Wednesday 17 April 2019

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

Wednesday 10 April 2019

Kiln Elements - Aging



As elements age, they generally increase in their resistance. This increase in resistance decreases the amount of amperage and, so, the amount of heat given off by the elements. This explains  why older kilns sometimes go so slowly and may not reach their maximum temperature.

There are several factors which affect the longevity of elements and so have implications for firing practices.
  • ·        Contaminants such as silica which is contained in kiln wash and some glazes attack the aluminium oxide coating of the wire.
  • ·        Allowing the wires to become tightly wound increases overheating of sections of the element.
  • ·        Powders, paints and kiln wash accidentally touching the elements cause rapid corrosion of the elements if not cleaned off before firing.
  • ·        Firing close to the elements allows fumes to contact the elements.
  • ·        Subjecting elements to reducing atmospheres will age the elements quickly.  This would 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, wax, halogens (such as chlorine or fluorine), molten metals (such as zinc, aluminium), lead glazes, alkaline metals, borax compounds.


All these elements attack the element coating.  And each time you fire the slight difference in expansion between the core of the wire and the coating creates cracks in the coating.  The exposed core forms new coating to fill the gaps.  This over time reduces the thickness of the element wire.  As the wire thins, the resistances increases, causing more fissures in the coating to occur, accelerating the aging process.

The next in this series is about how firing practices can affect the life of elements.
Firing Practices

Other relevant posts:
Nature of elements
Maintenance

Friday 5 April 2019

Kiln Elements




Questions arise on whether old elements can become inefficient or hold a “memory” of previous firings. Old elements increase in resistance so decreasing amperage and consequently reducing the temperature that can be achieved or speed with which the kiln can reach the top temperature required. It not a "memory" of heat or temperature.

This series of blog posts will look at the nature of elements, their aging, effects of firing practices, and maintenance of the elements.

Nature of elements

A kiln element is a wire designed to have considerable resistance to electricity passing along it so creating heat.  The measurement of the amount of resistance is in units named ohms.

Most electric kiln elements are made of Kanthal A-1, a trade name of Sandvik.  This is an alloy of iron, chrome and aluminium. During the first firings the wire develops an aluminium oxide layer on its surface.  This helps protect the rest of the substance of the wire from further corrosion.

It is critical to the life of the elements to develop this aluminium oxide coating and is the reason people are told to fire their kiln clean and empty.  Any contaminants, including dust can inhibit the formation of the protective oxide locally.

The new kiln elements begin to achieve their protective coating when they reach 1000°C.  The kiln does not have to reach that temperature, just the element.  But it is advisable to fire toward 950°C at a moderate rate of about 250°C per hour and soak there for half an hour to ensure the coating is firmly in place. Your kiln may never be fired as hot again, but you will be sure the elements are properly prepared.

It is important to remember that the elements are flexible when heated initially, but after a few firings become stiff and brittle.  After the initial firings, you need to ensure the elements are still well seated in their groves.

A well-designed kiln will have the largest diameter element wire and the largest distance between the coils (runs cooler). The thicker the elements, the greater the stability and the longer the life.  When elements get above 925C they become very soft.  As they soften, the coils begin to collapse, causing the distance between the coil turns to lessen. When the distance between coil turns is small the element will overheat in those areas.
The next in this series is about the aging of elements.
Aging of elements
Firing Practices
maintenance

Wednesday 3 April 2019

Slumping Breaks

“Why does my full fused disc break when I slump it?”

There are several possibilities. The two main ones are annealing and ramp speeds.

Inadequate annealing in the fusing stage can lead to a very fragile piece when being re-heated.  If there is significant residual stress in the fused piece, it is much more sensitive to heat changes during subsequent firings whether full, tack, or slumping/draping. It is important to thoroughly anneal any piece at every firing.  If you are firing a different layup or contrasting colours and styles, you should check for stress using polarising filters.  

The slump – or drape – firing needs to be much slower in temperature rise than the fuse firing.  You now have a thicker piece which takes longer to absorb the heat evenly. 

If your piece is tack fused, it needs an even more slow rate of advance.  Sometimes this needs to be as though the piece were two to four times the actual thickness of the piece.  The more angular and pointed the tack fused elements, the greater the reduction in firing speed.  This post gives guidance on how the piece is designed and its thickness affects the rates and soaks in tack fusing. 

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


Wednesday 27 March 2019

Observation

The importance of Observation (and recording)


Observing what you, or the kiln, is doing whether you are using a cartoon, or a schedule obtained from elsewhere – including the kiln manufacturer – means that you will learn much more quickly as you progress.  You will be able to alter things as you go.  This applies to all stages of the piece from design to removing the piece from the kiln.

The Design

Once you have made your design – whether as a drawing or a mock-up – look at it.  Really look at it.  Look at it from a distance, climb a ladder if you can’t pin it on a wall and look down on it.  Look at it from the sides so you have an oblique angle view.  Turn it upside down to confuse your expectations and so see what is really there.  Look at it, using a mirror to see if it still looks good. Make the alterations you need as you go along to get the look you want and then repeat the process until you are happy.

Assembly

Observe how you have put the piece together.  Do the pieces fit?
Is everything in the right place? Are the colours right? Does it match your vision – symmetrical or asymmetrical?   Do these things as you progress, so you become aware of the process and its rhythm.

Firing

Once you have determined your schedule, you cannot just leave the piece. If you are new to fusing, you need to observe the stages of firings to begin to understand what is happening to the glass at various temperatures and rates of advance. You would not put a cake into the oven and leave it without checking on it from time to time. Why would you fail to observe a much more expensive process?

Even when you are experienced  - observation of new layups, new processes and anything you haven’t done several times before - you need to know how things are progressing during the firing.

Observing a firing is relatively simple.  You need to check on two things:

·   Check for a too rapid rate of advance.  Peek into the kiln at around 540C to see if the piece is still whole.  If not, you can abort the firing and progress to fixing or move on to another project.

·   Check to see when the desired shape has been achieved.  Peeking to see if the slump is complete or needs more time is important to getting the shape right.  Peek to determine if the tack fuse has been achieved.  When it has, advance to the next segment to avoid over firing.  If it hasn’t, add time to the schedule to get it right.

Recording

It is not enough to simply observe.  You need to record what you intended and the results you achieved.  That includes what you did to get things right as well as wrong.  What did you do to correct elements?  These are all things that you will need to refer to in the future.

The key to rapid learning is observation and recording what you see.

Wednesday 20 March 2019

Kiln wash


When considering how many layers of kiln wash to put on shelves, especially in melts, combing and other high temperature operations, you need to remember what the kiln wash is doing – what its purpose is. 

Kiln and batt wash, shelf and mould primer are all different terms for the same thing – a separator between the glass and the kiln furniture or mould.  The amount needed is enough to completely cover the shelf. This is usually 4 coats - one top to bottom, one side to side, one each diagonal.  If you are spraying the kiln wash, use a coloured kiln wash to help ensure coverage. The shelf is adequately covered when the shelf is a uniform colour although a sense of the original remains while the kiln wash is wet.  Additional coats do not provide additional protection. The disadvantage of thick coatings of kiln wash is that the excess tends to stick to the glass as it is lifted from the shelf or mould.

This post gives guidance about the methods for application of kiln wash.



Wednesday 13 March 2019

Textured Side



There is a little concern about whether the textured side of the glass pieces in leaded and copper foiled glass should be towards the inside or outside.

The traditional advice is to have the textured side toward the inside.  This is based on the piece being used as a window. It is easier to keep the weather side clean if the smooth side is on the outside. The same thinking leads to the recommendation to allow the cemented panel to rest with the smooth (outside) down.  This minimises the thickness of the putty and so allows less water to collect on the outside horizontal leads.

If the window is not primary glazing, it does not matter which side, nor how consistent you are in placing the glass.  It becomes a matter of aesthetics – which ever way you prefer is fine if it gives you the effect you want.

There is a small visual effect if you are using transparent glass.  There is slightly more dispersion of light if the textured side is outwards. 

Placing the textured side inwards can be useful if you wish to indicate a rough surface contrasting with a smoother one.

These considerations show that the placing of the textured side is largely determined by the function of the panel and the aesthetics applied.

Wednesday 6 March 2019

Patina



The successful application of patina to solder or zinc depends on an understanding of what patina is, how it works and the methods of applying it.

What is it?

Definition:

Patina is a thin layer that variously forms on the surface of copper, bronze and similar metals (tarnish produced by oxidation or other chemical processes), or certain wooden furniture (a sheen produced by age, wear, and polishing), or any similar acquired change of a surface through age and exposure.
The chemical process by which a patina forms or is deliberately induced is called patination, and a work of art coated by a patina is said to be patinated.
The word "patina" comes from the Latin for "shallow dish". Figuratively, patina can refer to any fading, darkening or other signs of age, which are felt to be natural or unavoidable (or both).


A description of patination and the industrial process:

“In their natural state, most metals combine with chemicals in the earth or air to create metallic compounds that change their surface colour, which appear as rust or tarnish. These thin layers of corrosion are nature's patinas.”

“Among the most common procedures [to patinate] are immersion and spraying. During immersion, a piece is cleaned with sandblasting or chemicals, then dipped into a prepared liquid compound, creating an immediate change in colour. Alternatively, a piece is sprayed or brushed with a patina solution, allowed to air dry, and spritzed again. This oxidation process creates corrosion on the metal's surface that forms a layer of patina. Other methods include heat, dabbing and wiping, anodizing, and random contact patina.”

Source: Triple-S Chemical Products



A product – Black on Solder – is described and the industrial process illustrated:

“DESCRIPTION: Black on Solder is a chemical formula developed to achieve a black antique finish on Tin/Lead or Solder areas (60-40 or 50-50). This solution is a non-chromate, non-cyanide liquid solution widely used on lighting fixtures, tin wares, sculptures, gift items and other decorations. The surface will not chip, flake or peel.

“PREPARATION: Parts must be free of grease, alkalinity or acid when Black on Solder is applied. Parts must be thoroughly cleaned and deoxidized prior to blackening. … Do not use petroleum degreasing solvents that leave a residue on the surface. Rinse thoroughly with over flowing cold water to remove residual cleaners and dust. It is important that alkaline cleaners are completely rinsed off prior to blackening.

“IMPORTANT: Triple- S does NOT recommend using any sort of alcohol, solvent, acid or degreaser to clean parts prior to solution application. … Powdered cleaners such as Ajax or Comet can also be used. Use the cleaner in conjunction with a scotch brite pad and apply medium strength scrubbing to prepare the part then thoroughly rinse with fresh water. ….

“APPLICATION: Clean the part with [your chosen material]. Rinse thoroughly with water and dry. Apply [the patina] solution with a brush or spray evenly and let it react. Rinse with water and air dry or wipe with a cloth to dry the surface. [Repeat this as necessary.] It is recommended to protect the finish with a clear [varnish]”

Source: Triple-S Chemical Products

Take note:

The above quote is from a company that works with metals exclusively and is an illustration of how important cleaning is for good results in patina application.  When cleaning in proximity or on glass different processes must be used to protect the glass.

1. I never would use abrasive or corrosive materials to clean solder lines holding glass.  The most aggressive cleaner I use is that intended for fibreglass baths.
2. I never use abrasive methods in conjunction with painted glass.
3. Do not use metal or scouring pads when cleaning
4. I never use patina on any part of a panel that has painting on any of the glass. The acid will remove or damage the painting.
5. I never use patina on leaded panels at all.

I suggest these precautions should always be followed.

Cleaning
These sources indicate that a patina solution is used to form a thin layer of corrosion to the material.  To do this, the metal must be cleaned of oils, and be acidically neutral.  Cleaning is to be done with household cleaners such as powdered or cream cleaners applied with moderate pressure by synthetic scrubbing materials such as a dish scrubbing pad (sometimes called a green scrubby). The metal then needs application of running water (not a bath of water) to rinse off any residues. 

Application
The clean metal needs to be dried before application of the patination solution.  Apply with a brush or sponge, or spray and allow time for the patina to react with the metal.  Rinse with water and allow to air dry.  If wanted, the drying can be aided by wiping with a soft cloth or absorbent paper.  Often a second or third application is required to achieve the depth of colour desired.

Protect
You can then apply a varnish or wax to shine and protect the colour of the patination.  This protective process must not involve scrubbing, as that will remove the patination layer from the metal.


Do it Yourself Colourations

Goran Budija has listed a wide variety of patination formulas and methods in his publication.  What follows is a reworking of his data.

Patination of Tin

Black 1
Method:
Immerse objects in heated solution(70C). When colour is developed rinse well, dry and wax.
Formula:
5 gms Bismuth nitrate
50cc Nitric Acid
80gms Tartaric acid
1 litre water

Black 2
Method:
Immerse objects in the hot (70C) solution.
Formula:
30gms Ammonium chloride
7.5gms Molybdenum acid
1 litre water

Greyish black
Method:
Immerse objects in the room temperature solution.
Formula:
200gms Iron III chloride
1 litre water

Bronze brown
Method:
Dissolve ingredients in water acidified with nitric or hydrochloric acid. Apply to the surface(s).
Formula:
3 gms Ammonium chloride
12gms copper acetate
20ml vinegar
500ml water

Bronze colour.
Method:
Mix diluted solution of copper sulphate and cream of tartar, Rub it on an object.
Formula: equal parts of:
Copper sulphate
Potassium hydrogentartarate/cream of tartar



Patination of Zinc

Black. 1
Method:
Ingredients must be dissolved in hot water, then filtered and used.  Immerse objects and take them out immediately. Colour develops after contact with air.  Repeat if needed, rinse well and dry.
Formula:
125gms copper sulphate
60gms potassium chlorate
1 litre water

Black. 2
Method:
Immerse objects in heated solution (90 C).
Formula:
12gms copper sulphate
15gms potassium permanganate
1 litre water

Black. 3
Method:
Immerse objects in the solution. (room temperature)
Formula:
20gms ammonium molybdate
5gms sodium acetate or sodium thiosulphate
1 litre water

Greyish black.
Method:
Immerse objects in the solution (approximately 20 minutes).
Formula:
200gms Iron III chloride
1 Litre water
 
From:
Collection of formulas for the chemical, electrochemical and heat colouring of metals, the cyanide free immersion plating and electroplating, by Goran Budija.  March 2011.  Zagreb, Croatia


Summary of applicable DIY formulas and methods

Tin
Goran Budija recommends hot application to get a black patination, but this is not usually suitable for stained glass work.  Cold application will also work but needs more time and repeated applications to have the same effect as hot immersion.  Whether you choose Black 1 or 2 will depend largely on the availability of the chemicals.

A cold method of patination is the Greyish Black using iron III chloride, which is easily available. More applications and drying will intensify the colour.

To get a bronze patination of solder equal parts of copper sulphate and cream of tartar made into a paste and rubbed onto the solder will be effective, although not a copper colour.



Zinc
Black 1 seems the most useful method and formula for zinc framing of stained glass panels.  It is a cold application and immersion can be substituted by painting or brushing on the chemical solution.  Note the multiple applications required to get the depth of colour required, and the thorough cleaning and rinsing noted in the industrial process.

Wednesday 27 February 2019

High Fast Slumps




What are the possible effects of fast rises to a high temperature for a slump?

Some of the possible effects of fast rises to a relatively high temperature slump are these:

Uneven slumps can occur. 
·         This largely due to differential heating of thicker/thinner parts. 
·         It can also emphasise anything off level.
·         Any unevenness in the heat across the kiln can also be emphasised by the rapid rise in temperature.

Uneven slumps can be promoted by contrasting colours. Dark and light colours heat at different rates, leading to one area of the glass slumping before another.

A dark/light contrast can lead to stress fractures in fast firings.

In a fast firing the top heats faster than bottom leading to the possibility of splits on the bottom of the piece

The edges of the piece heat faster than centre, increasing the possibility of spikes at the edge.

Fast slumps require higher temperatures to achieve the slump.  This means there will be more marking of the bottom surface.  It often includes stretch marks especially at the rim.


The Alternative to Fast High Temperature Slumps

Slow and Low

Slow rises in temperature means the slumps can be done at lower temperatures. Lower temperatures usually mean more control and fewer marks from the mould.  It does mean that you will need to observe at intervals to get the soak time you need, but this is required for all variations in rates and layups, as well as new moulds.

Wednesday 20 February 2019

Combining Black and White



Black and white are at almost opposite ends of the viscosity spectrum in glass terms. Black is the runniest, and white is the stiffest. Black transmits heat more quickly to the lower layers than white.  White is the glass that absorbs and transmits heat most slowly.

an example from Pintrest


A lot of care is required when combining the two.


If the white is on top of black, the white shades the heat – more than other colours - from the black underneath, so a lot of stress can build up in the black.

You need to give a lot of time for the two to adjust to each other. A slower rate of advance than normal is advisable. A significantly longer soak at annealing temperature is required. The annealing cool needs to be much slower than for other glass of the same dimensions.  Consider slowing the rates to half your normal firing rates.  Also double your soak times.  After some experience you will be able to alter these cautious rates to those more suitable for you.

Wednesday 13 February 2019

Soak


Kilnformers seem keen to reinvent terminology and then wonder about imprecise language being used in the field. Much of the terminology for kilnforming is already available from ceramics. It makes sense to continue to use that terminology where it applies.

A soak at a stated temperature is the same as "hold" at the same temperature.

The concept of soak is more useful than the term “hold”.  “Soak” implies the temperature is held at temperature to allow the heat to soak into the glass. And that is the purpose of a hold.  Using the term “soak” brings this purpose into the thinking about scheduling.  It is related to the concept of heat work

Using the concept of heat work allows you to use a slow rise to a temperature for a short time to get the effect you want.  Or to rise to a temperature in the normal way but with a long soak.

This is how you can get a tack fuse at 750C with a long soak – say 30 mins - as at higher temperature for a shorter soak – say 780C for 5 minutes. This the concept of heat work in practice.

Further information is available in the e-book: Low Temperature Kilnforming.

Wednesday 6 February 2019

Lamination

Lamination in kiln forming is the adhering the glass pieces together without changing the shape of the glass.  On a laminated piece the edges of the glass will still be sharp but cannot be pulled apart.  Each manufacturer's glass will have slightly different lamination temperatures and it will be affected by the length of soak.

How do I find the lamination temperature?

Observe

Make your chosen layup in clear glass.

Peek at your glass at frequent intervals from 550C.  The rate of advance should be slow, say 150C or less. When it is observed the edges are just  beginning to round, you know you have the high-profile tack temperature for that rate of advance.

On another firing of the same setup and rate of advance, soak at 20C lower than the previous temperature for 60 mins. You need to keep peeking during the soak to ensure the edges remain sharp. 

When you see the edges begin to round, you need to advance to the cool and record the length of the soak used.  You will need to shorten that soak by the interval of your peeking.  If you were peeking every 10 minutes, reduce the length of the actual soak given by 10 minutes for the next firing.

These three firings will give you a schedule for laminating glass together for your chosen layup.  Other layups will require slight variations which will require observation to determine how much change from the original schedule is required.

Anneal and cool carefully

Do not forget to schedule the anneal soak and cool for at least twice longer than for a tack fuse each time.  This may make the soak four or more times longer than for a full fuse.

The reasons for the longer soak and slower cool are:
·         The glass pieces are not incorporated with each other. 
·         The pieces will react to cooling in different ways. 
·         Different colours have different viscosities and different contraction rates.
·         The shading effect of one piece on top of another is intensified. 
    There are right angles between the base and the stack of glass above.
T

All these factors make it important to ensure all the glass is at the same temperature (the anneal soak) and that the pieces, that make up the whole, cool at the same rate even when shaded.

Further information is available in the e-book: Low Temperature Kilnforming.