A closer look at one of the most common flaws that can affect both the performance and the appearance of ceramic glaze.

In this episode, we break down the key causes, explain how they arise, and share practical ways to prevent them.

For a deeper dive into the topic, check out episode #39.

What is rheology and what is it used for?

This episode answers exactly these questions. Without delving into complex details, it presents a few key concepts to help navigate topics such as viscosity, material behavior, and process control.

It’s a first step toward understanding the practical role of rheology in improving quality and production efficiency. In ten minutes.

Wettability is, in general terms, the property that describes a liquid's ability to adhere to a solid surface.

It can also be understood as the process through which effective contact is established between a liquid and a solid.

In some cases, solid surfaces exhibit low wettability—a characteristic that, while not inherently problematic, can lead to significant issues in the ceramic industry.

When raw ceramic bodies or suspended particles display poor wettability, production inefficiencies may arise, ultimately affecting the quality of the final product.

Wetting additives play a crucial role in creating the optimal conditions for achieving proper substrate wettability.

But how do they work, and in which applications are they most commonly used?

The electrical conductivity of water is a key parameter in industrial production processes, as it reflects the amount of dissolved ions that can directly impact the stability and efficiency of operations.

When conductivity levels go unchecked, they can compromise the quality of the final product, cause corrosion in equipment, or alter the reactivity of the materials used.

In this episode, we explore why continuous monitoring is essential and what strategies companies adopt to keep conductivity within optimal limits.

We discuss not only direct treatments like reverse osmosis and deionization, but also indirect approaches: the use of additives and rheological modifiers can help mitigate the negative effects of high conductivity, ensuring more stable processes and more reliable end products.Zs_lab, educational, Zschimmer&Schwarz, Tiles, Ceramco, Chemistry, Ceramics,

In this episode, we dive into the essential role of chemical additives used during the grinding phase of ceramic glazes—a crucial step that sets the stage for successful application on the glazing line. 

We focus on dispersants and binders, compounds that give the glaze the right balance of cohesion, stability, and flow. But there’s no one-size-fits-all solution here: the type of additive must be tailored to the specific application method, whether it's airless spraying, bell, or curtain coating.

A technical yet accessible look at how chemistry drives performance—right from the start.

Digital printing has transformed the ceramic industry, opening the door to highly sophisticated, versatile, and customizable designs.

At the core of this shift are ceramic digital printers—advanced machines that use inkjet technology to precisely apply both functional and decorative materials.

While the focus is often on inks and printing performance, there’s another category of fluids working quietly behind the scenes: maintenance fluids.

Though they don't directly impact the final aesthetic result, they play a vital role in keeping printers running smoothly and extending their lifespan.

In this episode, we explore three key types of maintenance fluids: cleaners, stand-by fluids, and model fluids—each essential for ensuring reliable and consistent digital printing performance.

In the world of ceramics, temporary binders play a crucial role in improving the cohesion and workability of slips.

These substances, often polymer-based, act on a chemical level by creating bonds between particles, increasing the mechanical strength of the mixture.

In this episode, we explore what they are, how they work, and why they are essential in modern ceramic processes.

This episode takes inspiration from the thesis work of the Head of Research at Zschimmer & Schwarz Ceramco. The goal is not to focus on the specific topic explored in that study (in this case, the well-known issue of the "black core"), but rather to highlight the research methodology and the meticulous, in-depth work that takes place every day in the laboratories of chemical companies serving the ceramic manufacturing industry.

Although it begins in an academic context, the process described closely mirrors the structured, methodical approach followed by laboratory professionals in real-world industrial settings.

In the ceramic field, a “top glaze” refers to the glaze applied as the final layer onto the unfired ceramic substrate. 

This glaze can serve multiple functions, but it primarily protects the underlying decoration and imparts specific technical and aesthetic properties to the surface.

This episode focuses on this particular class of glazes, taking a closer look at the key functions and rheological characteristics (among others) that the suspension must exhibit, depending on the chosen application method and the type of ceramic product being manufactured.

After more than fifty episodes exploring topics of general interest—always through the lens of chemistry and ceramic production—we’ve decided to have some fun.

We posed a few simple questions to artificial intelligence, asking it to write a short text about chemistry with complete freedom to choose the themes and highlights.

The result? Amusing, sometimes absurd—mostly accurate, but not always.

As we know, Large Language Models (the technology behind AI’s ability to understand and generate text) can produce content that sounds convincing and is often correct, yet it’s not immune to errors or even clichés. With so much information available online, inaccuracies are just a step away.

That’s why it’s essential to keep in mind that this is, above all, an experiment—and, let’s not forget, just a bit of fun!

Melting materials used in ceramics, often in glazes and digital glues, are capable of lowering the melting point of a material or compound, thus accelerating the sintering process.

This action, which occurs through the breaking of the molecular structure of the compound (in our case, silica) by certain ions, affects several factors and must be carefully calibrated each time to achieve the desired result.

Some of the areas influenced by this process include the grit application, the glossy or matte finish of the surface, interaction with colors, and energy savings.

How do these materials (such as sodium, potassium, zinc, calcium, boron, etc.) work within the suspensions they are added to, and how does this action reflect on the final ceramic material?

Industrial productivity is a top priority for any manufacturing enterprise, regardless of its field of operation.

The ceramic industry, too, must adhere to rules and parameters that enhance productivity while avoiding any form of waste.

However, process interruptions—representing the most extreme scenarios—can be triggered by numerous factors and can occur at various stages along the production line.

Even the digital printing process, including all the micro-processes that occur immediately before and after the printer, can be prone to issues that, in the most severe cases, lead to machine downtime.

This discussion explores some of the most representative critical scenarios related to the topic, providing an overview of preventive actions that can be implemented to mitigate such risks.

Water is one of the most widely used natural resources in numerous applications and across various sectors of industrial production.

For example, process water forms the basis of different production phases and ensures their proper development.

However, not all waters are the same.

Depending on its source, water can have very different properties, which may make it suitable or unsuitable for a specific process.

In general, water quality is often a necessary precondition.

For this reason, there are various processes capable of purifying water efficiently and, most importantly, safely.

One of the most widespread and commonly used methods is reverse osmosis.

Suspending agents belong to a broad category of additives whose primary purpose is to provide ceramic suspensions (slips, glazes, engobes, or frits) with good internal stability, counteracting potential sedimentation phenomena.

Available in both liquid and solid forms, these products act within the suspension to ensure the right balance.

There are various mechanisms that can be employed to properly maintain the solid phase of the mixture in suspension.

Among these, the most significant are about viscosity, electrostatic repulsion, and concentration (solid/liquid ratio).

This episode, after reviewing the properties of suspending agents, focuses on these three main tools, delving into the reasons and mechanisms behind each, also considering the application systems through which suspensions are deposited onto the ceramic substrate—a detail that can significantly influence the type of suspending agent to be used.

Complexing agents are capable of catching multivalent cations present in suspension to prevent them from negatively affecting the ceramic process. 

They are responsible for one of the main mechanisms underlying the deflocculation process: complexation.

Complexing agents (or chelating agents) are chemicals that bind to specific ions (such as calcium, magnesium, iron, etc.), forming stable complexes.

This property allows them to "sequester" metals, making them less reactive or preventing their precipitation in solutions.

These are simplified and very short descriptions of this particular category of additives. 

The episode takes a closer look at the mechanisms enacted by these substances within the ceramic production process, highlighting their functions, benefits, and sometimes, risks.

The topic of non-planar surfaces, which develop on multiple micro-levels and are sometimes improperly identified as 3D surfaces, plays a crucial role in giving ceramic surfaces not only a more natural appearance but also a broader and more extensive expressive potential.

This is not a new requirement: it took its first steps with the help of traditional technologies, but it has found new momentum with the arrival of the latest digital techniques.

The episode offers an overview of the main methodologies currently used to achieve textured surfaces, delving into the chemical mechanisms that occur on the surface and contribute to producing the desired effects.

In the previous episode (#45) we discussed the technical aspects of digital printing systems in relation to ceramic bricks.

This second part looks at the necessary preparatory work for the printing phase, going through the various steps involved in preparing a print file.

Regardless of the media on which you will work.

Some key words: standardized lighting, colorimeter, spectrophotometer, linearization, chart...

At present, in the heavy clay industry, products are decorated mainly by applying engobe with the aid of scattered granules or by means of reduction effects created by the firing process.

These techniques are suitable to produce traditional products for the existing market. 

What added value does digital printing offer in this field?

The operating temperature is an important parameter that ceramic producers must take into account in order to avoid application problems that can also negatively affect the quality of the finished product.

However, this parameter is not always easy to manage, especially if we consider the fluctuations promoted by seasonability.

The episode addresses the topic with the help of specific examples, highlighting the main scenarios and the different levers on which one can act to better manage the anomalies that may occur along the production lines.

Most ceramic production processes involve the dispersion of ceramic powders in a liquid medium - mostly water - to obtain a suspension or, more generally, a dispersed system.

To provde the suspensions with the desired stability and workability, depending on the different applications, we use the addition of small quantities of suitable chemicals that, interacting with the solid particles, change the rheological behaviour of the whole system.

The episode offers a picture of two categories of chemical - deflocculants and binders - almost always involved in order to achieve the right result and therefore the correct application performance.