Piston FAQ
Piston Anatomy
A piston is a cylindrical engine component that slides back and forth in the cylinder bore by forces produced during the combustion process. The piston acts as a movable end of the combustion chamber. The stationary end of the combustion chamber is the cylinder head. Pistons are commonly made of a castaluminum alloy for excellent and lightweight thermal conductivity. Thermal conductivity is the ability of a material to conduct and transfer heat. Aluminum expands when heated and proper clearance must be provided to maintain free piston movement in the cylinder bore. Insufficient clearance can cause the piston to seize in the cylinder. Excessive clearance can cause a loss of compression and an increase in piston noise.
Not a Subaru piston, pictures are for representation purposes only
Piston features include the piston head, piston pin bore, piston pin, skirt, ring grooves, ring lands, and piston rings. The piston head is the top surface (closest to the cylinder head) of the piston which is subjected to tremendous forces and heat during normal engine operation.
Not a Subaru piston, pictures are for representation purposes only
A piston pin bore is a through hole in the side of the piston perpendicular to piston travel that receives the piston pin. A piston pin is a hollow shaft that connects the small end of the connecting rod to the piston. The skirt of a piston is the portion of the piston closest to the crankshaft that helps align the piston as it moves in the cylinder bore. Some skirts have profiles cut into them to reduce piston mass and to provide clearance for the rotating crankshaftcounterweights.
Not a Subaru piston, pictures are for representation purposes only
A ring groove is a recessed area located around the perimeter of the piston that is used to retain a piston ring. Ring lands are the two parallel surfaces of the ring groove which function as the sealing surface for the piston ring. A piston ring is an expandable split ring used to provide a seal between the piston and the cylinder wall. Piston rings are commonly made from cast iron. Cast iron retains the integrity of its original shape under heat, load, and other dynamic forces. Piston rings seal the combustion chamber, conduct heat from the piston to the cylinder wall, and return oil to the crankcase.
Not a Subaru piston, pictures are for representation purposes only
Piston rings commonly used include the compression ring, wiper ring, and oil ring. A compression ring is the piston ring located in the ring groove closest to the piston head. The compression ring seals the combustion chamber from any leakage during the combustion process. When the air-fuel mixture is ignited, pressure from combustion gases is applied to the piston head, forcing the piston toward the crankshaft. The pressurized gases travel through the gap between the cylinder wall and the piston and into the piston ring groove. Combustion gas pressure forces the piston ring against the cylinder wall to form a seal. Pressure applied to the piston ring is approximately proportional to the combustion gas pressure.
A wiper ring is the piston ring with a tapered face located in the ring groove between the compression ring and the oil ring. The wiper ring is used to further seal the combustion chamber and to wipe the cylinder wall clean of excess oil. Combustion gases that pass by the compression ring are stopped by the wiper ring.
An oil ring is the piston ring located in the ring groove closest to the crankcase. The oil ring is used to lubricate the cylinder wall during piston movement. Excess oil is returned through ring openings to the oil reservoir in the engine block.
Piston Manufacturing Techniques
Pistons are manufactured via a cast or forged technique. Some consider hypereutectic pistons to be the “third manufacturing technique”, but as they are actually a cast piston with physical properties that fall between cast and forged pistons due to their unique aluminum alloy.
Cast pistons are made by pouring melted aluminum into a mold that shapes the metal into a piston.
Forged pistons are formed using a giant press that takes a block of metal and pounds it into shape under thousands of tons of pressure. The tooling needed to do this is much more expensive than the tooling used to make a casting, and it wears out quicker. This makes forged pistons more costly. Forged pistons have inherent advantages in terms of density, ultimate strength, and durability. Forging eliminates metal porosity, improves ductility, and generally allows the piston to run cooler than a cast unit. Within reason, forgings can be lightened without adversely affecting structural integrity. However, forged pistons expand and contract more under changing temperatures, so they traditionally require greater piston-to-wall clearance than cast pistons. The manufacturing technique produces a metal slug, which is then CNC milled to produce the final piston shape.
Piston Alloys
With regard to cast piston, they generally use aluminum alloys doped with silicon. Aluminum silicon alloys used fall into three major categories: eutectic, hypoeutectic, and hypereutectic. Probably the easiest way to describe these categories is to use the analogy of sugar added to a glass of iced tea. When sugar is added and stirred into the iced tea it dissolves and becomes inseparable from the iced tea. If sugar is continuously added, the tea actually becomes saturated with sugar and no matter how much you stir, the excess sugar will not mix in and simply falls to the bottom of the glass in crystal form.
Silicon additions to aluminum are very similar to the sugar addition to the iced tea. Silicon can be added and dissolved into aluminum so it, too, becomes inseparable from the aluminum. If these additions continue, the aluminum will eventually become saturated with silicon. Silicon added above this saturation point will precipitate out in the form of hard, primary silicon particles similar to the excess sugar in the iced tea.
This point of saturation in aluminum is known as the eutectic and occurs when the silicon level reaches 12%. Aluminum with silicon levels below 12% are known as hypoeutectic (the silicon is dissolved into the aluminum matrix). Aluminum with silicon levels above 12% are known as hypereutectic (aluminum with 16% silicon has 12% dissolved silicon and 4% shows up as primary silicon crystals).
Pistons produced from these alloy categories each have their own characteristics. Hypoeutectic pistons usually have about 9% silicon. This alloy has been the industry standard for many years but is being phased out in favor of eutectic and hypereutectic versions. Most eutectic pistons range from 11% to 12% silicon.
Eutectic alloys exhibit good strength and are economical to produce. Hypereutectic pistons have silicon content above 12%. In addition to greater strength, scuff, and seizure resistance, the hypereutectic will improve groove wear and resist cracking in the crown area where operating temperatures are severe.
It is the primary silicon that gives the hypereutectic it’s thermal and wear characteristics. The primary silicon acts as small insulators keeping the heat in the combustion chamber and prevents heat transfer, thus allowing the rest of the piston to run cooler. Hypereutectic aluminum has 15% less thermal expansion than conventional piston alloys.
A. Graham Bell, in his book "Forced Induction Performance Tuning" (published in 2002 by Haynes), says hypereutectic pistons are a poor choice for turbocharged engines. Hypereutectic cast pistons have twice as much silicon in the aluminum alloy as regular cast pistons (15-20% instead of only 7-8%). According to Bell, the added silicon leaves them "quite brittle and, as such, prone to breaking when subjected to detonation."
Forged pistons, barring unique manufacturer’s specifications, generally use two aluminum alloys, which are 4032 and 2618. Typical recommended applications are as follows: 4032 is a durable and lighter material usually used in naturally aspirated engines. 2618 Alloy is designed for the rigors of blown, marine, and nitrous applications.
4032 pistons will have quieter cold start operations due to their tighter piston to wall clearances compared to 2618 pistons. This is due to the 15% greater thermal expansion seen in the 2618 alloy. 15% may seem like a lot, but do the math. Considering a piston to bore clearance of 2/1000's of an inch, 15% is only .0003". Once the pistons have reached their operating temperature, the noise (piston slap) differences should be nearly identical in volume between the two alloys. 4032 pistons will have reduced oil consumption and longer ring life compared to their 2618 cousins due to their better cold start tolerances. While to many these physical comparisons point towards 4032, you must understand that 2618 pistons, for their slight “defects”, are clearly superior in terms of tensile strength and fatigue endurance to 4032. This is why most piston manufacturers specify the 2618 alloy for use in Subaru (turbocharged) pistons.
A wonderfully informative thread about piston expansion by be read via this link.
Piston Manufacturers
www.ariaspistons.com
www.cppistons.com
www.cobbtuning.com
www.cosworth.com
www.jepistons.com
www.junauto.co.jp
www.mahle.com
www.manleyperformance.com
www.rosspistons.com
www.techworkseng.com
www.wiseco.com
For the record, Cobb Tuning’s pistons start life as JE Piston forgings that are wholly CNC machined by Cobb Tuning. This is a common practice though, as many “manufacturers” use other manufacturers’ forgings as a 2000 ton forge costs millions whereas a CNC machine may be within their capital reach. In fact, JE Piston themselves are rumored to use TRW forgings. Additionally, you may find XXX’s pistons are actually pistons from one of the above manufacturers made to XXX’s specifications. This list represents true manufacturers and not resellers. Also realize these are the companies that stock Subaru specific pistons. As long as you have the correct measurements, almost any aftermarket piston manufacturer can custom make pistons to your specifications.
Piston Coatings
Dry film lubricants, also known as solid film lubricants, provide a lubricating film that reduces friction, inhibits galling and seizing, reduces piston scuffing, extends cylinder bore life, and in some instances can aid in dispersing heat. One of the obvious reasons for using a lubricating coating is to reduce friction, which improves wear, extends part life, and frees up power normally lost due to friction. A second major benefit is a reduction in part temperature. As well, no machining is 100% perfect, so the coating will wear and make up for very slight differences decreasing blow by.
Most dry film lubricants are Molybdenum Disulfide based. Why not Teflon? PTFE, also known as Teflon, is listed as having the lowest coefficient of friction (COE). However, under high speed and load, the COE of PTFE degrades while that of MOS2 (Molybdenum Disulfide) improves, until it is significantly better than PTFE. Moly also attracts oil, keeping an adequate film on the part unlike PTFE, which sheds oil.
Dry film lubricants are primarily applied to piston skirts.
Thermal barrier coatings are designed to reduce the transfer of heat. Thermal barrier coatings generally consist of a ceramic material. They are primarily applied to piston crowns. Coating the piston's crown will cause heat reflectivity, driving a percentage of any detonation energy back into the fuel burn zone, to increase fuel burn efficiency. It will also lower carbon buildup, which reduces detonation quality, as it builds up on the piston's crown and increases the risk of detonation damage to the piston crown surface. By retaining minimal heat on the surface of the piston, less heat is transferred to the incoming fuel mixture, leading to a reduction in pre-ignition which leads to detonation. This type of coating also reduces oil temperature. It also provides a good safety margin in case you get a sudden rise in EGTs from a bad tune or a bad tank of gas.
Thermal barrier coatings are primarily applied to piston crowns.
Thermal dispersants are capable of transferring heat faster than the bare metal surface alone. This is particularly important to pistons to prevent hot spotson the piston face. Depending on the coating manufacturer, thermal dispersant properties are combined into a thermal barrier coating or a dry film lubricant. The coatings can also allow heat at the surface to move more evenly over the surface reducing hot spots. They also reflect heat into the combustion chamber for more even distribution of heat, allowing more efficient combustion of the fuel. This allows more of the fuel molecules to be oxidized, which in turn, means less fuel is needed for optimum power.
Thermal dispersants are primarily applied to piston crowns.
Oil shedding coatings are designed to increase cooling efficiency by not allowing oil to coat certain surfaces where it may heat up. By continually shedding and replenishing the oil supply to treated surfaces, this will ensure maximum thermal conductivity. Heat transfers most rapidly when there is a large difference in temperature. The longer oil clings to a hot surface the hotter the oil becomes. By shedding the cooling oil more rapidly, cooler oil is splashed over the surface more frequently.
Oil shedding coatings are primarily applied to piston bottoms.
While there are numerous coatings manufacturers, the three largest are Swain Tech Coatings, High Performance Coatings (HPC), and Polymer Dynamics, also known as Poly Dyn.
Piston Anatomy
A piston is a cylindrical engine component that slides back and forth in the cylinder bore by forces produced during the combustion process. The piston acts as a movable end of the combustion chamber. The stationary end of the combustion chamber is the cylinder head. Pistons are commonly made of a castaluminum alloy for excellent and lightweight thermal conductivity. Thermal conductivity is the ability of a material to conduct and transfer heat. Aluminum expands when heated and proper clearance must be provided to maintain free piston movement in the cylinder bore. Insufficient clearance can cause the piston to seize in the cylinder. Excessive clearance can cause a loss of compression and an increase in piston noise.
Not a Subaru piston, pictures are for representation purposes only
Piston features include the piston head, piston pin bore, piston pin, skirt, ring grooves, ring lands, and piston rings. The piston head is the top surface (closest to the cylinder head) of the piston which is subjected to tremendous forces and heat during normal engine operation.
Not a Subaru piston, pictures are for representation purposes only
A piston pin bore is a through hole in the side of the piston perpendicular to piston travel that receives the piston pin. A piston pin is a hollow shaft that connects the small end of the connecting rod to the piston. The skirt of a piston is the portion of the piston closest to the crankshaft that helps align the piston as it moves in the cylinder bore. Some skirts have profiles cut into them to reduce piston mass and to provide clearance for the rotating crankshaftcounterweights.
Not a Subaru piston, pictures are for representation purposes only
A ring groove is a recessed area located around the perimeter of the piston that is used to retain a piston ring. Ring lands are the two parallel surfaces of the ring groove which function as the sealing surface for the piston ring. A piston ring is an expandable split ring used to provide a seal between the piston and the cylinder wall. Piston rings are commonly made from cast iron. Cast iron retains the integrity of its original shape under heat, load, and other dynamic forces. Piston rings seal the combustion chamber, conduct heat from the piston to the cylinder wall, and return oil to the crankcase.
Not a Subaru piston, pictures are for representation purposes only
Piston rings commonly used include the compression ring, wiper ring, and oil ring. A compression ring is the piston ring located in the ring groove closest to the piston head. The compression ring seals the combustion chamber from any leakage during the combustion process. When the air-fuel mixture is ignited, pressure from combustion gases is applied to the piston head, forcing the piston toward the crankshaft. The pressurized gases travel through the gap between the cylinder wall and the piston and into the piston ring groove. Combustion gas pressure forces the piston ring against the cylinder wall to form a seal. Pressure applied to the piston ring is approximately proportional to the combustion gas pressure.
A wiper ring is the piston ring with a tapered face located in the ring groove between the compression ring and the oil ring. The wiper ring is used to further seal the combustion chamber and to wipe the cylinder wall clean of excess oil. Combustion gases that pass by the compression ring are stopped by the wiper ring.
An oil ring is the piston ring located in the ring groove closest to the crankcase. The oil ring is used to lubricate the cylinder wall during piston movement. Excess oil is returned through ring openings to the oil reservoir in the engine block.
Piston Manufacturing Techniques
Pistons are manufactured via a cast or forged technique. Some consider hypereutectic pistons to be the “third manufacturing technique”, but as they are actually a cast piston with physical properties that fall between cast and forged pistons due to their unique aluminum alloy.
Cast pistons are made by pouring melted aluminum into a mold that shapes the metal into a piston.
Forged pistons are formed using a giant press that takes a block of metal and pounds it into shape under thousands of tons of pressure. The tooling needed to do this is much more expensive than the tooling used to make a casting, and it wears out quicker. This makes forged pistons more costly. Forged pistons have inherent advantages in terms of density, ultimate strength, and durability. Forging eliminates metal porosity, improves ductility, and generally allows the piston to run cooler than a cast unit. Within reason, forgings can be lightened without adversely affecting structural integrity. However, forged pistons expand and contract more under changing temperatures, so they traditionally require greater piston-to-wall clearance than cast pistons. The manufacturing technique produces a metal slug, which is then CNC milled to produce the final piston shape.
Piston Alloys
With regard to cast piston, they generally use aluminum alloys doped with silicon. Aluminum silicon alloys used fall into three major categories: eutectic, hypoeutectic, and hypereutectic. Probably the easiest way to describe these categories is to use the analogy of sugar added to a glass of iced tea. When sugar is added and stirred into the iced tea it dissolves and becomes inseparable from the iced tea. If sugar is continuously added, the tea actually becomes saturated with sugar and no matter how much you stir, the excess sugar will not mix in and simply falls to the bottom of the glass in crystal form.
Silicon additions to aluminum are very similar to the sugar addition to the iced tea. Silicon can be added and dissolved into aluminum so it, too, becomes inseparable from the aluminum. If these additions continue, the aluminum will eventually become saturated with silicon. Silicon added above this saturation point will precipitate out in the form of hard, primary silicon particles similar to the excess sugar in the iced tea.
This point of saturation in aluminum is known as the eutectic and occurs when the silicon level reaches 12%. Aluminum with silicon levels below 12% are known as hypoeutectic (the silicon is dissolved into the aluminum matrix). Aluminum with silicon levels above 12% are known as hypereutectic (aluminum with 16% silicon has 12% dissolved silicon and 4% shows up as primary silicon crystals).
Pistons produced from these alloy categories each have their own characteristics. Hypoeutectic pistons usually have about 9% silicon. This alloy has been the industry standard for many years but is being phased out in favor of eutectic and hypereutectic versions. Most eutectic pistons range from 11% to 12% silicon.
Eutectic alloys exhibit good strength and are economical to produce. Hypereutectic pistons have silicon content above 12%. In addition to greater strength, scuff, and seizure resistance, the hypereutectic will improve groove wear and resist cracking in the crown area where operating temperatures are severe.
It is the primary silicon that gives the hypereutectic it’s thermal and wear characteristics. The primary silicon acts as small insulators keeping the heat in the combustion chamber and prevents heat transfer, thus allowing the rest of the piston to run cooler. Hypereutectic aluminum has 15% less thermal expansion than conventional piston alloys.
A. Graham Bell, in his book "Forced Induction Performance Tuning" (published in 2002 by Haynes), says hypereutectic pistons are a poor choice for turbocharged engines. Hypereutectic cast pistons have twice as much silicon in the aluminum alloy as regular cast pistons (15-20% instead of only 7-8%). According to Bell, the added silicon leaves them "quite brittle and, as such, prone to breaking when subjected to detonation."
Forged pistons, barring unique manufacturer’s specifications, generally use two aluminum alloys, which are 4032 and 2618. Typical recommended applications are as follows: 4032 is a durable and lighter material usually used in naturally aspirated engines. 2618 Alloy is designed for the rigors of blown, marine, and nitrous applications.
4032 pistons will have quieter cold start operations due to their tighter piston to wall clearances compared to 2618 pistons. This is due to the 15% greater thermal expansion seen in the 2618 alloy. 15% may seem like a lot, but do the math. Considering a piston to bore clearance of 2/1000's of an inch, 15% is only .0003". Once the pistons have reached their operating temperature, the noise (piston slap) differences should be nearly identical in volume between the two alloys. 4032 pistons will have reduced oil consumption and longer ring life compared to their 2618 cousins due to their better cold start tolerances. While to many these physical comparisons point towards 4032, you must understand that 2618 pistons, for their slight “defects”, are clearly superior in terms of tensile strength and fatigue endurance to 4032. This is why most piston manufacturers specify the 2618 alloy for use in Subaru (turbocharged) pistons.
A wonderfully informative thread about piston expansion by be read via this link.
Piston Manufacturers
www.ariaspistons.com
www.cppistons.com
www.cobbtuning.com
www.cosworth.com
www.jepistons.com
www.junauto.co.jp
www.mahle.com
www.manleyperformance.com
www.rosspistons.com
www.techworkseng.com
www.wiseco.com
For the record, Cobb Tuning’s pistons start life as JE Piston forgings that are wholly CNC machined by Cobb Tuning. This is a common practice though, as many “manufacturers” use other manufacturers’ forgings as a 2000 ton forge costs millions whereas a CNC machine may be within their capital reach. In fact, JE Piston themselves are rumored to use TRW forgings. Additionally, you may find XXX’s pistons are actually pistons from one of the above manufacturers made to XXX’s specifications. This list represents true manufacturers and not resellers. Also realize these are the companies that stock Subaru specific pistons. As long as you have the correct measurements, almost any aftermarket piston manufacturer can custom make pistons to your specifications.
Piston Coatings
Dry film lubricants, also known as solid film lubricants, provide a lubricating film that reduces friction, inhibits galling and seizing, reduces piston scuffing, extends cylinder bore life, and in some instances can aid in dispersing heat. One of the obvious reasons for using a lubricating coating is to reduce friction, which improves wear, extends part life, and frees up power normally lost due to friction. A second major benefit is a reduction in part temperature. As well, no machining is 100% perfect, so the coating will wear and make up for very slight differences decreasing blow by.
Most dry film lubricants are Molybdenum Disulfide based. Why not Teflon? PTFE, also known as Teflon, is listed as having the lowest coefficient of friction (COE). However, under high speed and load, the COE of PTFE degrades while that of MOS2 (Molybdenum Disulfide) improves, until it is significantly better than PTFE. Moly also attracts oil, keeping an adequate film on the part unlike PTFE, which sheds oil.
Dry film lubricants are primarily applied to piston skirts.
Thermal barrier coatings are designed to reduce the transfer of heat. Thermal barrier coatings generally consist of a ceramic material. They are primarily applied to piston crowns. Coating the piston's crown will cause heat reflectivity, driving a percentage of any detonation energy back into the fuel burn zone, to increase fuel burn efficiency. It will also lower carbon buildup, which reduces detonation quality, as it builds up on the piston's crown and increases the risk of detonation damage to the piston crown surface. By retaining minimal heat on the surface of the piston, less heat is transferred to the incoming fuel mixture, leading to a reduction in pre-ignition which leads to detonation. This type of coating also reduces oil temperature. It also provides a good safety margin in case you get a sudden rise in EGTs from a bad tune or a bad tank of gas.
Thermal barrier coatings are primarily applied to piston crowns.
Thermal dispersants are capable of transferring heat faster than the bare metal surface alone. This is particularly important to pistons to prevent hot spotson the piston face. Depending on the coating manufacturer, thermal dispersant properties are combined into a thermal barrier coating or a dry film lubricant. The coatings can also allow heat at the surface to move more evenly over the surface reducing hot spots. They also reflect heat into the combustion chamber for more even distribution of heat, allowing more efficient combustion of the fuel. This allows more of the fuel molecules to be oxidized, which in turn, means less fuel is needed for optimum power.
Thermal dispersants are primarily applied to piston crowns.
Oil shedding coatings are designed to increase cooling efficiency by not allowing oil to coat certain surfaces where it may heat up. By continually shedding and replenishing the oil supply to treated surfaces, this will ensure maximum thermal conductivity. Heat transfers most rapidly when there is a large difference in temperature. The longer oil clings to a hot surface the hotter the oil becomes. By shedding the cooling oil more rapidly, cooler oil is splashed over the surface more frequently.
Oil shedding coatings are primarily applied to piston bottoms.
While there are numerous coatings manufacturers, the three largest are Swain Tech Coatings, High Performance Coatings (HPC), and Polymer Dynamics, also known as Poly Dyn.
