During the Second World War, the science of metallurgy thrived and prospered manifolds. Necessity is the mother of all pioneer technology. During this time period, a craving need was felt for better materials that could sustain high challenges and temperatures and yet serve the demanding needs of operations. The infantry was expected to travel light and might not afford to carry replacement parts along with ammo. The science of logistics was also growing. Hence maintenance and repair operations were considered a luxury than the usual necessity.
It was of these difficult times for metallurgical sciences that a new material was identified. Ceramics were remodelled to form a new model of materials wholesale custom ceramic flower planter pot that would sustain the challenging circumstances and come good on most expectations. Also the raw material required for this new ceramic was equally cheap so because of this, it was a win-win situation for the manufacturers. This man made silicon carbide compound later went on to be named as ‘Wear Resistant Ceramic’.
The Silicon carbide compound was impossible and almost wear-proof. The biochemistry of bonds in the ceramic spanned out ordinary manner that the nitrite bonded silicon compound shown great covalence and capacity to resist rust at any temperature, pressure, dampness and pH value. As an immediate application the compound was used in mining and nutrient processing operations. The results were along expected lines and wear resistant ceramics announced their arrival on grand scale.
The wear resistant ceramic showed an uncommon capacity to withstand mechanical phenomenon like rust, wear, rust, erosion, scrapping, etc. these inevitable mechanical side-effects were prime reason for most manufacturing activities being at the top of cost and low on returns. These ceramics ascertained that the downtime associated with the processes were low and manageable.
Currently, the wear resistant ceramics are available in various forms. Boron, Tungsten, Nitride, etc. are some of the available additives in modern ceramics. Some of the common applications of these ceramics are only in armoured vehicles, forming, polishing and lapping processes in foundries, pumps, jets, etc. In addition, general consumption components are now casted and made from wear resistant ceramics to counter for the high replacement costs and downtime expenses.
Some of the properties of wear resistant ceramics that produce them stand out from other countries in the materials include its non-porous surface it does not let any harmful particles enter or dimple the material couture. Ceramics demonstrate high electrical stability. They are bad conductors of electricity thereby supporting in using them for critical applications. The wear resistant ceramics are highly supple in nature.
They wear resistant ceramics demonstrate high quotient for Young’s Modulus of elasticity indicating their flexibility to variety of shapes and sized. The life span of a ceramic is not determined by the ledge life of the material. Being a man made compound the ceramics can theoretically survive till times unlimited. They are impossible materials that sustain wear and scratching causing elements and work to the main benefit of the user because of their longevity of operations.
In the modern production sectors, corporate are not bashful on investing big on onetime expenses. However the Operating Expenditure (OPEX) should rationalize the investments in the long run. The wear resistant ceramic can virtually fit into almost any component and can be modelled accordingly. The product bandwidth varies from the simplest versions of silica to the complicated tungsten ceramics. The future certainly holds adequate business sense for organizations to line-up themselves with Wear resistant ceramics.