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CETARCH Guide

What are technical ceramics?

Technical ceramics — also known as advanced ceramics or engineered ceramics — are the family of ceramic materials designed for extreme performance: near-diamond hardness, abrasion resistance, chemical inertness and stability at high temperatures.

Definition

Technical ceramics, advanced ceramics, engineered ceramics

All three names describe the same class of material: ceramics of controlled composition — such as alumina (aluminium oxide, Al₂O₃) and zirconia — formed and sintered at temperatures above 1,500 °C until they develop a dense, hard, chemically stable microstructure. Unlike traditional ceramics (bricks, tiles, tableware), technical ceramics are engineering materials: each formulation is designed for a target property, such as wear resistance, chemical resistance or heat resistance.

In industry, their most common role is replacing metal where it fails. Surfaces exposed to continuous abrasion — mineral slurries, abrasive powders, ash, grain — wear out hardened steel in weeks. A wear-resistant ceramic lining at the same point multiplies equipment life by up to 10× compared with alloys such as Ni-Hard.

9 Mohshardness — close to diamond
1300–1600 HVVickers hardness (CT CEDUR line)
> 1.600 °Csintering temperature
+10×service life vs. Ni-Hard in abrasion

Properties of technical ceramics

Technical ceramics vs. traditional ceramics

Traditional ceramics start from natural raw materials (clays) and tolerate wide variations in composition — the goal is shape and cost. Technical ceramics start from high-purity oxides with controlled particle size and composition, and are sintered at much higher temperatures, virtually free of glassy phase. The result is a structural material with predictable, reproducible mechanical properties, specified through hardness, density, flexural and water-absorption testing.

Materials

Key materials: alumina first

The most widely used material in industrial technical ceramics is alumina (Al₂O₃), for its combination of hardness, chemical inertness and cost. CETARCH manufactures the CT CEDUR line, with alumina content from 90% to 99.7% and nanoparticles built into the formulation — including doped-zirconia and rare-earth compositions for specific demands.

Material Al₂O₃ content Hardness HV Best for
CT CEDUR 90Standard · lining 90% a 99,5%> 1300 HV High-hardness, chemical-attack lining
CT CEDUR 94HHHigh abrasion 95,8–96,3%1450–1500 HV Excellent abrasion resistance
CT CEDUR 96HHAbrasion + impact 95,8–96,3%1500–1600 HV Severe abrasion and impact
CT CEDUR 99HHHigh purity 99,5–99,7%1550–1600 HV Abrasion, impact, chemistry and thin/complex parts
Technical ceramic sintering kiln with in-house refractories
Sintering kiln designed and built by CETARCH — firing up to 1,750 °C.

Where technical ceramics are used

Wherever equipment lives with abrasion, corrosion or heat, there is an application for technical ceramics. The most common cases in heavy industry:

In these sectors, ceramics take the shape of ready-to-install components: cyclones, pipes and elbows, lined pumps, bushings, orifice plates and custom-engineered parts.

How technical ceramics are made

  1. Raw material — high-purity oxides; CETARCH produces its own alumina, zirconia and rare-earth nanoparticles, contamination-free.
  2. Forming — pressing, extrusion or slip casting, depending on part geometry.
  3. Sintering — firing above 1,600 °C in in-house kilns, densifying the material virtually free of glassy phase.
  4. Grinding & QC — precision machining plus hardness, density and absorption testing to guarantee the specification.
FAQ

Frequently asked questions about technical ceramics

What is the difference between technical ceramics and advanced ceramics?

None — they are synonyms. "Technical ceramics", "advanced ceramics" and "engineered ceramics" all describe the same family of high-performance ceramic materials, designed for structural and protective functions in industry.

Are technical ceramics harder than steel?

Yes, much harder. Technical alumina reaches 9 Mohs and over 1,300 HV Vickers hardness — well above hardened steels and wear alloys such as Ni-Hard. That is why, in pure abrasion, a ceramic component can last 10 times longer than its metal equivalent.

How long does a wear-resistant ceramic lining last?

It depends on the severity of the process, but the field benchmark is up to 10× the service life obtained with Ni-Hard or hardened steel at the same point. Beyond lasting longer, the part keeps its geometry — preserving process efficiency between shutdowns.

Which industries use technical ceramics?

Mining, cement, steel, energy (thermal power), chemical, ceramics and glass, pulp and paper, and agribusiness — any process with abrasion, corrosion or high temperature is a candidate.

Do technical ceramics resist chemicals?

Yes. Alumina is inert to aggressive acids, alkalis and solvents under typical process conditions, with no corrosion and no contamination of the processed material — an important advantage over metals in chemical and pulp & paper plants.

Can ceramic parts be custom made?

Yes. CETARCH designs and manufactures 100% custom parts: engineering analyses the wear point, defines the geometry and the right CT CEDUR formulation, sinters and grinds the part, and follows up installation and field performance.

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