This invention relates to ignition apparatus. More particularly, this invention relates to ignition apparatus for a spark-ignition internal combustion engine.
A spark-ignition internal combustion engine conventionally includes a number of spark plugs situated in a cylinder head of the engine for creating a spark in each cylinder thereof. Each spark plug is connected to a respective terminal of a distributor by a respective high tension ignition lead. The phrase “high tension”, is used to differentiate electrical components that are used to conduct charge at comparatively high potential from those components that conduct large at comparatively low potential. In the case of a typical automobile engine, high tension components can have a potential difference thereacross measured in kV, such as 25 kV, whereas low tension components would be raised to a potential of tens of volts. In operation, the distributor connects a high voltage across each ignition lead, and hence the respective spark plug, rapidly in succession. This high voltage is sufficient to produce a discharge arc, that is to say a spark, across a respective air gap of each spark plug. During the short-lived existence of the spark, charge flows in an associated ignition lead. The nature of the spark is that high frequency current exists in the lead. This is sometimes referred to as “high frequency noise” and tends to result in radio frequency radiation being emitted by the ignition lead. This radiation is sometimes referred to as radio frequency interference (RFI) as it may interfere with nearby electrical apparatus and thus be problematic. For example, in the case of an automobile, such radiation may interfere with audio equipment of the automobile, such as an in-car Hi-Fi, and may also interfere with computer processing apparatus of the automobile, such as engine management computers.
In an attempt to address this problem, engine and automobile manufactures have sought to use ignition leads with a high electrical resistance. For example, it has been found that use of ignition leads with a resistance of 16 kΩ/m acts to suppress high frequency noise. A drawback of increasing the resistance of ignition cables, however, is that the intensity of the spark may be reduced, resulting in incomplete combustion which in turn leads to reduced power output and increased emissions from the engine. The heating of the ignition leads brought about by their high resistance may also shorten their useful life. There is therefore a trade-off between high frequency noise suppression on the one hand and engine performance and ignition lead life on the other. In attempt to strike the correct balance, at least some international standards limit the resistance of ignition leads to 16 kΩ/m. Thus, the tendency has been for manufacturers to favour leads of high resistance but which are within this limit, for example leads with a resistance of 16 kΩ/m. Such leads, however, still give rise to the drawbacks set out above.
It is an object of at least one embodiment of this invention to address this problem.
Currently-available ignition cables tend to be of one of three different types of construction. The first type includes a highly electrically conductive metal wire, such as copper, to form an electrically conductive core. The second type includes electrically insulating fibres, such as glass or aramid, that are coated with an electrically conductive compound to form the conductive core. The third type also includes electrically insulating fibres, but these are surrounded by a ferrite layer, with a conducting metal wire being wound helically around both the fibres and the ferrite layer to form a core. The wire can be of Ni—Cr alloy, Cu—Sn alloy or stainless steel.
However, each of these types of construction suffers from drawbacks. Drawbacks of the type of construction that uses a copper core include poor resistance to corrosion and poor high frequency noise suppression, together with the resulting cable being rigid and heavy. The second construction type that includes a core formed of insulating fibres coated in a conductor exhibits the undesirable characteristic of an increasing resistance with use. This leads to a worsening of the problems associated with high resistance as set out above. The ferrite layer of the third construction type has poor mechanical properties and is prone to cracking, especially under dynamically varying and tensile forces.
It is an object of at least one embodiment of this invention to address these problems associated with currently-available cables.
According to one aspect of this invention, there is provided a high tension ignition cable for a spark ignition internal combustion engine, the cable having a resistance per unit length of less that 10 kΩ/m, and a core formed at least partly from an electrically conducting material that includes fibres of a non-metallic conducting material.
According to another aspect of this invention, there is provided ignition apparatus for a spark-ignition internal combustion engine, the apparatus including high tension ignition cable having a resistance per unit length of less that 10 kΩ/m, the apparatus further including radio frequency interference suppression means that includes at least one of:
The cable may have a resistance per unit length of less that 7 kΩ/m. It may have a resistance per unit length of less that 1 kΩ/m. It may have a resistance per unit length of less that 0.5 kΩ/m. More preferably, it has a resistance per unit length of less that 100 Ω/m. Most preferably, it has a resistance per unit length of less than 50 Ω/m.
It has been found that providing ignition apparatus that includes a cable of low resistance, such as less than 10 kΩ/m, has an effect on engine operation. This is particularly the case if the resistance per unit length of the cable is even lower, for example, less than 50 Ω/m. For example, the provision of such cable has been found to improve engine starting and idling, increase power output of the engine, improve fuel economy and reduce unburned hydrocarbon and toxic exhaust emissions, which in turn prolongs the life of any catalytic converter fitted to the engine. Improvements in combustion may also reduce carbon deposits deposited on spark plugs and hence prolong the useful life of sparkplugs.
The apparatus may include one, more or all of the features listed at (a) to (d), in any combination.
The connector that includes a resistor therein may be a connector for receiving a sparkplug, wherein the connector is a resistor spark plug boot. The resistor connector may be a connector for connector to a high tension electrical terminal, such as, for example, a terminal of a distributor or of a transformer coil.
The resistor spark plug and/or the connector that includes a resistor therein may include a resistor with a resistance of between 0.2Ω and 16Ω. More preferably the resistor is in the range of 300Ω to 9 kΩ. More preferably still, the resistor is in the range 500Ω to 6 kΩ. Most preferably, the resistor is in the range 1 kΩ to 4 kΩ.
It has been found that providing the ignition apparatus with a resistor spark plug or a resistor boot that has a resistor with such a resistance suppresses radio frequency interference caused by a changing current in the cable to an acceptable level, resulting in the apparatus achieving both the improved engine operating characteristics attributable to the low resistance cable and acceptable suppression of radio frequency interference.
The field stabilizer device preferably includes a stabilizer and/or a regulator, the stabilizer being arranged to stabilize the voltage of the current through the device and the regulator being arranged to regulate the voltage of the current through the device. Preferably the device is arranged to deliver a current with a voltage that is sufficiently constant so as to have a beneficial effect on noise suppression and/or of a magnitude that gives rise to good spark characteristics. The field stabilizer device may be arranged just to receive high tension ignition current. The field stabilizer device is preferably connected on the side of the cable remote from the spark plugs. The field stabilizer device is preferably connected on the input side of the distributor. The field stabilizer device may be connected on either side of a transformer coil. The field stabilizer device may be additionally arranged to receive current from other electrical components, such as electrical components associated with an automobile or an internal combustion engine, such as, for example, fuel pumps, transmission components, throttle components, an alternator, and so on. The field stabilizer device may be arranged to receive leakage current. The leakage current may be from components such as those just listed or conceivable any component, including, for example the automobile chassis. The leakage current may be grounded and/or recycled back to the battery and/or ignition components such as the distributor. The field stabilizer device may include a radio frequency interference (RFI) suppressor. The field stabilizer device may also be arranged to monitor the current that it receives. The field stabilizer device may further include field booster means for use with a molecular stabilizer and/or fuel cracker that is or are arranged to act on a fuel line of the engine.
The cable may have a core formed at least partly of an electrically conducting material. The core may include fibres of a non-metallic conducting material, such as, for example, carbon or graphite. The core may consist of a plurality of elongate ones of the fibres, extending side-by-side. Preferably, the fibre material has a specific gravity in the range 1.2 to 2.0. The core may be of fibres derived from the carbonisation of man-made fibres, coal tar and/or petroleum pitch. The man-made fibres may include natural polymers and their derivatives, such as cellulose and rayon. The man-made fibres may include synthetic polymers such homopolymers and/or copolymers of polyacrylonitrile. The man-made fibres may be oxidised in air at a temperature of 200 C to 300 C. The man-made fibres may be converted into an infusible form by chemical crosslinks at a temperature up to 300 C. The man-made fibres may be carbonised at a temperature of 1000 C to thereby convert the fibres into graphite; and, optionally, subsequently heat treated at a temperature in the range of 1500 C to 3000 C to form carbon or graphite fibre filaments. Preferably, the fibres have a polycrystalline structure orientated with graphite planes aligned in parallel to the fibre axis. Preferably the fibres have a tensile strength in the range of 100 000 to 900 000 lbs/sq in. Preferably, the fibres have good fatigue and/or damping characteristics, and preferably have high corrosion resistance and/or chemical inertness.
The core may be at least partly formed by supporting a substrate, to which carbon fibre is attached, about a support member. The substrate may in the form of an elongate strip of material such as a tape. The substrate may be impregnated with the carbon fibre. The tape may be of a polymeric material. The arrangement may be similar in construction to a conventional fibre-reinforced tape. The tape may be wrapped around the support. The substrate may be a fabric and may be woven or non-woven.
The core may be formed by extrusion.
The core may include a plurality of the fibres suspended in a substrate. The substrate may be a thermoplastic. The substrate may be polymeric. The core may be of a carbon fibre reinforced polymeric composite, in which the carbon fibre is preferably in the form of filaments or in the form of cut lengths of the fibre. Less preferably, the core includes carbon fibre in powder form. The polymeric material may be, for example, epoxy or a thermoplastic such as polyamide, polycarbonate, thermoplastic polyurethane, polyphenylene sulphide or polybutylene terephthalate.
The core may further include metal particles suspended in the substrate. The addition of metal particles can be used to increase conductivity, thereby reducing resistance.
Forming the core with conducting elements in the form of non-metallic conductive fibre, whether these be a plurality of elongate fibres arranged substantially in parallel, or fibres suspended in substrate, or fibres in some other form, successfully addresses at least some of the problems associated with currently-available leads. For example, non-metallic conductive fibres can be more resistant to corrosion than, for example, copper; and can exhibit a more constant resistance over time than non-conductive fibres coated with a conductive material. Non-metallic conductive fibres are also less prone to cracking that is, for example, ferrite material.
The semiconductor material may be disposed around the core. The semiconductor material may form a layer, such as a coating, on and around the core. The semiconductor material may be disposed in the core. The core may be impregnated with the semiconductor material. Preferably the semiconductor material is flexible so that it is resistant to cracking or breaking when the cable is bent as it may be during use. The semiconductor material may be plastically deformable. The semiconductor material may be elastically deformable. The semiconductor material may include polymeric compositions, such as, for example: acrylate bases and their copolymers, thermoplastics such as PE and/or EVA, thermosets such as crosslinkable polyolefin, ethylene-vinyl acrylate copolymer, ethylene-propylene copolymer, ethylene-propylene-diene terpolymer, ethylene-vinyl acetate copolymer, epichlorohydrin homopolymer and/or copolymer, nitrile rubber, hydrogenated nitrile rubber, acrylic rubber and silicone rubber. The semi-conductor material is preferably based on thermosets like crosslinkable polyolefin, ethylene-vinyl acetate copolymer, ethylene-vinyl acrylate copolymer, epichlrorhydrin polymers and silicone rubber. A flexible semi-conductor material with good mechanical properties, that is resistant to bending and heat ageing, and that has low volume resistivity, is preferred. For these reasons, a semi-conductor material based on acrylate type and epichlorohydrin type polymers is preferred. The semi-conductor material may include a conductive filler material, such as, for example, conductive carbon black, graphite and/or conductive metal, which may be in the form of a powder. Preferably the conductive filler material is in the range of 20 PHR to 200 PHR. PHR refers to the weight of the conductive filler relative to 100 parts weight of the polymer. Selection of the polymer base material, together with the amount of conductive filler therein, can be chosen to give a semi-conductor material with a preferred conductivity.
The semiconductor layer may be formed by extrusion. It may be formed by impregnation.
The cable may include no semiconductor material.
The electric resistivity at 15 C of the layer of semiconductor material may be in the range of 1000 Ω/m to 1000 MΩ/m.
The cable may include insulating material therein or thereon. The insulating material may form one more insulating layer of the cable. Preferably, the cable includes an insulating layer on and around the core. Preferably, the cable includes an insulating layer disposed between the core and the semiconductor material, which may form another layer on and around the insulating layer. The cable may also or alternatively include an insulating layer on and around the semiconductor material. The insulating material may be a polymeric material and may include, for example: thermoplastics, such as polyvinyls, polyolefin bases, polyamide and polyester; thermoplastic elastomers; and preferably themosets, such as crosslinkable polyolefin, ethylene-propylene copolymer, ethylene-propylene-diene terpolymer, chlorinated polyethylene, chloroprene rubber, chlorosulfonated polyethylene and silicone rubber.
The or each insulating layer may be formed by extrusion.
The cable may include protecting material to protect other components of the cable from damage. The protecting material may be formed around one or more of the other components of the cable to form a protecting layer. The protecting material may form an outermost layer of the cable. The protecting material may include one or more yarns of fibre that is or are spiraled, or preferably braided, around other components of the cable to form the protecting layer. The protecting material may include glass fibre and/or man-made fibre yarn such as, for example, polyester, polyamide, polyaramid, cellulose and viscous rayon. The protecting layer may include fibre-reinforced tape that is wrapped around other components of the cable to form the protecting layer. The protecting layer increases the strength of the cable and protects other layers thereof. This increase in strength can be useful during manufacturing of the cable when a high strength is necessary if connectors are to be press-fitted to ends of the cable.
The protecting layer may be reinforced with a reinforcing material. The reinforcing material may include glass fibre and/or steel wire. The reinforcing material may form a layer on and around the protecting layer.
The cable may include an outermost layer. The outermost layer is preferably flame retarding and is formed of a flame retardant material. Preferably the outermost layer is formed of a material that has good dielectric properties. For example, the outermost layer may be formed of a material that exhibits volume resistance at 20 C of at least 1013 Ohm/cm. Preferably the outer most layer is formed of a material that is resistant to one or more of: oil, fuel, abrasion and ozone. Preferably the flame retardant material exhibits heat resistance in the range of 125 C to 200 C. The outermost flame retardant layer are based on ethylene-vinylacetate co-poloymer, crosslinkable polyolefin, ethylene-vinyl acrylate copolymer, ethylene-propylene copolymer, ethylene-propylene-diene terpolymer, hydrogenated nitrile, silicone rubber, chloroprene rubber, chlorinated polyethylene, and chlorosulfonated polyethylene. The outermost flame retardant layer is preferably at least partly formed of zero-halogen low-smoke non-corrosive polymeric materials.
Preferably, each component of the cable is of a material that does not contain halogens and that preferably is flame retardant. This has the result of the cable tending not to emit hazardous toxic and corrosive gases during a fire.
The cable may be for connecting between a distributor and a spark plug. The cable may be for connecting between a transformer and a distributor. The cable may be for connecting between any two terminals for the purposes of conducting charge at a high potential.
It is envisaged that the cable and/or the ignition apparatus may be for use with any type of engine in which it is desired that RFI caused by ignition be minimised. For example, the cable and/or the ignition apparatus may be used with carburetor-based or fuel injected engines, with gasoline or LPG engines, or with automobile, motorcycle or industrial engines.
According to a further aspect of this invention, there is provided a field stabilizer device as defined hereinabove.
Specific embodiments of the invention will now be described by way of example only and with reference to the accompanying drawings, in which:
In general, the ignition apparatus 10 is arranged with an input of the transformer coil 20 connected to a 12V DC supply of electricity from a low tension electrical circuit 22. The transformer coil 20 is conventional. A high tension output of the transformer coil 20 is connected to an input of the field stabilizer device 30. The field stabilizer device 30 is not conventional and at least in part embodies the present invention. A high tension output of the field stabilizer device 30 is connected to an input of the distributor 40. The distributor 40 is conventional. The Four high tension ignition leads 50 that at least partly embody the invention are each connected to a respective output of the distributor 40, it being envisaged in this embodiment that the apparatus 10 is for use with a typical automotive engine. Each lead 50 terminates in a connector 52, 54 at each of its ends. The connector 54 that is adjacent the distributor is conventional and is for plugging into an output terminal thereof. The other connector 52 is a spark plug-receiving boot 52. For simplicity of illustration, only one boot 52 is shown. A respective spark plug is received in each boot 52. Again, for simplicity, a single plug 60 is shown received in the boot 52.
As mentioned above, the coil 20 and distributor 40 are conventional. These will therefore not be described in further detail. The remaining components are however now described in more detail.
The field stabilizer device 30 is shown in more detail in
As stated above, in this embodiment, at least one of the inputs to the device 30 is the high tension cable running from the high tension output of the transformer coil 20. However, it an alternative embodiment, the device 30 may be positioned upstream of the coil 20 so as to receive a low tension supply of electricity, with the output of the device 30 being connected to the input of the coil 20. The device 30 may also be used in embodiments wherein the distributor includes a transformer coil therein, such as can be the case with modern multi-injection ignition systems. In such an embodiment, the device would be position upstream of the distributor.
In this embodiment, each of the high tension ignition leads 50 is the same as each other lead 50. Only one of the leads 50 will therefore be described in detail. The representative lead 50 includes a length of cable 56 running between the connector 54 that is for plugging into the distributor 40 and the spark plug-receiving boot 52. The composition of the cable is shown in
With continued reference to
As stated above, the one 52 of the connectors 52, 54 that is for connecting to the spark plug 60 is termed a “boot”. In this embodiment, the boots 52 are conventional. It is, however, envisaged that an unconventional form of boots termed “resistor boots” may be used. Resistor boots are similar to conventional boots but include a series-mounted electrical resistor inside the boot arranged such that electrical charge passing from the ignition cable to a spark plug received in the boot must pass through the resistor. In this embodiment, the spark plugs 60 that are used in the ignition apparatus 10 are an unconventional form of spark plug known as “resistor spark plugs”. Resistor spark plugs are similar to conventional spark plugs but additionally include a series-mounted resistor therein to provide the plug with an internal resistance. In the present invention, the resistor spark plugs 60 are selected each with a resistance of about 1KΩ. It is envisaged, however, that resistor plugs with other resistances may be selected.
In operation, the distributor 40 periodically connects a high potential difference across the cable 56 in the conventional manner. As will be appreciated, this causes a spark at the spark plug 60, with charge then flowing in the conductor core 100 of the cable 56. As the conductor core is of low resistance per unit length—less than 50 Ω/m in this embodiment—a good strong spark is produced. This minimises the risk of poor or incomplete combustion of the fuel-air mixture in which the spark is created.
The use of resistor spark plugs 60, although increasing the overall resistance of the cable, boot and spark plug arrangement and so, at least to some extent, will weaken the spark, tends to prolong the duration of the spark and so acts to reduce the high frequency noise resulting therefrom.
High frequency noise that does result from the sparking will be in the form of a high frequency current in the cable 56. As a result of the so-called “skin effect”, this high frequency current will tend to exist in the radially outermost conductive part of the cable 56. This part is the semiconductor layer 120. The semiconductor layer is chosen and arranged so as to effectively suppress high frequency currents therein. Thus, the high frequency noise is further suppressed.
From the forgoing description, it should be understood that the various component parts of the ignition apparatus described above may be used with great flexibility and the beneficial result of a low-resistance cable with acceptable high-frequency noise suppression still obtained. It should also be understood that one or more of those component parts of the apparatus may be omitted and the apparatus still used to advantageous effect. For example, although it is envisaged that the field stabilizing device could be used additionally to suppress high frequency noise, this component may be omitted and the remaining components selected and arranged such that acceptable high frequency noise suppression is still obtained. Similarly, resistor spark plugs and/or resistor boots may be used, and their respective resistances selected, such that, in combination with the cable, acceptable high frequency noise suppression is obtained. Furthermore, it is envisaged that no resistor spark plugs or resistor boots may be used and, instead, the field stabilizer device be employed to ensure acceptable high frequency noise suppression. Another option would be to use neither resistor spark plugs, resistor boots, nor the field stabilizer device and instead rely upon semiconductor material in the cable to suppress high frequency noise. Other combinations of the components described herein are envisaged and will present themselves to the skilled reader in the light of the foregoing description.
In alternative cables that also embody the present invention, a carbon fibre-filled thermoplastic composite may be substituted for the carbon fibre core 100 in any of the embodiments described above. In the carbon fibre-filled thermoplastic composite, the carbon fibre is in the form of short filaments and/or cut lengths suspended in thermoplastic material.
In other alternative cables that embody the present invention, the reinforcing layer 140 may be omitted from any of the embodiments described above if the outermost protective layer 150 were arranged so as to have acceptable resistance to mechanical actions such as cutting, tearing, abrasion and compression.
Number | Date | Country | |
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Parent | 11568297 | Oct 2006 | US |
Child | 12683276 | US |