Refractory Selection is Part Science, Part Art

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In refractory lining maintenance, recommendations for repairs and relines often consist of selecting a similar or equivalent material to replace the original. Sometimes that’s sufficient. Many refractory contractors and maintenance teams strive to use best practices by purchasing the same refractories that have worked on similar equipment in the past, but this carries the risk of assuming that nothing has changed in the process, production or maintenance of the equipment over time. This assumption can be a dangerous bet because furnace equipment is made to meet the immediate demands of each thermal processor, and these demands often change depending on factors like production orders and maintenance capacities.

Choosing an appropriate refractory lining for an application isn’t always a straightforward decision. Many times, it is part science and part art. Making an effective choice requires knowledge of the industrial application process, refractory performance expectations and potential refractory service failures. These factors must then be weighed against each other to find the right balance and best solution. While there are a number of important criteria to consider, refractory engineers focus on five aspects to make an evaluation and choose a refractory material for each specific application: thermal, mechanical, chemical, logistics and value – as well as connections among these aspects.

What is the best refractory material choice? To answer this question, each individual application requires both an overall evaluation of the thermal-processing furnace in regard to each of the factors mentioned and then a careful balance of the five aspects in finding the best solution that meets both the immediate and long-term needs of the thermal processor.

1. Thermal Requirements: Temperature
   For any high-temperature industrial process, the primary piece of information to know is the operating and maximum temperatures. The refractory lining chosen must meet the operating temperature requirements.

   Refractory linings are designed to maintain physical properties at very high temperatures – 932°F and above. Refractories used to line thermal equipment must have proper insulating properties to reduce the steel skin temperatures to acceptable levels, usually well below 300°F. The use of multi-component linings, which employ a dense refractory material at the hot face with an insulating refractory or ceramic-fiber board or blanket behind it, is known for achieving adequate cold-face temperatures with structural integrity for long thermal life.

   Spalling and thermal shock are the most common thermal failure mechanisms in a refractory lining. These are due to crack formations caused by temperature cycling and high thermal loads. There is a lot more to learn about fracture mechanics thanks to researchers, but knowing the importance of this phenomenon is enough for the application specialist.

   In recent years, many thermal processors have experienced increased production demands. Meeting that need means that their furnaces are operating at higher temperatures for increased output. Running furnaces harder and faster often has the unintended consequence of overheating the refractory to the point that phase changes in the refractory matrix start to occur, causing lower-temperature glassy phases to form, softening the refractory and shortening life. Due to this, the refractory engineer often needs to consider a material with higher refractoriness to meet the performance needs of shock resistance and high thermal loading. This usually means a higher-alumina material.

2. Physical Properties: Mechanical
   The vast majority of higher-performing refractories in service today have been developed to maximize materials’ physical properties to improve lining lifespan and keep furnaces running at their best performance. Much of the information on a product Technical Data Sheet is devoted to the physical properties of the material, such as cold crushing strength, hot/cold MOR and abrasion resistance. All of these are based on well-defined ASTM standards to make valid comparisons among various choices.

   Refractory linings experience all sorts of mechanical and thermal loads that lead to wear and eventual failure, requiring repairs or replacement. Some of these are excessive expansion, thermal cycling fatigue, mechanical impact (dynamic loading), severe abrasion and erosion, pinch spalling, tensile loads, large hydraulic loads (such as in molten-metal containment furnaces) and creep (deformation at high temperatures over time). While a deeper discussion of each of these failure modes is beyond the scope of this article, knowing the type of potential refractory failures for each application becomes the solution in choosing the refractory to best address the failure mode present.

   During a visual refractory inspection, the lining can often give clues about failures. Crack patterns, wall buckles, surface spalls, discolorations and other visual differences occur in locations and manners that correspond with their failure type. Mechanical and thermal forces will find weak points and initiate cracking. Many times, these occur in typical geometric locations and patterns – such as sharp inside corners, archways, midpoints of a lining and in circular patterns – indicating a particular failure system. These will usually indicate shock and expansion due to high thermal loads, inadequate expansion allowance, deficient material properties for the application and/or improper anchoring.

3. Corrosion: Chemical
   Chemical attacks on the refractory matrix have been a fundamental concern of ceramics engineers since the beginning of refractory development. Chemical reactions between the vessel’s contents and the refractory at high temperatures can cause a change in the structure of the refractory matrix, which can have a detrimental effect on the performance and life of the lining. Chemical or mineralogical changes due to reactions occurring within the refractory lining can cause excessive volume change of the crystal structure or reduction of the oxides in the lining, causing breakdown of the ceramic bonds in the cement. The most common examples of these are:
   • A reducing atmosphere of carbon monoxide reacting with the lining, such as in CO boilers
   • An H2 reaction in the lining, which reduces silica in the refractory matrix at high temperatures
   • Molten slags, such as in coal-fired boilers
   • Alkali corrosion from ash in wood-burning furnace applications
   • Corundum growth in aluminum furnaces, especially those with aggressive alloys containing MgO

4. Installation: Logistics
   In addition to the aforementioned elements, refractory construction contractors are faced with multiple logistics pressures to get their customers’ thermal-processing equipment back on-line. This means that the choice of anchoring systems, installation methods and bake-out becomes an important consideration.

   The adage “time is money” is often a deciding influence when crafting a refractory solution. “Get it back up and running ASAP” is often the most pressing need communicated by the thermal processor. For example, while a brick lining often gives customers a highly durable option, bricking a job is very labor-intensive, requires high levels of experience and usually takes a long time to complete. A cast-in-place lining may yield the best physical properties in service, but the time also needed for forming (or multiple formings), casting/pumping, then stripping may not be desirable. In other words, the required length of downtime may not justify these options.

   Another example is the use of low-cement castables, which have superior properties. These have been around since the Plibrico Company first developed them, but they require more careful and longer bake-out. Gunning or shotcreting the lining could be a viable option if time or cost is a determining factor because forming is not required, and material can be placed at higher rates.

   While a cast product theoretically produces the best physical properties in general, followed by shotcrete and gun mixes, time limits may require another method of installation. Other factors to consider may be to ram the lining using plastic, which requires no setting or moist cure requirements. With the advent of reduced bake-out refractories, such as Plibrico’s Fast Track castables and gun mixes, contractors can place material and fire several hours sooner. This saves time and money but often at a cost of reduced physical properties. Again, it is a balancing act.

5. Price: Value
   Refractory linings are one of the most significant operational costs over the life of an industrial furnace. Therefore, when choosing a material for the application, price is always a very important factor. However, value is not only reducible to price. There is often more than one choice of materials to pick from.

   The economics of each individual application can direct the engineer/specialist to recommend one solution over another. When we speak of price, the real driver is value. Everyone wants a refractory product installed that is “good, fast and inexpensive.” However, it is often very difficult to achieve all three of these simultaneously. Value is the determination of the relative importance of each.

Conclusion
The question to be asked is this: What do refractory linings do? Their most basic function is to withstand very high temperatures; contain heat within a vessel; have adequate physical properties, such as strength; and resist chemical degradation or disintegration by aggressive atmospheres and corrosion by liquid slags and solids.

Choosing the right material solution for thermal-processing applications requires balancing multiple aspects to determine a hierarchy of which aspect is most important. In many cases, there is no one single answer to the problem. However, understanding the process, challenges, history and root causes of refractory failures becomes the key to making the best decision to solve the problem.

Tech Team · Kintek Solution

Updated 7 months ago

How to choose the right refractory materials? Optimize Efficiency and Durability for High-Temperature Processes

Refractory materials are essential in high-temperature industrial processes, and their selection depends on specific requirements such as thermal conductivity, corrosion resistance, thermal shock resistance, ease of installation, and maintenance. The choice of refractory material is also influenced by the specific process and environment, such as the type of kiln or furnace, the materials being processed, and the desired energy efficiency. For example, low-iron alumina or magnesium-spinel bricks are used in iron ore reduction kilns, while magnesite bricks are preferred in cement kilns. Additionally, crucibles require extremely high-temperature resistance, chemical stability, and compatibility with the materials they contain to prevent contamination. Multi-layer insulation designs, such as those using lightweight alumina ceramic fiber and insulation boards, are also critical for reducing heat loss and energy consumption.

Key Points Explained:

1. Low Thermal Conductivity:

   • Refractory materials must have low thermal conductivity to minimize heat loss and improve energy efficiency. This is particularly important in high-temperature environments like kilns and furnaces, where maintaining consistent temperatures is crucial. For example, multi-layer insulation designs using lightweight alumina ceramic fiber and insulation boards are effective in reducing heat loss.

2. Resistance to Corrosion:

   • Refractories must withstand chemical reactions with the materials they come into contact with, such as molten metals or slag. This is especially critical in processes like iron ore reduction or cement production, where the materials can be highly corrosive. Low-iron alumina or magnesium-spinel bricks are often used in such environments due to their chemical stability.

3. Thermal Shock Resistance:

   • Refractory materials must endure rapid temperature changes without cracking or degrading. Thermal shock resistance is vital in processes where temperatures fluctuate significantly, such as in furnaces or kilns. Materials like magnesite bricks are commonly used in cement kilns because of their ability to withstand thermal stress.

4. Ease of Installation and Maintenance:

   • Refractory linings should be easy to install and maintain to reduce downtime and operational costs. This includes considerations like modular designs or pre-fabricated components that can be quickly replaced or repaired. A stable refractory lining that is easy to maintain ensures long-term reliability and cost-effectiveness.

5. Material-Specific Requirements:

   • The choice of refractory material depends on the specific process and environment. For example:
     • In iron ore reduction kilns, low-iron alumina or magnesium-spinel bricks are used due to their resistance to high temperatures and corrosive materials.
     • In cement kilns, magnesite bricks are preferred for their thermal shock resistance and durability.
     • Crucibles require materials with extremely high-temperature resistance and chemical compatibility to prevent contamination of the melts.

6. Insulation Design:

   • Multi-layer insulation designs, such as those incorporating lightweight alumina ceramic fiber and high-quality insulation boards, are essential for reducing heat loss and energy consumption. These designs also ensure that the refractory material does not contain harmful components like asbestos, making them safer and more environmentally friendly.

7. Chemical and Physical Stability:

   • Refractory materials must maintain their structural integrity and chemical composition under extreme conditions. For example, crucibles must have a melting point higher than the materials they contain and be chemically compatible to avoid reactions that could lead to deterioration or contamination.

By considering these key points, purchasers can select refractory materials that meet the specific needs of their industrial processes, ensuring efficiency, durability, and cost-effectiveness.

Summary Table:

Key Factor Importance Example Materials Low Thermal Conductivity Minimizes heat loss, improves energy efficiency Lightweight alumina ceramic fiber, insulation boards Resistance to Corrosion Withstands chemical reactions with molten metals or slag Low-iron alumina, magnesium-spinel bricks Thermal Shock Resistance Endures rapid temperature changes without cracking Magnesite bricks Ease of Installation Reduces downtime and operational costs Modular designs, pre-fabricated components Material-Specific Needs Tailored to the process (e.g., iron ore reduction, cement production) Low-iron alumina for iron ore kilns, magnesite bricks for cement kilns Insulation Design Reduces heat loss, improves energy efficiency Multi-layer insulation with alumina ceramic fiber Chemical Stability Prevents contamination and maintains structural integrity Crucibles with high-temperature resistance and chemical compatibility

Need help selecting the perfect refractory materials for your application? Contact our experts today for tailored solutions!

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