In the glass industry, the performance of refractory materials, particularly fused-cast AZS blocks, depends directly on the control of thermal parameters during the casting process. Temperature variation, both in the molten material and in the mold—are responsible for many of the defects observed during on-site inspections and supplier audits: internal defects, stress zones, cracking, structural heterogeneities, and even significant reductions in furnace lifetime.
At MXS Refractory, we do not manufacture AZS blocks. Instead, we audit suppliers, analyze their processes, conduct refractory quality assessments, and support glass manufacturers in improving performance and securing the reliability of their refractory supply chain. Years of field experience allow us to identify both essential best practices and the most frequent weaknesses in thermal control during casting.
This article summarizes the key points of attention we regularly observe among AZS block manufacturers and the improvement levers we recommend.
1. Melt Temperature: A Critical Parameter Often Poorly Controlled
During our refractory audits at supplier facilities, one of the primary sources of quality variability is insufficient control of the electro-fused bath temperature. Poor thermal control is directly linked to the appearance of bubbles, inclusions, striations, or non-homogeneous zones.
1.1. Complete Melting and Homogenization
Proper melting and homogenization of the raw materials are fundamental to producing a high-performance AZS block.
However, we still frequently observe:
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temperature differences within the bath,
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composition gradients,
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insufficient homogenization of raw materials.
These issues increase the likelihood of internal heterogeneities and reduce the corrosion resistance of the block in the glass-contact zone.
1.2. Instrumentation Quality and Continuous Monitoring
One point we systematically highlight during audits is the quality of sensors and the actual frequency of measurements.
Many plants still rely on:
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sensors that are not regularly calibrated,
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outdated instruments,
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manual readings taken too infrequently.
We recommend the use of high-precision sensors with continuous data logging, which helps prevent thermal drifts that destabilize the melt.
1.3. Avoiding Overheating and Underheating
Overheating leads to:
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excessive bubble formation,
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increased volatilization,
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structural instability.
Underheating results in:
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insufficient fluidity,
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poor mold filling,
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defects such as layering or stratification during solidification.
A thermal window that is too wide is often a sign of a lack of procedural discipline, something we frequently identify in audits.
2. Mold Temperature: A Critical Element Often Underestimated by Manufacturers
MXS audits consistently reveal that mold temperature management is a major source of non-conformities.
2.1. Mold Preheating: A Step Rarely Standardized
We observe significant variations in practice between suppliers:
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Insufficient preheating → thermal shock, internal cracking.
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Excessive preheating → slow solidification, residual stress.
We recommend implementing written procedures based on the mold material, geometry, and melt temperature.
2.2. Cooling Rate Control
Solidification must proceed progressively and in a controlled manner to ensure the correct distribution of AZS phases. Cooling that is too rapid results in:
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internal stresses,
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microcracks,
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undesired crystallization.
We often encounter cooling systems that are poorly sized or overly dependent on the operator’s personal experience.
3. Global Process Control: A Core Focus of Our Supplier Audits
Beyond thermal management, the overall manufacturing process has a direct impact on the final quality of the refractory. During our missions, we systematically assess the following parameters.
3.1. Production Environment
Variations in ambient temperature, airflow, and humidity can all disturb block solidification.
We recommend:
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isolating critical areas,
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reducing unnecessary airflow,
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maintaining stable thermal conditions in casting rooms.
3.2. Operational Discipline
A recurring finding in our audits is the lack of process standardization.
In many plants, quality depends too heavily on operator experience, leading to batch-to-batch inconsistency.
We support our clients by:
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formalizing procedures,
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securing critical parameters,
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reducing human variability.
3.3. Equipment Maintenance and Calibration
A large portion of observed defects stems from equipment that is:
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poorly maintained,
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improperly calibrated,
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or nearing end-of-life.
We stress the importance of a preventive maintenance plan, including regular calibration of sensors and heating systems.
3.4. Raw Material Selection
Poor-quality raw materials cannot produce a high-performance AZS block.
During audits, we verify:
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alumina and zircon sourcing,
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certificates of analysis,
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storage conditions,
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consistency and repeatability of batch preparation.
Conclusion: Refractory Audits as a Performance Lever for the Glass Industry
Controlling casting temperatures is fundamental to ensuring the quality and reliability of fused-cast AZS blocks. The poor practices we still observe in some plants show that many suppliers must improve their processes to deliver stable, high-quality materials that meet the demands of modern glass manufacturing.
At MXS Refractory, our mission is to help industrial clients secure their refractory supply, optimize technical purchasing, evaluate the true quality of manufacturers, and support supplier development.
A comprehensive technical audit allows you to:
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detect procedural deviations,
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improve thermal management,
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reduce production defects,
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and ensure better refractory performance in operation.
If you want to strengthen your sourcing strategy, audit a supplier, or improve the quality of your AZS blocks, our technical team is ready to assist you.