Advantages
Ceramic microstructures enjoy covalent bonding inherent between non-metal elements. This means they share electrons. This atomic co-operation yields a very strong attraction force and because of this, ceramics offer a series of benefits in comparison to metals.
Disadvantages
I know what you’re thinking: Look at all of those advantages! Why aren’t all bearings made of these brilliant materials? But I’m afraid I have a bit of potentially bad news.
Advantages vs Disadvantages Chart
This table highlights the aforementioned advantages and disadvantages in much fewer words:
Table 1: Advantages and Disadvantages of Ceramic Bearings
Common Ceramic Bearing Materials: Silicon Nitride, Zirconia and Silicon Carbide
Silicon Nitride combines the retention of high strength and creep resistance with oxidation resistance. It has better high temperature capabilities than most metals and its low thermal expansion coefficient gives a better thermal shock resistance in comparison with most ceramic materials.
Silicon Nitride is black in colour and the material of choice for vacuum and high speed applications. It’s 58% lighter than traditional steel causing a reduction in centripetal force generated by the rolling elements, which significantly increases fatigue life time. Unlike other ceramic materials, Silicon Nitride can hold similar loads to bearing steel; however, it is unsuitable for the race design in any application with shock loading due to the hardness of the material.
Picture 1: Example of Silicon Nitride Bearings
Zirconia (ZrO2) was developed in the 1960s and ‘70s to produce a thermal barrier on the external tiles of a space shuttle in order to allow the shuttle to re-enter the Earth’s atmosphere without disintegrating. Since then, Zirconia has been the material of choice for high temperature and highly corrosive applications. The density and thermal expansion of Zirconia is more similar to steel than that of any other ceramic material; therefore, it does not have the same weight saving and thermal shock resistance enjoyed by other ceramic materials. However, compared with Silicon Nitride and Silicon Carbide, Zirconia has a high fracture toughness. Zirconia is white in colour.
Picture 2: Examples of Zirconia, left, and Silicon Nitride Bearings, right
Less frequently used than other ceramic materials due to its raw materials cost and difficulty to machine, Silicon Carbide offers the best heat and corrosion resistance of all the ceramic materials.
Silicon Carbide is best used under low loads and in highly corrosive environments.
The material properties of these ceramic materials are listed in the tables below along with 440C Stainless Steel for comparison purposes.
Table 2: Material properties of Zirconia, Silicon Nitride, Silicon Carbide and 440C Stainless Steel
Applications
Space and Satellites
Many modern materials find their origins in pioneering space technology. Many ceramic materials that are now commonly used in bearings were developed for just this reason. Space exploration exhibits extreme loads and turbulent environments while demanding strict weight constraints and vacuum requirements.
Ceramic bearings are able to fulfil these requirements as many of them are lightweight and vacuum compatible. Unlike their steel equivalents, ceramic bearings are able to run unlubricated which not only stops possible contamination of delicate components in the surrounding applications but also reduces weight as there is no need for heavy greases. They also don’t experience cold welding unlike their steel counterparts.
Chemical and Medical
Many applications where contamination can be potentially life threatening, ceramic bearings provide the best solutions. Whether it is mixing chemicals or within medical equipment, standard steels succumb to the effect of strong acids and alkalis. Standard steels, including stainless steel, can rust when washed with solutions and result in particulate contamination. Ceramic bearings do not react in the same way as standard steels because they are chemically inert compounds. This means they are not chemically reactive to corrosive materials and will not release harmful by-products.
Standard steel bearings also require some form of lubrication, either grease or oil, which can be difficult to clean and eventually breed bacteria unsuitable for sanitary applications. Moreover, as ceramics bearings can run dry and free of additional lubrication, there is no additional microbiology to worry about.
Scientific Instrumentation
Some highly specialized instrumentation may require a fully non-magnetic system. The magneto-optical phenomenon called the Faraday Effect showcases the interaction between light and a magnetic field in a medium. If light is being measured or utilized in an instrument, a standard steel bearing must be avoided. Ceramic bearings are perfect for situations when magnetic resonance is an issue.
Conclusion
Ceramic bearings exhibit a vast range of advantages for engineering applications but also have disadvantages that must be taken into consideration. They are extremely hard, corrosion-resistant and have a high elastic modulus. They are able to run without lubrication, have low thermal expansion, are normally low density and have non-magnetic qualities. However, they are expensive, have low load capacities, are sensitive to thermal shock and are difficult to achieve a high quality of surface finish on.
Whether you are using Silicon Nitride, Zirconia or even Silicon Carbide, ceramic bearings are available for a wide range of applications such as space, chemical, medical, and scientific instrumentation.