Causes of Large bubbles

 Let’s think about moisture and large bubbles from under the glass. It is not the water, but the gasses created by the decomposition of materials that can cause the bubbles. There are other causes of large bubbles too. The most common causes are discussed here.

The usual explanations are:

• ·        Uneven shelf
• ·        Heat resistant particles under the glass
• ·        Uneven heating
• ·        Glues
• ·        Organic material
• ·        Moisture
• ·        Amount of gas

 

image credit: Warm Glass

Uneven shelf

Shallow depressions in shelves can cause large bubbles. Occasionally, the shelf can be damaged in various ways causing scratches or dings in the shelf. Air can be trapped in these depressions. And it does not take much volume of trapped to be a problem. The heat of kilnforming causes the air to expand. As the glass becomes less viscous with increased temperature, the pressure from the expanding air forces the glass upwards. The amount of air and the amount of heat work combine to create bubbles from simple uprisings to large thin walled or even burst bubbles.

There are some things that can be done to detect and avoid bubbles from forming. It is possible to screed powdered kiln wash over kiln washed shelf. This gives pathways for the air to escape. It does leave a more marked bottom surface than kiln wash.

Using 1mm or 2mm fibre paper allows air from under glass. You can maintain a relatively smooth surface with Papyros or Thinfire over the fibre. Even Thinfire or Papyros on its own will allow air from under the glass.

Checking for depressions can be done by spreading kiln wash powder over shelf and drawing a straight edge over the shelf. Depressions will be shown by the presence of the powder. It can also be done with powdered glass frit.

Particles under glass

Any particle resistant to kilnforming temperatures holds the glass up while it is forming so creating an air space. It is important to ensure the shelf is clean as well as flat. Small pieces of grit or dirt that are resistant to high temperatures will hold the glass up from the shelf enough to create a bubble – small or large depending on the temperature. Vacuuming the shelf before adding anything to the surface before each firing is important to bubble free results.

Uneven heating

This is sometimes cited as a cause of bubbles. If so, the heat would need to be very localised. This is possible if the glass is very near elements. In general, the temperature is equalised at a distance equal to the width of the elements.

Glues

A wide variety of glues are used in kilnforming. Those available to enthusiasts all burn away leaving gasses between layers. These gasses - if trapped - can thin the glass below as well as above the glue’s position. This will give the impression that the bubble has come from between the shelf and the glass. Most often the bubble forms between the glass layers, pushing a bubble only into or through the top layer. The solution is to avoid using glue or minimise it and place it only at the edges.

Organic material

Organic materials can be a problem. When you are using a large or thick fibre paper sheet under a piece of glass, occasionally the gasses from burning out of the binder can be great enough to create a bubble. Although normally, this only leaves a grey to black mark on the underside of the glass. Vermiculite boards need to be fired before use, as they contain significant amounts of binder.

Inclusion of organic materials such as leaves, twigs, or bones, leads to bubbles. Very long soaks below the softening point of the glass are required to allow the organic material to burn out of the objects.  The time required increases from an hour for leaves to 24 for bones.

Moisture

Moisture is very often cited as the source of bubbles. It is possible that the steam from water may be trapped in shelf depressions, or the areas held up from the shelf. And anytime there are no precautions to allow the air from under the glass, or between sheets bubble formation can be promoted. If adequate precautions are taken (flat shelf, clean shelf, bubble squeeze) the moisture will evaporate before the glass is hot enough to form a seal around the edges and trap any steam. It is another good reason for moderate ramp rates at the beginning of a firing.

Amount of gasses

Of course, if there is a lot of moisture there can be problems. Simply applying kiln wash in four coats does not leave enough water in the shelf to be a problem.

If you have washed the kiln wash off a mullite shelf, there will be a lot of water in it even after it feels dry. Then it does need to be kiln dried before use. To avoid breaking the shelf you need to fire slowly to 99°C/210°F and soak there for a couple of hours with the vents open or lid propped up a little to allow the moisture out of the kiln.

 

 

Metal inclusions

Two difficulties with metal inclusions in glass are common: stress and bubbles.

Stress

Metal inclusions always create stress in the glass. Different metals have different expansions and different strengths.  They also have different melting points - some so low that they liquify during the fusing process.

The trick in using metals as inclusions is to minimise the amount of stress. Small amounts of stress can be contained within the glass. The thicker or more mass inside the glass, the greater risk of stress breaks. The stronger or more rigid the metal is, the more stress will be generated.

Minimising stress is most easily achieved by using small amounts of the metal.  Thinning the metal as much as possible also reduces stress.  Flattening wire also helps reduce the amount of stress as well as keeping it in the place you want it without rolling away from its placement.

Bubbles

Bubbles often form around inclusions, especially of metals.  Metals that do not melt at fusing temperatures are stiffer than the surrounding glass.  You can see from the table noted above those metals which melt at higher temperatures than fusing.  These metals will create bubbles around their perimeter and elsewhere over the metal wherever there are wrinkles or undulations as the metal holds air in those places.

Thin metals

One possibility to reduce the bubbles is to thin the metal by hammering flat or use foil thicknesses of the metal.  Many specialist metal suppliers have very thin metals, often called shims.  They are increasingly available in online shops.

Weight

Another is to use enough glass on top to flatten the metal.  You should flatten the metal in the cold state as much as you can.  Then the weight of the glass presses down on the metal both in the cold and heated states. With a good long bubble squeeze, you can force more air out to the sides than with less covering glass.

Placing

A third possibility is placement. The further the metal inclusion is from the edges the more air is likely to be trapped to form bubbles.  If the air has less distance to travel, more is likely to escape.

Pressing

Supporting the edges or corners allows the centre to drop before the edges are sealed.  The weight of glass helps to press the air out to the sides.  Thicker glass (6mm/0.25") on top of the metal inclusion can help push the air away from the metal. You can also provide - within the design - paths for the air to escape. This can be elements such as powder, stringers and other glass accessories that can hold the glass up during the bubble squeeze process, but become invisible at fusing temperatures.

Fire in stages

A fifth possibility is to fire differently.  You can place the metal on a kiln shelf which is covered with fibre paper and put the glass on top of the metal and fire to a rounded tack fuse at the minimum.  To avoid dog-boning, you should cut the capping piece several centimetres larger than the final piece, so you can cut off the distorted edges. Clean the bottom and dry very well after firing and put the base under the top piece that has the metal attached.  Fire the combined piece slowly with a good bubble squeeze.  This can be applied to included vegetable matter too. 

Further information is available in the ebook Low Temperature Kiln Forming.

Inclusions often produce stress and bubbles.  There are some things that can reduce both when encasing metals or vegetation.

Firing Practices that Affect Kiln Elements

The way that you fire glass and other materials in your kiln affect the longevity of the kiln elements.  Some things you can do and avoid are given here.

Venting

Even if you have the best aluminium oxide coating, the fumes that emit from glazes, paints, organics, inclusions and devitrification solutions can still attack the element through cracks in the coating. Downdraft vents are your best defence against potentially harmful fumes. Downdraft vents pull the fumes from the kiln chamber before they have a chance to damage the elements.

If you do not have a downdraft vent your next best option is to prop the lid a couple of inches until the kiln reaches 540°C to allow the fumes out of the chamber. You should also consider leaving at least one peephole out during the entire firing for the fumes that escape above 540°C.

This presents a dilemma, as the recommendation is to keep the kiln closed from 540°C upwards to protect the glass from cold air drafts.   Those who rarely fire above 800°C do not have the same problem as those who regularly fire at 850°C and above for casting, combing, and melts.  The higher the temperature, the greater the effect of fumes on the elements.  At fusing and below temperatures the effect on the elements is not as great.  Thus, low temperature firings can follow the standard practice of closing the kiln above 540°C.  Those going higher, should consider venting the kiln all the way to the top temperature to reduce the wear on the elements.

Maintain an Oxidising Atmosphere

Elements need an oxidising atmosphere to provide a long dependable service.  Subjecting elements to reducing atmospheres will age the elements quickly.  This is be done by introducing organics or oils into the kiln without venting.  Among the things that will attack the aluminium oxide coating of the elements are

• ·        Carbon - this includes materials made from carbon and plant-based inclusions.   
• ·        wax burnout – it is best to steam wax out of moulds to eliminate most of the wax before any burnout, as the fumes are largely carbon.
• ·        halogens (such as chlorine or fluorine) 
• ·        molten metals (such as zinc, aluminium).  This is a more important reason for avoiding the use of zinc and aluminium in kilnforming than the possibility of health problems.
• ·        lead bearing paints and glazes – lead is a common component of paints, enamels and glazes.
• ·        alkaline metals – the main one we come across in kilnforming is magnesium which produces an amethyst colour of varying intensities.  This has a melting point of 650°C and boils at 1090°C, so some fumes can develop during firings and affect the elements.
• ·        borax compounds – used in enamel glazes and some devitrification sprays. 

If you use these materials in the kiln, you need to ensure that the kiln is well vented while these are in the kiln.

When you do have to use these elements - even when you vent - it is good practice to follow this firing by one without materials corrosive to the coating.  This allows the coating to re-form around the element surfaces after a corrosive firing.

Trying to do reduction firings in your kiln will greatly limit their useful life and is definitely not recommended.

Avoid Contaminants

Contaminants such as silica which is contained in kiln wash and some glazes attack the aluminium oxide coating of the wire.

Powders, paints and kiln wash accidentally touching the elements cause rapid corrosion of the elements if not cleaned off before firing.

Placing

Firing close to the elements allows any fumes from materials being used to affect the elements more than allowing some space between the glass and the elements.  This provides another reason to keep the glass away from the edges of the kiln in addition to the possible uneven heating of the glass.

High Temperature Firings

High temperatures with very long soak times will accelerate an increase in element resistance through the differential expansion of the inner wire and the coating. The higher the temperature, the longer the soak, the sooner the element will decrease in life. Usually short soaks work much better for the longevity of the element.  This is not such a big factor for glass kilns as it is for ceramic kilns.

The next part in this series deals with the maintenance of the elements.


Earlier relevant posts
Element Description

Aging