Piston and Piston Rings

Jun. 24, 2024

Piston and Piston Rings

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Piston and Piston Rings

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 cast aluminum 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.

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.

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 crankshaft counterweights.

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 an 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. Piston ring size and configuration vary depending on engine design and cylinder material.

Piston rings commonly used on small engines 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 wipe excess oil from the cylinder wall during piston movement. Excess oil is returned through ring openings to the oil reservoir in the engine block. Two-stroke cycle engines do not require oil rings because lubrication is supplied by mixing oil in the gasoline, and an oil reservoir is not required.

Figure 4 - Piston Rings

Figure 5 - Piston Ring Gap

Piston rings seal the combustion chamber, transferring heat to the cylinder wall and controlling oil consumption. A piston ring seals the combustion chamber through inherent and applied pressure. Inherent pressure is the internal spring force that expands a piston ring based on the design and properties of the material used. Inherent pressure requires a significant force needed to compress a piston ring to a smaller diameter. Inherent pressure is determined by the uncompressed or free piston ring gap. Free piston ring gap is the distance between the two ends of a piston ring in an uncompressed state. Typically, the greater the free piston ring gap, the more force the piston ring applies when compressed in the cylinder bore.

A piston ring must provide a predictable and positive radial fit between the cylinder wall and the running surface of the piston ring for an efficient seal. The radial fit is achieved by the inherent pressure of the piston ring. The piston ring must also maintain a seal on the piston ring lands.

In addition to inherent pressure, a piston ring seals the combustion chamber through applied pressure. Applied pressure is pressure applied from combustion gases to the piston ring, causing it to expand. Some piston rings have a chamfered edge opposite the running surface. This chamfered edge causes the piston ring to twist when not affected by combustion gas pressures.

Another piston ring design consideration is cylinder wall contact pressure. This pressure is usually dependent on the elasticity of the piston ring material, free piston ring gap, and exposure to combustion gases. All piston rings used by Briggs & Stratton engines are made of cast iron. Cast iron easily conforms to the cylinder wall. In addition, cast iron is easily coated with other materials to enhance its durability. Care must be exercised when handling piston rings, as cast iron is easily distorted. Piston rings commonly used on small engines include the compression ring, wiper ring, and oil ring.

Compression Ring

The compression ring is the top or closest ring to combustion gases and is exposed to the greatest amount of chemical corrosion and the highest operating temperature. The compression ring transfers 70% of the combustion chamber heat from the piston to the cylinder wall. Most Briggs & Stratton engines use either taper-faced or barrel-faced compression rings. A taper faced compression ring is a piston ring that has approximately a 1° taper angle on the running surface. This taper provides a mild wiping action to prevent any excess oil from reaching the combustion chamber.

A barrel faced compression ring is a piston ring that has a curved running surface to provide consistent lubrication of the piston ring and cylinder wall. This also provides a wedge effect to optimize oil distribution throughout the full stroke of the piston. In addition, the curved running surface reduced the possibility of an oil film breakdown due to excess pressure at the ring edge or excessive piston tilt during operation.

Wiper Ring

The wiper ring, sometimes called the scraper ring, Napier ring, or back-up compression ring, is the next ring away from the cylinder head on the piston. The wiper ring provides a consistent thickness of oil film to lubricate the running surface of the compression ring. Most wiper rings in Briggs & Stratton engines have a taper angle face. The tapered angle is positioned toward the oil reservoir and provides a wiping action as the piston moves toward the crankshaft.

The taper angle provides contact that routes excess oil on the cylinder wall to the oil ring for return to the oil reservoir. A wiper ring incorrectly installed with the tapered angle closest to the compression ring results in excessive oil consumption. This is caused by the wiper ring wiping excess oil toward the combustion chamber.

Oil Ring

An oil ring includes two thin rails or running surfaces. Holes or slots cut into the radial center of the ring allow the flow of excess oil back to the oil reservoir. Oil rings are commonly one piece, incorporating all of these features. Some on-piece oil rings utilize a spring expander to apply additional radial pressure to the piston ring. This increases the unit (measured amount of force and running surface size) pressure applied at the cylinder wall.

The oil ring has the highest inherent pressure of the three rings on the piston. Some Briggs & Stratton engines use a tree-piece oil ring consisting of two rails and an expander. The oil rings are located on each side of the expander. The expander usually contains multiple slots or windows to return oil to the piston ring groove. The oil ring uses inherent piston ring pressure, expander pressure, and the high unit pressure provided by the small running surface of the thin rails.

The piston acts as the movable end of the combustion chamber and must withstand pressure fluctuations, thermal stress, and mechanical load. Piston material and design contribute to the overall durability and performance of an engine. Most pistons are made from die- or gravity-cast aluminum alloy. Cast aluminum alloy is lightweight and has good structural integrity and low manufacturing costs. The light weight of aluminum reduces the overall mass and force necessary to initiate and maintain acceleration of the piston. This allows the piston to utilize more of the force produced by combustion to power the application. Piston designs are based on benefits and compromises for optimum overall engine performance

The Material Details & Evolution of Piston Ring Technology

The split piston ring commonly used today was first invented by John Ramsbottom in the late s. His invention immediately replaced the hemp style rings that were used in steam engines, and represent a quantum leap in performance capability. The advantages using this type of ring in the steam engine were overwhelming in terms of power, efficiency, and maintenance.

When you think of piston rings, have you ever considered that they are the smallest component of the internal combustion engine, yet have the largest responsibility? When you assemble an engine, you never really grasp what the piston ring is going to do during its lifespan, making the performance of this diminutive component even larger in reality.

The piston rings have three major tasks to ensure the engine makes consistent power efficiently. First of all, the ring must seal each cylinder effectively, without fail, for thousands&#;and sometimes hundreds of thousands&#;of miles before replacement. When the air and fuel mixture ignite in each cylinder, the ring must seal to the cylinder wall so the explosion can drive the piston down the bore. The piston ring&#;in reality a formed piece of wire&#;must also keep blow-by gases from entering the crankcase while containing the combustion explosion.

Secondly, the ring helps to transfer the heat from the piston induced by the explosion to the cylinder&#;s walls. The rings are the only contact between the cylinder bore and the piston, and this is the only way heat can be transferred into the cooling system from the combustion process.

Thirdly, and perhaps most importantly, the piston ring must control engine oil from entering the combustion chamber. Each cylinder bore is made to be much like an engine bearing. The hone scratches in the bore provide a pocket for oil to be trapped so the rings will have lubrication as they rotate and travel up and down in the cylinder. But all of the oil that gets splattered on the cylinder walls from the rotating assembly has to be scraped away to prevent oil from entering the combustion chamber, as oil that enters the combustion chamber can be detrimental to the combustion process by effectively lowering vehicle octane, potentially causing harmful repercussions.

Through the magic of research and development&#;and the trickle-down effect from OE manufacturing efforts&#;it seems as though every year piston rings become dimensionally thinner, yet engine performance improves. This applies to all applications, from custom racing pistons to off-the-shelf replacement pistons. If the piston rings have such an enormous job to do, then why are they becoming smaller? Are there any adverse effects that may arise in the future?

Extensive testing has shown that smaller ring widths have proven to be just as effective&#;and maybe a touch more so&#;than previous thicker versions. This is mainly due to the difference in the contemporary material being used for the piston ring compared to older, less efficient materials. In addition, differences in design and shape along with finish and coatings applied to the surface of the piston rings help to improve performance and reduce drag. These changes have proven to be more efficient, provide more power with less blow-by, and extend longevity. The best way to understand what is occurring in the piston ring world is to take a look back and understand where we came from. Thanks to input from Total Seal&#;s Keith Jones, who also assisted us with the photography and diagrams for this article.

Material Selection

A popular material used for piston rings is cast iron, often referred to as grey iron. The biggest advantage in using cast iron to manufacture pistons rings is that it will not gall or scuff the cylinder bore. And as long as the cast iron ring is sufficient in size, it will provide adequate seal. If the operating loads are increased or the size is decreased for the application, then ring seal can become an issue. When cast iron is used for the top ring, it is usually coated with molybdenum or chrome to prevent bore wear. If cast iron is used for the second ring, no coating is applied. Cast iron material is very brittle; under a microscope, the grain structure of cast iron is rectangular and sharp. This is why if you were to try to twist a cast iron ring it will break because the grain structure is easily fractured. Cast iron is popular because it is somewhat cost-effective to manufacture. The drawback to its use is that several manufacturing steps are required for completion&#;and it&#;s not ideal for high-performance engines.

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There are two primary methods in which a cast iron ring is made. The most common way is to take the desired outside diameter of the piston ring and form a mold. Then once the cast iron has been formed inside this cylindrical mold, the center of the mold is cut out to the inside piston ring dimension. To give an example, once the process is completed, you would have something similar to a gun barrel. Then each individual ring is cut from the mold sort of like slicing a loaf of bread.

The other way cast iron rings are formed is similar to the way a model car or truck is manufactured. When you open up a model car box, you find several sheets of plastic that have pieces formed that you break from the mold to extract the parts. Cast iron is poured into a mold much like the model car pieces, only in the shape of piston rings. When the process is complete the rings are snapped from the mold and final-machined for use. While cast iron rings may be affordable due to the cost of the material, they do require a lot of hands-on machining in order to be processed and finalized. Also, there is a lot of waste that has to be recycled once the finished product is achieved.

Ductile iron is another material used in the manufacture of piston rings; it has been around for quite a few years and is still common today. The forming process for ductile iron piston rings is extremely similar to that used to manufacture a cast iron ring. The composition of the material is taken from cast iron by extracting the carbon flakes&#;which is mostly graphite&#;and forming that material into a cylindrical mold to set the outside dimension. Then the inside dimension can be cut out. The rings can then be sliced from the &#;gun barrel&#; and heat-treated. Under a microscope, ductile iron has round nodular shaped grains that are very strong, unlike the grain structure for cast iron. If you were to take the ductile iron ring and try to break it you would find that it will only bend and twist into a pretzel shape. Ductile iron is twice as strong as cast iron and is used in high-output applications. Since most diesel engines are turbocharged, ductile iron rings were commonly used for their resistance to failure in high compression situations with high operating cylinder pressures.

The up and down motion of the piston keeps the keystone ring loaded in the ring groove of the piston and as a byproduct, also keeps the ring groove clean from the soot of the diesel fuel. The uniquely-shaped ductile iron keystone ring is not commonly used today, however. Because the use of Exhaust Gas Recirculation has become standard on nearly all internal combustion engines, when this shape is used, carbon packing tends to stick the ring in the piston groove, causing failure.

If you are not sure of what material your rings are made of, don&#;t try to bend them. An easy way to test them is to drop them on a table in your shop. If the ring makes a ringing sound it is ductile iron, and if it simply thuds onto the table, it is manufactured from cast iron.

Steel&#;s The Deal

Today&#;especially in high-performance and severe-duty applications&#;steel is used to construct piston rings. The advantages of steel rings are many: they are easier to manufacture, stronger and harder than ductile iron, and resist breakage especially in those demanding power-adder applications. The disadvantage? The materials are more expensive.

The manufacturing process for steel piston rings is simple; wire is cut from a spool of material measuring the desired proportions. There is no waste, and there are less steps from cutting to final product. Perhaps the best thing about using steel rings is that it can endure more heat stress from harsh environments and still hold its form without failure. And in high-RPM, low-tension, high-vacuum applications like NHRA Pro Stock and other naturally-aspirated racing classes, steel rings offer far better ring seal. The inside top surface will usually have a bevel which will help induce twist when the cylinder fires. The thin top ring is pushed down against the bottom of the top piston groove and gas pressure pushes the ring against the bore. Because the face of the ring is barrel shaped, as the piston travels down the bore the ring is in constant contact with the cylinder wall.

Steel Ring Details

In order for a steel ring to be compatible with cast iron cylinder bores, it must be coated with moly, chrome, PVD (Particle Vapor Deposition), or gas nitriding. Moly coatings are applied to the face of the ring. Moly offers a high resistance to scuffing, but also is porous which provides some oil retention.

Chrome is a very hard coating used in high load applications and is found often in dirt racing engines. The chrome coating can resist dirt impregnation and send the debris out the exhaust port. If you were to use moly coated rings in these applications, the dirt ingestion would be caught in the face of the ring because of porosity, and damage to the bore would result.

As a piston ring face application, PVD has become more popular in the last several years. PVD is a thin coating that is deposited on the ring using titanium or chromium evaporated by heat with a reactive nitrogen gas. This process will make the ring very hard, smooth, and temperature resistant.

Lastly, gas nitriding is a heat process that impregnates the ring with nitrogen which will cause the ring to case harden. This process hardens the surface somewhere around .001-inch deep; the cylinder bore will show signs of wear before the ring when gas nitriding is used.

Second rings are transitioning from cast iron to ductile iron and steel. Because the second ring scrapes most of the oil from the cylinder walls, steel rings for the second position are beveled on the underside to induce twist. As the piston goes down the bore the twist of the ring allows the tapered face to scrape the oil from the cylinder wall.

Napier rings&#;which use a hook-faced design&#;are also common for the second position. The hook pockets the oil as it is being scraped which allows the use of low tension oil rings in these situations. Second rings that are steel or ductile iron are not coated, as research has shown that coated second rings offer no advantages compared to an uncoated ring because the scraping action used to remove oil keeps them well lubricated.

Quick Assembly Tips

If you are assembling an engine and using steel rings, make sure to measure the free gap of the piston ring. Free gap is measured when you take the rings out of the box and lay them on a table. As an example, the gap in the piston ring laying on the table would be .600-inch. You install the piston ring in the engine and now the gap is .020-inch for your application. At freshen-up, the free gap now measures .500-inch which would be considered normal after the engine has been heat-cycled in competition. But, if the free gap measured .100-inch, then something is wrong with the air/fuel ratio or ignition timing because the ring is losing tensile strength and distorting due to too much heat.

Another tip is to debur and chamfer as little as possible when file-fitting piston rings. In addition, leave the edges as square as you can to offer better ring seal. Follow the manufacturer&#;s recommendations for the proper honing technique. Proper cylinder bore finish will offer the correct amount of oil retention for lubricating the ring material being used.

In Conclusion

Using a piston ring set which is thinner than you ever thought possible is an easy way to free up horsepower in your performance engine. The trickle-down impact from current OEM technologies have proven to be a winner in this particular instance. These ring designs are not detrimental to performance; with proper break-in procedures they can be expected to last many thousands of miles in a street application with no harmful side effects, although we can&#;t promise the same if you&#;re hitting them with a couple of kits of nitrous oxide every week on your Saturday night trips into Mexico.

Contact us to discuss your requirements of Piston Ring Manufacturers. Our experienced sales team can help you identify the options that best suit your needs.