein the metal shell includes a side electrode that forms a spark gap with the center electrode at a firing end of the spark plug. When the spark plug is installed in a combustion system (e.g., screwed into a cylinder head), a portion of the firing end is disposed within the combustion chamber such that a controlled voltage applied across center and side electrodes causes controlled sparking across the spark gap to ignite the air-fuel mixture therein.
Electrical fields along a surface of a charged conductor are strongest at locations having the greatest surface charge density, such as along a sharp edge or at a point, for example. With this in mind, a firing end of the center electrode is typically formed with sharp perimeter edges and a small diameter (so as to be point-like), wherein, generally, the smaller the diameter the lower the voltage required to cause a spark across the spark gap between the sharp perimeter edges of the center electrode and sharp edges of the side electrode.
While there are a number of spark plug types available, the most common are nickel spark plugs, platinum spark plugs, and iridium spark plugs. Nickel spark plugs employ a center electrode having a copper core about which a nickel alloy is fused, particularly at the electrode head (e.g., 2.5 mm in diameter). While highly electrically and thermally conductive, a nickel alloy is a relatively soft material. Consequently, the electrode head tends to wear down relatively quickly from repeated high-voltage sparking at a same point under the high pressure, high temperature, and corrosive conditions within a combustion chamber. As the electrode head erodes, its sharp edges are lost and the spark gap widens, thereby requiring a higher voltage to elicit a spark (i.e., a higher breakdown voltage). Electrode head erosion often leads to spark plug fouling and reduced engine performance (e.g., engine misfiring). As a result, known nickel spark plugs need to be replaced relatively frequently (e.g., every 20,000 miles).
Platinum and iridium spark plugs also employ a copper core center electrode wire having a nickel-alloy tip. However, in the case of platinum spark plugs, a small platinum disk (e.g., 1.1 mm in diameter) is welded to the nickel-alloy tip of the center electrode wire. Similarly, in the case of iridium spark plugs, an iridium “wire” (e.g., 0.4 mm in diameter) is welded to the nickel-alloy tip of the center electrode wire. Platinum and iridium are part of the “platinum group” of precious metals, which are known for their hardness and their chemically non-reactive nature. Because platinum and iridium are harder materials than nickel-alloys, platinum and iridium spark plugs hold their edges and maintain their gaps longer than nickel spark plugs and, thus, have a longer lifetime (e.g., 50,000 miles for platinum, and 100,000 miles for iridium). Even though platinum and iridium spark plugs are more expensive, they do not provide the same performance level as conventional nickel spark plugs. However, due to their extended lifetimes, the use of platinum and iridium spark plugs continues to increase and has replaced the use of nickel spark plugs in many applications.
According to examples which will be described in greater detail herein, the present disclosure provides a spark plug having a large center electrode head (e.g., 8 mm in diameter) which may be formed from non-precious metals (including nickel-alloys traditionally used for nickel spark plugs), wherein a perimeter edge of the large center electrode head forms a circumferential spark gap with a circumferentially extending side electrode formed by the metal shell of the spark plug. The disclosed spark plug is lower in cost and provides improved performance (e.g., faster combustion, improved torque, increased efficiency, better fuel economy) relative to platinum and iridium spark plugs, while having a lifetime similar to that of iridium spark plugs (e.g., 100,000 miles). Previous attempts have been made at developing spark plugs employing large electrode heads comprising non-precious metals. However, such known attempts have physically failed during operation and/or have failed to achieve lifetimes approaching those of iridium spark plugs primarily due to thermal issues. It is noted that due to high material costs, it is generally cost-prohibitive to manufacture large electrode heads of precious metals, such as iridium and platinum, and, in fact, tend to motivate the use of small electrode heads.
Spark plug 10 further includes a terminal electrode 40 and a center electrode 50 extending axially along axial centerline 14. Terminal electrode 40 includes a terminal wire 42 extending to a terminal stud 44 proximate to terminal end 16. In accordance with the present disclosure, spark plug 10 includes a center electrode 50 including a center electrode wire 52 and a center electrode head 54, where center electrode head 54 is threaded to center electrode wire 52. In one example, center electrode wire 52 includes male threads 56 at a first end 57 and a wire head 58 at an opposing second end 59, where male threads 56 are threaded to corresponding female threads 60 (see
With continued reference to
Insulative core 12 is then inserted into threaded sleeve 34, with gaskets 64 and 66 respectively forming a seal between an interior surface of threaded sleeve 34 and shoulders 65 and 67 on insulative core 12 when nut 32 is fused with threaded sleeve 34 (e.g. via a thermal process). In one example, after nut 32 is fused with threaded sleeve 34, insulative nose 20 of insulative core 12 extends axially beyond side electrode 36, with threads 56 of first end 57 of center electrode wire 52 extending axially beyond insulative nose 20 so as to be exposed therefrom. In one example, center electrode head 54 is then coupled to center electrode wire 52, such as by threading.
By attaching center electrode head 54 to center electrode wire 52 after center electrode wire 52 has been installed within central bore 22 of insulative core 12, center electrode head 54 can be sized larger than the diameter of central bore 22. As will be described in greater detail below, a large center electrode head provides an increased linear edge length (e.g., a continuous circumferential edge) which increases the spark point diversity of the center electrode head when forming a spark gap with a corresponding side electrode extending from the metal shell. In-turn, the increased spark point diversity enables a spark plug, in accordance with the present disclosure, to utilize an enlarged center electrode head formed with nickel-alloys traditionally employed for nickel spark plug electrodes while providing improved engine performance and achieving lifetimes comparable to iridium spark plugs.
When threaded onto electrode wire 52, collar 106 is seated within counter bore 74 at insulative nose 20 of insulative core 12 such that a portion 110 of bottom surface 104 of electrode plate 100 surrounding collar 106 engages and is flush with end surface 75 of insulative nose 20 (see
In one example, as illustrated, a circumferential edge 114 of electrode plate 100 is angled downward at a head angle, θ, from upper surface 102 toward lower surface 104 such that a spark gap distance, dgap, of a spark gap 140 formed between a circumferential edge 116 of lower surface 104 of electrode plate 100 and circumferentially extending side electrode 36 may vary depending on head angle, θ (see
As illustrated, threaded sleeve 34 includes side electrode 36 axially extending from threaded region 122. In one example, as illustrated, side electrode circumferentially extends from threaded region 122 and is ring-like in shape with an inner diameter, di, formed by an inner perimeter edge 36-1 and an outer diameter, do formed by an outer perimeter edge 36-2. As will be described in greater detail below (see
In one example, as illustrated, center electrode head 54 is threaded onto male threads 56 of center electrode wire 52 via female threads 60 disposed in collar 106 such that bottom surface 110 of electrode plate 100 is flush with the end surface 75 of insulative nose 20. In one example, threads 56/60 forming the threaded connection between center electrode wire 52 and electrode head 54 are locking threads which function to immobilize and secure the threaded connection to prevent center electrode head 54 from decoupling from center electrode wire 52 during operation of spark plug 10. Such locking threads include any suitable locking mechanism such as cold welding (e.g., thread galling), self-locking type threads (e.g., interference threads), and thread locking systems (e.g., adhesives), for example.
In one example, an end surface 130 of center electrode wire 52 is substantially flush with end surface 75 of insulative nose 20. In other examples, the length of center electrode wire 52 and depth of female threads 60 of center electrode head 54 may vary so long as bottom surface 110 of electrode plate 100 is flush with end surface 75 of insulative nose 20. In one example, the respective shoulder regions 84 and 108 of insulative nose 20 and of center electrode head 54 serve to position electrode head 54 within counter bore 74 when threaded to center electrode wire 52. In one example, as illustrated, expansion gaps 134 and 136 are respectively disposed between collar 106 of center electrode head 54 and the sidewalls of counter bore 74 of insulative nose 20, and between center electrode wire 52 and the sidewalls of central bore 22 to accommodate expansion of center electrode wire 52 and center electrode head 54 due to differences in the coefficients of thermal expansion between the materials thereof. In some examples, a thermal expansion gap may also be present between shoulder regions 84 and 108.
In one example, as illustrated, when threaded to electrode wire 52, circumferentially extending lower perimeter edge 116 of electrode plate 100 forms a continuous radial spark gap 140 having a gap distance, dgap, with the circumferentially extending edge 36-1 defining the inner diameter, di, of side electrode 36 (e.g., ground electrode). By forming a continuous radial spark gap 140, the entire perimeter edge 116 of electrode plate 110 forms a continuous edge which provides a spark point diversity so that electrode plate 100 does not wear or erode as quickly as known spark plugs having a single point spark gap or a plurality of discrete spark gaps, thereby extending the operational life of spark plug 10, in accordance with the present disclosure. In other examples, which are not explicitly illustrated herein, side electrode 36 may include multiple points, with each point forming a separate gap with electrode plate 100.
In one example, the diameter, dh, of center electrode head 54 is greater than the outer diameter, dn, of insulative nose 20, but less than the inner diameter, di, of side electrode 36 such that spark gap 140 is diagonal and at an acute angle, α, relative to central axis 14 such that spark gap 140 is not “shaded” by electrode plate 100 when spark plug 10 is disposed within a combustion chamber of an internal combustion engine. In examples, the gap distance, dgap, of spark gap 140 may be varied by adjusting various structural features, such as by varying the axial length, ln, of insulative nose 20, by varying the diameter, dh, of center electrode head 54, by varying the inner diameter, di, of side electrode 36, by varying the head angle, θ, of the circumferential edge 114 of disk-shaped electrode plate 100, and/or by varying the thickness, th, of electrode plate 100, or any combination thereof. In one example, gap distance, dgap, may exceed 2.0 mm. In other examples, electrode head 54 may be disposed relative to side electrode 36 such that a horizontal surface gap is formed between electrode plate 100 and side electrode 36 (a so-called “surface gap” spark plug).
Spark plugs are configured to operate within an industry-standard heat range, which is typically defined as being between 600° C. and 850° C. A spark plug operating at temperatures above such heat range may cause pre-ignition of the air-fuel mixture within the cylinder. If operating below such temperature range, the air-fuel mixture may not burn properly so that residue may build-up on the spark plug (“fouling”) and lead to failed or inconsistent spark generation (“misfiring”). As such, for optimal operation, a spark plug should operate with an electrode head temperature hot enough to provide self-cleaning (i.e., to burn off residue), but cool enough to avoid pre-ignition of the air-fuel mixture.
A tremendous amount of heat is generated within a cylinder during engine operation, a portion of which is absorbed by, and must be dissipated by, the spark plug. Since different engines generate and dissipate different amounts of heat and are designed with different optimal operating temperatures or heat ranges, each engine typically specifies a temperature range, or heat range, at which a spark plug must operate in order to provide optimal engine performance. With this in mind, spark plugs are typically designated with a heat rating, where such heat rating is indicative of the ability of the spark plug to dissipate heat and, thus, indicative of a temperature (or range of temperatures) at which the spark plug is configured to operate. A so-called “hot” plug has a configuration which is slower to draw heat away from the electrode head and, thus, has a higher operating temperature within the standard heat range, while a so-called “cold” plug has a has a configuration which draws heat away from the electrode head more quickly and, thus, has a lower operating temperature within the standard heat range. As such, to better ensure optimal performance, engines typically specify a heat rating, or heat ratings, of spark plugs to be used therewith. Employing spark plugs which do not comply with a specified heat range may result in sub-optimal engine performance and even engine failure.
Spark plugs typically dissipate absorbed heat by passing heat from the electrode head through the center electrode wire to the insulative core, and from the insulative core to the engine cooling system via the threaded metal shell (which is threaded into the cylinder head). Generally, the heat range of a spark plug is related to a length of the tapered insulating nose of the ceramic insulating core. The longer the insulating nose, the less the amount of surface area of the ceramic insulating core which will be in direct contact with the metal shell for transfer of heat to the engine cooling system, and the “hotter” the operating temperature of the spark plug. Conversely, the shorter the insulating nose, the greater the amount of surface area of the ceramic insulating core which will be in direct contact with the metal shell for transfer of heat to the engine cooling system, and the “cooler” the operating temperature of the spark plug.
In known spark plugs, including platinum and iridium spark plugs, the center electrode head does not exceed the diameter of the center electrode wire (i.e., does not exceed the diameter of the central bore at its narrowest point). Due to the small exposed surface area of the electrode head (the smaller the exposed surface area, the less the amount of heat absorbed by the electrode head). Because of the relatively large thermal pathway provided from the electrode head to the ceramic insulator by the electrode wire of known spark plugs (where the diameter of the center electrode head does not exceed the diameter of the center electrode wire), overheating of known spark plugs is generally not an issue.
To conform to industry-standard heat range specifications and to achieve an extended life expectancy, spark plug 10, in accordance with the present disclosure, dissipates a large amount of heat from the large electrode plate 100 of center electrode head 54 as compared to known plugs. For example, electrode plate 100 may be 8 mm in diameter as compared to 1.1 mm of the platinum disk of a conventional platinum spark plug. As illustrated and described above, to enable a large amount of heat dissipation from electrode head 54, example spark plug 10 of the present disclosure includes a number of unique structural features to create a large thermally conductive pathway between electrode head 54 and metal shell 30. In examples, the ability of electrode head 54 to quickly dissipate large amounts of heat enables spark plug 10 to employ a large electrode plate 100 of traditional copper and nickel-alloy materials (i.e., non-rare earth or precious metals) while providing a comparable life expectancy and improved engine performance (e.g., faster combustion, improved torque) relative to known platinum and iridium spark plugs.
A first example of a unique structural feature is that an amount of surface area of electrode plate 100 exposed to the combustion chamber via which heat may be absorbed is limited by mounting electrode plate 100 with a portion of bottom surface 110 flush with end surface 75 of insulative nose 20. In addition to reducing the amount of exposed surface area and, thus, the amount of heat transfer to electrode plate 100, direct contact between bottom surface 110 and end surface 75 further provides a thermal pathway for transferring heat from electrode plate 100 to insulative core 12.
Another unique structural feature is the threaded connection between center electrode head 54 and center electrode wire 52 via threaded collar 106. The large circumferential surface area contact between threaded collar 106 and electrode wire 52 provides a large heat transfer pathway from electrode plate 100 to center electrode wire 52 and subsequently to the engine cooling system via metal shell 30. The threaded connection enables the same or similar materials to be employed by center electrode head 54 and center electrode wire 52, thereby providing a contiguous heat transfer pathway of materials having the same or similar thermal characteristics (e.g., thermal conductivity and coefficient of thermal expansion). Using materials having the same or similar thermal characteristics also reduces the potential for physical failure of the connection between center electrode head 54 and center electrode wire 52 that might otherwise result between materials having different thermal expansion characteristics.
A further unique structural feature is the seating of collar 106 within counter bore 74 of insulative nose 20. Seating collar 106 within counter bore 74 provides a large amount of surface contact area between center electrode head 54 and insulative nose 20 which forms a large heat transfer pathway from center electrode head 54 to insulative core 12.
The above-described unique structural features, which together thermally couple electrode head 54 to electrode wire 52 and insulative core 12, provide an amount of heat transfer from center electrode head 54 which enables center electrode head 54 to be formed using traditional copper and nickel-alloy materials. Such traditional materials have thermal conductivities superior to those of harder, more heat resistant materials (e.g., iridium, platinum, and other non-traditional materials) and, thus, further improves the heat dissipation capacity of spark plug 10.
The durability testing simulations for spark plugs 10 and 160 each used the same designated thermal model setup conditions, which included both operating conditions and boundary conditions. The operating conditions were modeled a power output of 210 HP at 5,000 rpm (high power, but not extreme conditions). The boundary conditions were modeled with the electrode and plug face at a 1050° C. gas temperature and htc=750 W/m2K (from 1D model); the threat and seat fixed at 130° C. (assumed to be anchored to the engine head temperature; a plug back side (ambient) at a 60; and contact resistances were estimated from wire-to-insulator, insulator-to-housing, and disk-to-insulator.
It is noted that a maximum operating temperature of spark plug 10 may be adjusted by increasing or decreasing the length, ln, of insulative nose 20 (e.g., see
As mentioned above, in contrast to the example spark plug 10 of the present disclosure, due to thermal issues (failure to dissipate heat), known spark plugs employing large center electrode heads (e.g., larger than the diameter of the central electrode wire) have physically failed during operation and/or have failed to achieve operating lifetimes approaching that of platinum and iridium spark plugs. Such thermal issues are attributable to multiple structural deficiencies.
Additionally, in some examples, the large electrode heads of known spark plugs are spaced from the insulator nose, such as illustrated by a gap 172 between electrode plate 164 and an insulator nose 174. Gap 172 results in an increased surface area of electrode plate 164 being exposed to the combustion chamber as well as a surface area of a portion of an end of the center electrode wire 170 (which is completely shielded from the combustion chamber by the structure of spark plug 10 of the present disclosure). Such exposure increases the rate of heat transfer to the electrode head and, in one example, is known to have caused physical failure of the exposed portion of the electrode wire 70 at the point of connection with electrode plate 164, resulting in the catastrophic detachment of electrode plate 164 form center electrode wire 170, as illustrated by the photograph of
Spark plug 210 further includes a terminal electrode 240 and a center electrode 250 extending axially along axial centerline 214. Terminal electrode 240 includes a terminal wire 242 extending to a terminal stud 244 proximate to terminal end 216. In accordance with the example implementation of
With continued reference to
With center electrode wire 252 disposed within central bore 222, a conductive glass powder 262 is disposed within central bore 22 from terminal end 216, followed by insertion of terminal wire 242 of terminal electrode 240 into central bore 222, with terminal wire 242 being employed to tamp glass powder 262. Glass powder 262 is then fired at high-temperatures so as to be melted. Upon cooling, the melted glass powder 262 solidifies to form a solid glass lock 262-1 (see
Similar to that described above with respect to spark plug 10, by attaching center electrode head 254 to center electrode wire 252 after center electrode wire 252 is disposed within central bore 222 of insulative core 212, center electrode head 254 of spark plug 210 can be sized larger than the diameter of central bore 222. It is noted that techniques other than those described herein may be employed to assemble spark plug 210. For example, in other cases, center electrode head 254 may be attached to center electrode wire 252 before center electrode wire 252 is inserted within central bore 222.
As will be described in greater detail below, a large center electrode head provides an increased linear edge length (e.g., a continuous circumferential edge) which increases the spark point diversity of the center electrode head when forming a spark gap with a corresponding side electrode extending from the metal shell. In-turn, the increased spark point diversity enables a spark plug, in accordance with the present disclosure, to utilize an enlarged center electrode head formed with nickel-alloys traditionally employed for nickel spark plug electrodes while providing improved engine performance and achieving lifetimes comparable to iridium spark plugs.
When attached to center electrode wire 252, collar 306 is seated within counter bore 274 at insulative nose 220 of insulative core 212 such that a portion 310 of bottom surface 304 of electrode plate 300 surrounding collar 306 engages and is flush with end surface 275 of insulative nose 220 (e.g., see
In one example, as illustrated, electrode plate 300 is angled downward toward circumferential edge 314 at a head angle, θ, from upper surface 302 toward lower surface 304 such that a spark gap distance, dgap, of a spark gap 340 formed between a circumferential edge 316 of lower surface 304 of electrode plate 300 and circumferentially extending side electrode 236 may vary depending on head angle, θ (see
As illustrated, threaded sleeve 234 includes side electrode 236 axially extending from threads 322. In one example, as illustrated, side electrode 322 circumferentially extends from threaded region 322 and is ring-like in shape with an inner diameter, di, formed by an inner perimeter edge 236-1 and an outer diameter, do formed by an outer perimeter edge 236-2. As will be described in greater detail below (see
In one example, as illustrated, center electrode head 254 is attached to center electrode wire 252 with a braze material 330 disposed between a perimeter surface of center electrode wire 252 and an interior surface of bore 307 of collar 306 such that bottom surface 310 of electrode plate 300 is flush with the end surface 275 of insulative nose 220. In one example, as illustrated in addition to the connection formed by braze material 330, center electrode head 254 is further secured to center electrode wire 252 by a “staking” or “stamping” process where first end 257 of center electrode wire 252 is compressed (stamped) to form cap 256 which is seated within pocket 303 of center electrode head 254. In other examples (not illustrated), electrode head 254 may be connected center electrode wire 252 via a brazed connection (without cap 256). In one example, the respective shoulder regions 284 and 308 of insulative nose 220 and of center electrode head 254 serve to position electrode head 254 within counter bore 274 of insulative nose 220.
In one example, as illustrated, when attached to center electrode wire 252, circumferentially extending lower perimeter edge 316 of electrode plate 300 forms a continuous radial spark gap 340 having a gap distance, dgap, with the circumferentially extending edge 236-1 defining the inner diameter, di, of side electrode 236 (e.g., ground electrode). By forming a continuous radial spark gap 340, the entire perimeter edge 316 of electrode plate 300 forms a continuous edge which provides a spark point diversity so that electrode plate 300 does not wear or erode as quickly as known spark plugs having a single point spark gap or a plurality of discrete spark gaps, thereby extending the operational life of spark plug 210, in accordance with the present disclosure. In other examples, which are not explicitly illustrated herein, side electrode 236 may include multiple points, with each point forming a separate gap with electrode plate 300.
In one example, the diameter, dh, of center electrode head 254 is greater than the outer diameter, dn, of insulative nose 220, but less than the inner diameter, di, of side electrode 236 such that spark gap 340 is diagonal and at an acute angle, α, relative to central axis 214 such that spark gap 340 is not “shaded” by electrode plate 300 when spark plug 210 is disposed within a combustion chamber of an internal combustion engine. In examples, the gap distance, dgap, of spark gap 340 may be varied by adjusting various structural features, such as by varying the axial length, ln, of insulative nose 220, by varying the diameter, dh, of center electrode head 254, by varying the inner diameter, di, of side electrode 236, by varying the head angle, θ, of the circumferential edge 314 of disk-shaped electrode plate 300, and/or by varying the thickness, th, of electrode plate 300, or any combination thereof. In one example, gap distance, dgap, may exceed 2.0 mm. In other examples, electrode head 254 may be disposed relative to side electrode 236 such that a horizontal surface gap is formed between electrode plate 300 and side electrode 236 (a so-called “surface gap” spark plug).
At
Although center electrode head 254 is illustrated by
Although specific examples have been illustrated and described herein, a variety of alternate and/or equivalent implementations may be substituted for the specific examples shown and described without departing from the scope of the present disclosure. This application is intended to cover any adaptations or variations of the specific examples discussed herein. Therefore, it is intended that this disclosure be limited only by the claims and the equivalents thereof
This Non-Provisional patent application claims the benefit of the filing date of U.S. Provisional Patent Application Ser. No. 63/062,917, filed Aug. 7, 2020, entitled “SPARK PLUG WITH THERMALLY COUPLED CENTER ELECTRODE,” the entire teachings of which are incorporated herein by reference.
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