Fine iron and iron-bearing minerals cause visual and
structural defects in ceramic tableware.
Such contamination appears as small dark spots on the surface or is
hidden within the body and causes premature cracking of the ceramic. The cup, saucer or plate is then either
rejected or reworked.
The problem of iron contamination is not new. The mix of minerals used to produce ceramics often include iron-bearing minerals (e.g. hematite and biotite mica). In the past, flaws such as iron spotting or discolouration, were masked by adding patterns and decals to the tableware. However, in more recent times, the high demand for plain white tableware means that any defect due to iron contamination is easily visible. Subsequently, reject and rework rates are high, which are costly in terms of time, production and wasted materials.
Iron-contamination problems are solvable thereby improving
the cost effectiveness of manufacture.
Many ceramic tableware manufacturers use a combination of different
designs of magnetic separators located at key points within the production
process. The magnetic separators attract
and remove any magnetic particle before the ceramic is fired.
In this blog, we review a typical ceramic tableware plant and
identify locations and magnetic separator designs to successfully remove iron
from the process.
Raw materials such as feldspar, zircon sand, silica sand,
calcium carbonate and various clays are commonly delivered by road on a
truck. Although many raw material
suppliers use magnetic separators and metal detectors to remove and detect
metal, larger tramp metal contamination is often picked up in the truck, or
during loading and discharge. A
combination of a permanent Overband Magnet (Model PCB) and Metal Detector
(Model TN77) on the main conveyor feeding the raw material storage silos
ensures that all larger tramp metal, ferrous and non-ferrous (e.g. digger
teeth, larger bolts and screws), is removed or detected. This prevents larger metal entering the
process, where it would seriously damage processing equipment, such as screens
and mills. Also, if the larger metal is
not removed, it enters the process and gets broken down into a significantly
large number of smaller particles, which spread throughout the raw material mix
and are far more difficult to remove.
Removing fine iron and magnetic minerals reduces the risk of structural and surface defects in the tableware post-firing. When iron is exposed to high temperatures, the particles react compromising the structural integrity of the ceramic. Surface defects are also an issue, even though the un-fired tableware is coated in glaze. Iron particles can cause uneven surfaces and discolouration and, when large in size, can break through the thin glaze coating.
There are several key locations for magnetic separators in
the ceramic body preparation process.
The dry raw materials are fed in designated proportions into
a mixer. Potentially within the mix is
smaller tramp magnetic metal such as washers, nails, rust, pipe-scale etc. At this point there are two recommended
magnetic separators, depending on the specific installation:
The best location for removing fine iron and magnetic minerals is after the non-metallic minerals are mixed into a slurry state (the ceramic ‘body’). Due to the high volume of material, a larger and higher-intensity magnetic separator is recommended.
The Electro Magnetic Filter is an
automatic self-cleaning magnetic separation system that is able to handle large
throughputs. The Electro Magnetic Filter
generates far higher magnetic fields than permanent magnets, increasing the
efficiency of separating fine iron and weakly magnetic minerals. Additionally, the self-cleaning operation
ensures that the maximum separation of magnetics is maintained at all times. A typical cleaning cycle would be every
twenty minutes depending on the level of ferrous contamination in the feed.
This is often the final opportunity
to capture and remove the magnetic contamination prior to the body moving onto
the filter press.
In some ceramic tableware plants, the body is dried into
uniformly-sized small grains using a spray drier. Spray drying is a method of producing a dry
powder from a liquid or slurry by rapidly drying with a hot gas. Very often fine iron is introduced into the
process by the drier via the hot air supply resulting in contamination
including iron sticking to some of the spray dried particles.
High-intensity permanent magnetic separators, such as the
Rare Earth Roll Separator and the Rare Earth Drum Magnet, automatically and
continuously removing any free iron and iron-contaminated spray dried particles.
After filter pressing, some plants produce a slip. To ensure that the slip is iron-free after
dosing, blunging and slip casting, a Liquid Pipeline Separator, designed with
strong permanent Tube Magnets, is installed into the pipe. The Tube Magnets capture any introduced tramp
iron. This is the final safety check
point prior to forming as a biscuit and firing.
The Glaze provides the perfect finish to any tableware, but
can be compromised if contaminated with even the smallest specks of iron. During the firing process, the iron will
react with the heat, causing spotting or discolouration of the glaze. Therefore, it is critical that the Glaze is
iron-free.
The Glaze colour depends on the tableware design, but is
commonly white. Care is needed when
passing coloured Glaze through any magnetic separator as the pigments can have
magnetic properties.
The Glaze raw materials are delivered in the same way as
those for the Body, and stored in designated silos. As with Body, after proportioning, the dry
raw material mix passes through a permanent magnetic separator such as a Bullet
Magnet or Drawer Magnet (both with high strength rare earth magnets) as they
are fed into the mixer.
The critical point for high-intensity separation of fine iron
and magnetic minerals is after the non-metallic raw materials are mixed into a
wet state to form the glaze. Commonly,
there will be a Glaze preparation area where different types and colours of
Glazes are made and stored.
As with the Body, the optimum iron-separation system is the
high-intensity Electro Magnetic Filter.
Commonly, for Glaze operations, this operates on a batch-fed basis
treating one container of Glaze at a time.
Many Electro Magnetic Filters are mounted on moveable wheeled frames for
easy re-positioning within a designated area, or even next to the Glazing Line. It is important to consider the consistency
of the Glaze as this may affect the flowability, especially if containing a
gluing agent.
The Electro Magnetic Filter removes fine iron and weakly
magnetic minerals, reducing the risk of surface contamination and product
rejects.
The Glaze is often transported in Glaze carts to Glazing Stations. At the station, high-strength Tube Magnets are positioned either inside a type of Liquid Pipeline Magnetic Separator or stand-alone in a design configured by the customer. Glaze will run across the surface of the Tube Magnets to remove any fine iron before being either poured or sprayed onto to tableware biscuit. Such protection provides a vital final stage protection against iron contamination prior to final firing.
Understanding the ceramic manufacturing process is important when making recommendations for the optimum magnetic separation equipment. The magnetic separators mentioned in this review are used successfully in ceramic production operations. However, each manufacturing process is unique and a visit by a local Bunting Sales Engineer will help understand a specific process and iron contamination issue and propose a specific solution.
For additional information on eradicating iron contamination blemishes in ceramic tableware, tiles, or sanitaryware, please contact us on:
Email: Gordon Kerr at GKerr@buntingmagnetics.com
Telephone: +44 (0) 1527 65858
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