Static seals are affixed between stationary materials and are most often held under some degree of compression. Given the elastic nature of rubber seals the material “pushes back” against the stationary material thereby forming a seal tight enough to secure the contents of the system. 

Some practical examples of elastomeric static seals include: O-rings, gaskets, & washers.

Static seals such as o-rings and washers are most often single piece rubber only constructions that are inserted into a gland/opening designed specifically for the system they are intended to seal.  

Gaskets can either be a single piece of rubber as shown above, or they can also be overmolded or coated onto rigid carriers made of metal, thermoplastic, or composite materials as in the examples of air intake manifold gaskets and cylinder head gaskets found on internal combustion engines.

Dynamic seals are almost always overmolded to a rigid substrate and are affixed on one side to a stationary material but experience movement of one or more other materials in contact with on the opposite side of the seal.  This movement is generally either rotating or reciprocating. 

Some practical examples of dynamic seals exposed to rotational motion would be engine and/or transmission shaft seals which are located at the crank shaft or drive shaft exit points of an internal combustion engine or transmission. In either case the seal serves to keep the lubricants securely inside the system while also preventing water, dirt, and debris from contaminating the same system. 

The external walls of the seals are stationary and affixed into a bore. A metal shaft passes through the inner opening of the seal as it exits the engine or transmission. The internal side of the seal is in contact with the shaft which rotates at speeds ranging from 0 to over 5000 rpm in either rotational direction. The sealing element contacting the shaft, often called the lip, is usually (but not always) held in place under modest compression by a metal garter spring.  In addition to the heat generated by the system itself, the movement of the shaft against the seal being forced against the metal surface by the spring creates additional frictional heating which can contribute to thermal degradation, cracking, and wearing away of the elastomeric seal material and ultimately leaking of the lubricant.

A practical example of a seal exposed to reciprocal motion would be a valve stem seal which is located on the top of an internal combustion engine along the valve train.  The valve and stem assembly moves up and down, opening and closing the intake and exhaust ports with each combustion cycle for every cylinder.

The metal base and or/ external wall of the seal is stationary and affixed to the engine while the valve stem passes through the elastomeric opening of the seal which is held against the stem by a metal garter spring. The stem is continually coated with engine oil in its downstroke movement. In the upstroke movement, as it passes through the seal, the oil is wiped down by the seal to a very thin film on the stem.  In addition to the nearby heat of the combustion chamber of engine, and the hot exhaust gasses, the movement of the stem against the spring loaded rubber seal generates frictional heating which can lead to thermal degradation, cracking, and wearing away of the sealing surface that ultimately causes excess oil film formation leading to leakage.