Automobile Repair/Spark plugs
A spark plug initiates combustion in an internal combustion engine. A plug sits right inside the combustion chamber and can be removed for inspection. An examination, or "reading" of the characteristic markings on the firing end of the spark plug can indicate conditions within the running engine. A spark plug's firing end will be affected by the internal environment and will bear the marks as evidence of what is happening inside the engine while running. Usually there is no other way to know what is going on inside an engine running at peak power. The information obtained is especially important in high performance engines to refine the adjustment of all the systems.
The reading of spark plugs for a racing engine is a precision technique distinct from the more generic reading of spark plugs from general purpose engines, as the published information is intended for commercial mechanics to diagnose engine damage.
A racing engine is tuned whilst in prime condition. These engines require fine adjustment to much tighter tolerances. The most relevant spark plug parts for reading are at the tip, the center and side electrodes as well as part of the insulator.
When a spark plug fires, it ignites the fuel-air mixture, creating a fireball inside the combustion chamber. The size of this fireball or 'kernel' depends on the exact composition of the mixture between the electrodes and the level of combustion chamber turbulence at the time of the spark. A small kernel will make the engine run as though the ignition timing was retarded. A large kernel appears like the timing was advanced for that individual cycle. The combustion process produces characteristic marks on the spark plug. It is these marks that you can analyze.
Spark plug construction
- Ribs: The ribs prevent electrical energy from leaking from the terminal to the metal case along the side of the insulator. The longer the current has to travel because of the ripples the higher the resistance thereby assisting with isolation.
- Insulator: Made from Aluminum Oxide ceramic. Designed to withstand 1,200 deg. F. and 60,000 volts. The exact composition and length of the insulator, extending from the metal case into the combustion chamber partly determines the heat range of the plug.
- Metal Case: Bears the torque of tightening the plug. Removes heat from the insulator and passes it on to the engine head. It acts as the ground for the sparks passing through the center electrode to the side electrode.
- Center Electrode: Can be made of copper, nickel-iron or precious metals. The center electrode is designed to eject electrons because it is the hottest (normally) part of the plug. The electrons 'boil off' from the hot electrode. A further improvement would be to use a pointed electrode but a pointed electrode would melt after only a few seconds. The development of precious metal high temperature electrodes allows the use of a much smaller center electrodes that are smaller in diameter-closer to a point, but they do not melt or corrode away. A smaller electrode also absorbs less heat from the spark and initial flame energy.
- Side Electrode: The side electrode is made from high nickel steel and is welded to the side of the metal case. The side electrode also runs very hot, especially on projected nose plugs.
As the electrons are pushed in from the coil, a voltage difference appears between the center electrode and side electrode. No current can flow because the fuel and air in the gap is an insulator, but as the voltage rises further, it begins to change the structure of the gases between the electrodes.
Once there is a small channel of gas which is affected this way, it is said to be "ionized". An ionized gas becomes a conductor and can pass electrons.
As the current of electrons surges across the gap, it raises the temperature of the spark channel to 60,000 K. The intense heat in the spark channel causes the ionized gas to expand very quickly, like a small explosion. This is the "click" you hear when watching a spark.
The heat and pressure force the gases to react with each other and at the end of the spark event there should be a small ball of fire in the plug gap as the gasses burn on their own. The size of this fireball or kernel depends on the exact composition of the fuel-air mixture between the electrodes at the time of the spark. A small kernel will make the engine run as though the ignition timing was retarded and a large one like the timing was advanced for that individual cycle.
Reading spark plug conditions for racing engines
Spark plug reading flashlight/magnifiers aid in reading spark plugs.
Accurate Reading Conditions
The most accurate plug readings are obtained after an engine is well tuned with new plugs and after shutting the engine at the end of a strong full throttle run. Having the engine shut down quickly and cleanly avoids creating misleading information and provides evidence from full power conditions. Idle conditions may be relevant for non-racing readings and general engine diagnosis.
Racers are concerned with only two gap styles illustrated in figure 2.
- Projected Nose
- Conventional gap
Most racing engines use projected nose, fine wire plugs, but some engines need the conventional gap fine wire plugs because of clearance problems or difficulty in cooling the plug. Surface gap, retracted gap, etc., plugs are not suitable for high performance use.
Engine conditions and impact on spark plugs
With respect to heat range, manufactured racing engines already have most of the selection done. The stock plug is usually within two heat ranges of ideal. The only change that might be needed to use the fine wire version of the same plug (usually 1 or 2 steps hotter). For heavily modified standard engines the choice is less clear. A plug 2 to 3 ranges colder than stock and of the fine wire type would be a good starting point. Complete the ignition timing and fuel system adjustments first and then select the final heat range for the spark plug.
Figure 1 illustrates hot versus cold spark plugs. Spark plugs are capable of running anywhere from cold to hot in a given engine, depending on plug design. Use the hottest plug that won't over heat itself under the worst conditions.
A hot plug does not make an engine run hot, nor a cold plug make an engine run cold. A hot plug merely means that the insulator nose will run hotter and keep itself clean by burning off deposits. Needs clarification, per NGK..... http://www.ngksparkplugs.com/techinfo/spark_plugs/installation.asp?nav=31300&country=US#heat
A plug which is too cold collects carbon and fuel deposits on its insulator, which leaks energy from the ignition, causing loss of power, if allowed to continue it will foul (not spark at all).
The length of the insulator determines the heat range of a plug. Use the hottest plug that doesn't burn the tip of the center electrode.
If your plug is too cold, you will see deposits on the nose of your plug. Figure 6 illustrates this. If your plug is too hot, the porcelain will be porous looking, almost like sugar. The material which seals the center electrode to the insulator will boil out.
Note: A lower number usually means a colder spark plug but not all the time. Ex: NGK uses high numbers for cold spark plugs as Bosch uses a lower number for colder spark plugs.
As the voltage builds up in the plug, it may leak to ground through any deposits, which are on the insulator nose, robbing the spark gap of its energy. This is what happens when you foul a plug. Any conductive deposits on the insulator nose will, (even if the engine doesn't misfire) cause a reduction of energy in the spark leading to small,erratic kernels, slightly reducing power.
Ignition timing can be seen on the center electrode tip. If the timing is too advanced by 2 to 4 degrees, the tip of the electrode will be scorched clean for about one millimeter from the tip. The center electrode will have its edges rounded from heat. The material which seals the center electrode to the insulator may boil out. This is illustrated in figure 3.
When the timing is correct or retarded, the fuel deposits on the electrode tip will extend right to the tip. So you can only see ignition advance on the plug, not retard.
This is the most important part of plug reading and the most misunderstood. Mechanics are often talk about "color" on their plugs. However there is only one color to look for on a plug and that is black. It is soot, the remains of combustion.
The brown color you see on a plug is only the result of gasoline additives and nothing more. In an engine which is running well, the plug will run hot enough to burn off all the brown color, leaving only white and black. Under test conditions as there will be little time to accumulate fuel deposits.
The black will be found at the base of the electrode insulator nose where the porcelain meets the metal case. This is the only place on the plug where you can see if the engine is rich or lean. This carbon forms a ring around the base of the electrode very quickly. It can be seen after only a few seconds of full throttle running, but a couple of full throttle runs should be made so that the ring will be very clear. (See figure 4).
While learning to read plugs it will be much easier to see the mixture ring if you cut apart the spark plug and remove the porcelain from the metal case. (See figure 5.) You will see the mixture ring starting where the seal was and extending up the insulator some distance.
The optimum width of this ring is about 0 to 2mm millimeters with .5mm being ideal for many engines, more than this is too rich for most engines and many engines respond to a mixture where almost no ring is visible but you must conduct power tests to find the ideal for your situation. Make sure your heat range is correct because it may affect the mixture ring.
Power produces heat and one can see the heat of combustion on the metal case of the plug. The only plugs that show this feature are the cadmium-electroplated types. Don't use the black oxide plugs because they can't show engine heat. Racing engines will produce enough heat to burn the plating off the end of the threads on the case as illustrated in figure 7. You should have 1 to 4 threads scorched by heat on your plugs. If you can't get that heat, you have a problem. Even if every other indication on the plug is perfect, the engine is not making its potential power.
You can see the performance of your ignition system on the electrodes where the spark jumps from one to the other. The spark should burn clean a spot on both electrodes where the spark touches as illustrated in figure 8.
If the spot is small and irregularly shaped, your ignition is going bad. You should watch this spot when you are experimenting with spark plug gaps.
"Detonation" is one of the worst things that can happen in a powerful engine because they are running near the edge of the envelope. It can occur for many reasons; high compression, overly advanced timing, fuel too low in octane rating, too high of a heat range spark plug or poorly shaped combustion chamber. It can often be seen on the spark plug before serious damage occurs.
You will see small balls of fuel and metal deposits on the porcelain tip and smaller balls of debris on the electrode tip. The metal case will look as if it were sandblasted (inside the engine the piston will also look sand blasted). See figure 9.
(Detonation is not entirely bad however, maximum power is always found with just a trace of detonation, not enough to be seen on the plug or to be heard by the driver, but enough to leave a slight sandblasted look (just enough to remove the carbon deposits) on the edge of the piston, after a race. (Drag racers may not have visible marks even though it is happening due to the short running time). It is theorized that the trace detonation is partially burning the otherwise unburnable mixture in crevices of the piston and chamber.)
Other observable factors
The information mentioned above is used in concert with other observable factors such as the operator's impressions, exhaust pipe deposits, combustion chamber and piston deposits, engine sound, actual measured performance of the engine, exhaust temperature and sometimes exhaust gas analysis.