Kiln Cleanliness

Problems with finished pieces can be caused by an untidy or dusty kiln interior.  Pieces can be affected by devitrification or specks of refractory material in or on the fired project.

Dust is a common problem.  Kiln wash, fibre papers and combustion products all produce particles that are collectively referred to as dust.

Vacuuming the kiln regularly is a good practice to keep the dust down.  It is best if the vacuum has a variable suction control to avoid damage to the refractory materials which make up the kiln.  It is best to use a brush attachment rather than the bare hose.

Dust on the brick or fibre board floor of kilns can be vacuumed easily if you remove the shelf.  Usually you need to use the most suction available to pick up heavier particles such as glass frit along with the dust that accumulates on the floor.

Dust also accumulates on the sides and top of the kiln too.  If you have brick sides and tops, you can continue to use the high suction.  You need to be careful around the elements so that you do not bump them.  This is where the brush attachment is most useful, as you can gently brush out any accumulated dust and any loose particles from the brick.

If you have fibre sides or top, the high suction setting on the vacuum will pull fibres from the refractory material.  You need to use a low setting to avoid damaging the insulating materials.  Gently pass the brush attachment along the insulating fibre and along the elements.

This vacuuming of the kiln does not need to be done on every firing, only at regular intervals.  It is also a good time to check the condition of the elements and condition of the interior of the kiln.  Any element tail connections can be checked for tightness.  The condition of the bricks can be checked as you vacuum. 

Of course, if you are going to fire an important piece, it is a good idea to make sure the kiln is clean before you start. But daily cleaning is not required.

It is not only the interior structure of the kiln that needs to be clean.  You should be checking the cleanliness of your kiln furniture too.  Make sure you keep the shelves dust free and regularly kiln wash them.  Check the kiln posts for flaking kiln wash and dust.  Clean off any dust or loose material and re-coat as necessary.  

And while you are doing all this cleaning, you could vacuum the outside of the kiln too.

First Kiln Selection

Glass fusing works best in top fired kilns.  Glass casting and some tall work are best with side or bottom elements too.  Compromises can be made of course.  The comparison of glass and ceramics kilns is important to understand.  

Kinds

Most of the following types of kilns are available for glass purposes.

Front loading.  These are good basic, multi-purpose kilns with good viewing properties.

Bell kiln.  This is where the whole of the heating chamber lifts up from the firing bed.  This is more common with very large kilns and is usually combined with lifting gear.

Clamshell kiln.  This is where the firing chamber is hinged, usually on the long side.  This kiln provides access from three sides. It can become too large to reach to the back of the kiln, so these tend to be rectangular.  The lid can also become too heavy for ease of movement and support.

Top loading.  Often called a coffin kiln, there are very good for casting or deep work, but are hard on your back while loading.  They need peep holes at appropriate levels to be able to monitor progress of the firing. These tend to have smaller floor areas than the clamshell.

Car kilns.  These are those where the firing chamber lifts like a bell kiln, but has the firing base on rails or tracks to move multiple firing bases under the firing chamber.

Modular kilns.  These are normally rounded kilns where each ring is controlled separately and can be placed on top of one another.  This is good for large heavy castings, as the refractory and glass reservoir can be placed on the base and the rings built up around the work.

All these kilns come in a variety of sizes.

Choose a kiln relevant to your current work.

The first thing you must decide is the kind and scale of work you intend to do in the near future.  It is too difficult to predict how your work might progress based on experiences with your current work.  It is better to by a smaller kiln that is ideal for the current work and then move to a different kiln, if necessary, or a kiln for different styles or scales of work.

The general advice is to buy as large a kiln as your budget and space and electrical installation will allow.  This remains the case with some precautions.  Think about how often you will fire - daily, a few times a week or a few times a month.   Think about how long it will take to fill the kiln.  A large kiln can take days or even a week to fill with small works. This would really limit the variety of things you could do in that period.  You would have to wait to slump until you had enough things fused to fill the space.  Indeed, you would need to have more moulds than if you had a smaller kiln.

I’m sure you can envisage a time when you will want to work larger than at present, but your first kiln will not become redundant.  It will continue to be useful throughout its long life.

Factors in the choice

Size. As already alluded, the size needs to fit with your current style and scale of work. 

Access.  How big a kiln can you get through the doorways?  How much bigger than actual external dimensions will the packaging make it upon delivery?  It is no use buying a kiln that must be taken apart, or all the packaging removed, to get it into your studio.  Of course, the wider the entrance(s) to your studio the easier it will be to get a larger kiln.  If you really need to have a large kiln, you might have to alter or move your studio space.  You also need to think about the kind of access to the studio.  Does the kiln have to come along the side of the house? Is the path paved or gravel? Stairs? Lift size? Parking for the delivery vehicle?

Space. The kiln also needs to fit into the space you have.  You will need about 15cm all around the outside dimensions for safety purposes.  This applies to ceramic kilns also, even though they routinely reach higher temperatures. The skin of the kiln does get hotter than is comfortable for your hand, but normally not hot enough to burn paper. You can reduce the front to back storage space by putting the kiln on wheels.  But the 15cm saved is not worth the time required to once again ensure that the kiln and shelves are level each time you move it. 

Accommodation also needs to consider access around the kiln to place work in the kiln, especially if you build elements in place on the shelf. 

Location within the studio is important, as the kiln needs to be near a power supply and in a place where it is away from the movement within the studio.

Power supply.  The nature of your power supply will also determine what size of kiln you should buy.  Note both the wattage and amperage required for the kiln and determine whether your household supply can cope with the energy requirements.  Usually a kiln can be run on household supply until it reaches the 1 metre² size, where three-phase power is required to have efficient use of the electricity.

Wattage. Kilns below the 1 metre² (approximately 1 square yard) in size have a need for at least 0.6 -1.2 watts per cm², or 4-8 watts per inch².  Once the kiln is larger, more power is required per area to accommodate the greater mass of the kiln.

Insulation.  All kilns require insulation.  This can be fibre or light weight brick, or a combination of the two.  These insulating bricks can be red hot internally, but only warm to the touch on the outside.  Generally, the refractory fibre – whether board or blanket – requires less energy to heat and cools more quickly in the critical devitrification range.  Most often the kiln floor will be made of brick to provide a firm base to support the kiln furniture.

Features

All kilns come with a range of features, many of them relevant to the size, but not all have the same ones, or the ones important to kiln forming.

Viewing ports.  These are variously called vents, ports, bung holes, etc.  Their importance is at least three-fold. 

·        These provide an opening(s) for you to view the progress of the firing, so you can add more time or heat, or skip to the next segment when adequate heat work has been completed earlier than expected.

·        They provide a means of venting the kiln.  This is important in the burn out of any fibre paper binders, and in allowing enough air to promote the oxidisation and maturation of the hot enamel colours.

·        These openings allow the kiln to safely cool more quickly at lower temperatures, say 300°C, but lower for thicker or more delicate pieces.

Opening.  The way the kiln opens is an important consideration.  Some kilns do not allow the kiln to be opened at all during firing.  This is not a desirable feature on a glass kiln.  It is important to have a switch that will turn the kiln off after a certain degree of opening, so that no contact can be made with a live element. 

·        A front opening kiln allows maximum flexibility to view the progress of slumps, drapes, tack and full fuse kilnforming.  It should have a switch to turn off the power to the elements after a certain degree of opening.

·        A top loading kiln allows you to add glass during a casting process, but is not suitable for working the glass during firings – E.g. combing, manipulation of a slump or drape.  This type of kiln occasionally has no allowance to open the top without turning off all the power to both the controller and the elements.  Avoid this, or have it changed.

·        A clamshell or bell kiln allows maximum accessibility during the loading phase and the forming stages.  Although a lot of heat is dumped forward, it is the easiest to use for combing and other manipulation of the glass during the firing. Again, this kiln needs a lid operated switch to cut the power to the elements when opened beyond a certain point.

Controller.  Although essential, controllers are often given as options, especially on smaller kilns.  There are at least two reasons for this.  There are a variety of controller styles and costs.  The buyer may already have their own controller, or wishes to specify the kind.  Controllers are significant costs involved in smaller kilns – sometimes being at least one-sixth of the price.  In general, the more features a controller has, the more it costs.

Controllers are often classified as “three-key”, or as full number pad.

·        The three-key controller – even if they have many more than three keys – is one where the numbers must be cycled through by holding an up or down arrow to change the numerical information.  This includes the programme number, segment number, time, rate, temperature, and sometimes other information. 

·        The full number pad controller will allow direct entry of numbers at each segment of the programming.  It will often have additional features, such as calculating the firing cost or kilowatts used, elapsed time, additional capacity for more saved programs, ability to control different areas of the kiln heating, etc.

Extras 

There are often things which will be worth considering purchase along with the kiln, but are not usually included in the base price.

Stands.  Smaller kilns range from table top - which do not need stands at all – through medium sized – which have optional stands – to larger ones that come with the stand integral to the whole kiln. Unless you intend to move your kiln about, it is not necessary to buy one of the metal stands. Even so, most of these stands come without wheels, so check that they do have wheels already attached.  If you will not be moving the kiln, you can use a wooden table with a refractory fibre board between the stub legs of the kiln and the table surface.  If the kiln does not have stub legs, you can set it on 4 house bricks. 

Kiln furniture. This consists of the refractory props and dams that will be needed in kilnforming.  The most essential are short (2.5cm) kiln posts to support the shelf.

Shelves.  Most shelves require a mullite/cordierite shelf to fire on.  This is a robust shelf that does not have the quartz/crystobalite inversions that ceramic shelves and tiles used for shelves have.  It is a good idea to buy one of these to fit your kiln at the time of purchase. Smaller kilns can use fibre board or vermiculite board as the shelf.  These can be purchased later.

Extractor fans.  These are available on many kilns. They are unnecessary on smaller kilns as they cool quickly anyway.  Larger kilns in a production environment may need quicker cooling, and these arrangements are very useful in those circumstances, but not others, as most kilns will cool in 8 – 16 hours without drawing air through the kiln.

There are a lot of other considerations in buying a kiln, but these are among the important ones, especially in selecting the first one.

Element Coatings

You will notice that after the initial few firings of your new kiln that a grey residue forms on the elements.  This is a protective layer.  It is a surface oxidisation that protects the underlying metal from further corrosion. 

Kiln elements are generally made from Kanthal or Nichrome wire. 

Kanthal wire is an alloy of iron, chrome and aluminium.  The aluminium oxidises to provide a protective layer of aluminium oxide.

Nichrome wire is an alloy of nickel (the main element) and chromium in various proportions for different applications. It is the most common heating element for high temperatures. The chrome forms a protective layer of chromium oxide at red hot temperatures.  But once heated, it becomes brittle, so it can be manipulated only when hot.

This layer is not a chemical reaction to the things you put into your kiln.  It is the necessary protective layer to give long life elements. This coating should not fall from the elements unless it is disturbed by bending, abrasion or impact. If it does, check for damage to the elements and look closely for any break.

Cooling the Kiln

“Why does my kiln take so long from boiling point to room temperature?”

The rate at which a kiln cools is dependent several factors:

• ·        The mass of the kiln. Some kilns have dense insulation bricks.  These are very good at holding heat, and release it slowly.
• ·        Its insulation characteristics. Other kilns have light weight bricks or fibre insulation. Both these materials have less mass and can release heat quickly at high temperatures, but much less slowly at lower temperatures.
• ·        The environment. The temperature of the surroundings has a big effect at lower temperatures.  The amount of air movement around the kiln also influences the cooling rate at these lower temperatures.

The physics of heat transfer determine the cooling rate. if all other factors are the same, the rate of temperature fall is faster when there is a greater temperature differential.  And it is slower where the temperatures are closer together.  You can see this by comparing the rates of fall at 800⁰C and at 300⁰C.  It is much faster at the higher temperature and slower at 300⁰C.  You will also notice that the kiln cools more slowly at the lower regions when the outside temperature is high than when low.

Rather than waiting hours or days for the kiln to get 

to room temperature, there are some things you can 

do.

·        Open any vents or peep holes your kiln has. Not only are peep holes good for observing the progress of the kiln work, they are important in cooling.  Their relatively small size insures that there is not such a great air exchange that could cause thermal shock.  The temperature at which you do this is relative to the thickness or variation in thickness of the pieces in the kiln, of course.

·        Open the kiln lid/door a little. As the temperature fall rate reduces, you can crack the kiln open a little.  Many times, you need to put a prop under the lid to keep it open only a little.  Again, this should only be done at a low enough temperature to avoid any thermal shock to the glass.

·        Create greater air movement around the kiln.  You can of course create greater air circulation around the kiln by opening doors and windows, or by a fan.  If you use a fan, it is best to avoid direct air current from the fan onto the kiln. This is because when the vents or lid are open, dust can be spread over the glass and throughout the studio.  If using a fan, it is best to have the kiln closed.  Some kilns have powered ventilation to speed cooling, but these are usually industrial.

How do I tell if I am cooling too fast?

The risk of opening your kiln after the end of the second part of the annealing cool (generally around 370⁰C) is thermal shock from the relatively cool air contacting the glass and cooling one part too much, causing a break or fracture.

You can select how fast a cool rate is safe for your piece and programme that into the controller down to room temperature.  Doing this does not use any more electricity than simply turning the kiln off.  The controller will only put more energy into the kiln if it is cooling more quickly than the rate you set. 

And this is the point of programming to room temperature.

When you vent your kiln, and have the controller set for a cooling rate, it will only add more heat if you have opened the kiln too much.  If you hear the controller switch on the elements, you know to reduce the size of the opening, because it is cooling faster than you set the rate to be.  This makes for a safe, but more rapid cooling than just letting the kiln cool with no ventilation.

"My controller shuts off when I open the kiln."

If your kiln does not allow any opening of the lid/door without the controller switching off, you need an alternative.  In this case, you will need to take note of the temperature drop over set periods to learn if the temperature is falling too fast or too slowly.  Usually 15-minute intervals are all that is required.  Record the temperature at the switch off and before venting the kiln. Vent the kiln. Fifteen minutes later record the temperature. Multiply the difference by four to get the hourly rate.  If that rate is above the one you intended, close the venting a little.  If it is less, open the venting a little more. Then record the temperature after another quarter of an hour. You continue to do this until you are satisfied you have settled on the rate of cooling you intended.

You must exercise patience with the cooling.  

The larger, thicker, more important the piece is, the more caution is required. 

Kanthal vs. Nichrome

Both Kanthal and Nichrome are high temperature wires.

Kanthal

Kanthal is the trademark (owned by Sandvik) for a range of iron-chromium-aluminium (FeCrAl) alloys used in resistance and high-temperature applications. The first Kanthal alloy was developed by Hans von Kantzow in Sweden.

“Kanthal alloys consist of mainly iron, chromium (20–30%) and aluminium (4–7.5 %). The alloys are known for their ability to withstand high temperatures and having intermediate electric resistance.”  So, it is often used in kiln elements.

“Kanthal forms a protective layer of aluminium oxide (alumina) when fired.”  This layer resists further oxidisation of the elements when firing.  Aluminium oxide is an electrical insulator with a relatively high thermal conductivity.  Ordinary Kanthal has a melting point of 1,500°C.

“Kanthal is used in heating elements due to its flexibility, durability and tensile strength.” Its uses are widespread, with it being used in home appliances and industrial applications as well as glass and ceramic kilns.  As an aside, it is being used in electronic cigarettes as a heating coil as it can withstand the temperatures needed in this application.

Based on Wikipedia https://en.wikipedia.org/wiki/Kanthal_(alloy) and other sources.

Nichrome

Nichrome is an alloy of various amount of nickel, chromium, and often iron.  The most common usage is as resistance wire.  It was patented in 1905.

“A common Nichrome alloy is 80% nickel and 20% chromium, by mass, but there are many other combinations of metals for various applications.”  Nichrome is silvery-grey, corrosion-resistant, and has a high melting point of about 1,400°C.

It has a low manufacturing cost, it is strong, has good ductility, resists oxidation and is stable at high temperatures.  Typically, nichrome is wound in coils to a certain electrical resistance, and when current is passed through it, the resistance produces heat.  This is probably the most common material used for kiln elements.

When heated to red hot temperatures, the nichrome wire develops an outer layer of chromium oxide, which is stable in air, being mostly impervious to oxygen.  This protects the heating element from further oxidation.  However, once heated the nichrome wire becomes brittle and must be heated to red hot before bending.

Based on Wikipedia https://en.wikipedia.org/wiki/Nichrome and other sources.

Broken Base Layers

Sometimes in fusing, the base layer can exhibit a crack or break without the upper layers being affected.  This kind of break almost always occurs on the heat up.  In a tack fuse, the top layers may still be horizontal and unaffected by the break beneath them.  If a full fuse, the upper layers will slump into the gap, or apparently seal a crack that is apparent on either side.

An example of tack fused elements on top of a previously fused base

Causes

This is more likely to be seen where there is a large difference between thicknesses.  If the base is a single or double layer and there are several layers of glass – especially opalescent – on top, there is a greater chance for this kind of break to occur.

The reason for this kind of break is that the upper layers insulate the part of the lower layers they are resting upon.  Glass is an insulator, and so a poor conductor of heat.  This means that the glass under the stack is cooler than the part(s) not covered.  A break occurs when the stress of this temperature differential is too great to be contained.

An example of  stacked glass in a tack fusing

This kind of break can also occur when there are strongly contrasting colours or glasses that absorb the heat of fusing at different rates.  One case would be where the dark lower layer(s) were insulated by a stack of white or pale opalescent glass.  The opalescent glass will absorb the heat more slowly than the dark base.  This increases the risk of too great a temperature differential in the base.

Reducing the risk of these breaks.

Even thicknesses

One way to reduce the risk of base layer breaks is to keep the glass nearly the same thickness over the whole of the piece.  Sometimes this will not give you the effect you wish to obtain.

Slow the firing rate

Another way is to slow down the temperature rise.  Some would add in soaks at intervals to allow the glass under the stack to catch up in temperature.  As we know from annealing, glass performs best when the temperature changes are gradual and steady.  Rapid or even moderate rates of advance with soaks, do not provide the steady input of heat.

This prompts the question of how fast the rate of advance should be, and to what temperature. 

Rate of advance

The rate of advance needs to take account of the thickness differential and the total thickness together.  A safe, but conservative, approach is to add the difference in thickness between the thinner and the thickest parts of the piece to the thickest.  Then program a rate of advance to accommodate that thickness.  E.g., a 6mm base with a 9mm stack has a total height of 15mm.  The difference is 9mm which added to 15mm means you want a rate of advance that will accommodate a 24mm piece.

The rate of advance can be estimated from the final annealing cool rate required for that thickness.  In the example above, the rate would be about 100°C per hour.  The more layers there are, the more you need to slow the heat up of the glass. The Bullseye table for Annealing Thick Slabs is the most useful guide here.

Firing already fused elements

If you were adding an already full fused piece of 9mm thick to a 6mm base, you could have a slightly more rapid heat up, bu not by a lot. This is because the heat will be transmitted more quickly through a single solid piece to the base glass.  It is safer to maintain the initial calculation. If your stack is tack fused, this will not apply, as the heat will move more slowly through the layers of the tack fusing much the same way as independent layers on the initial firing.

Conclusion

The general point is that you need to dramatically slow the speed of firing when you have stacked elements on a relatively thin base.  Even a two layer base can exhibit this kind of break when there is a lot of glass stacked on it.

Assessing Pre-programmed Schedules

Many kiln manufacturers are shipping their kilns with a set of programs already entered and saved into the controllers. 

You might think that all these pre-set schedules would all be the same, as the range of glass to be considered is relatively small. Yet, the range of schedules for the same glass varies from one manufacturer to another.  Yes, you may respond, but every kiln is different.  Well, I’d say, the variation is within a product line as much as between kiln manufacturers.

Assessing the installed schedules

What this means is that you need to assess the schedules that come with your kiln, rather than simply accepting what has been placed there.  There are a few things that can be looked at to assess whether you wish to rely on these pre-set schedules or not.

Differences between fast and slow fuses. 

• ·         What are the initial rates of advance, are they different?
• ·         Where is the bubble squeeze, is there one?
• ·         Are there different rates of advance from bubble squeeze to top temperature?
• ·         If you can compare their larger and smaller kilns, is there a difference in schedules?

Differences between tack and full fuses

• ·         Are the top temperatures different for tack and fuse?
• ·         Is there more than one tack fuse temperature to allow for various levels of tack from lamination to fully rounded?
• ·         Is there a difference in soak times at the target temperatures?

Differences in slump temperatures

• ·         Are there low and high temperature slumps?
• ·         Is there a difference in temperature or time between various slumps?
• ·         Is there any allowance for span or size of mould?
• ·         Does depth of the mould make any difference to the schedule?
• ·         Is a difference for the depth of the mould offered?

Differences for different manufacturers’ glasses

• ·         Are there different schedules for Spectrum, Wissmach, Bullseye, etc. fusing glasses?
• ·         Are float glass schedules any different for rates, soak times, annealing points?

Printed schedules

• ·         Are the schedules printed in the kiln handbook or manual?
• ·         Are you given clear instruction on when to alter the programs?
• ·         Are you given clear instruction on how to alter the programs?

The more “no” answers you get to these questions, the less you can rely on the installed schedules.

Fast Ramps - Kiln Forming Myths 26

Firing AFAP harms your kiln.

This may be a hangover from the time when ceramic kilns were being used commonly.  There certainly is a tradition of this kind in ceramics practice.  However, nowadays we are firing in kilns with light weight bricks or fibre, or a combination of the two, making this less relevant.

The light weight bricks are much less subject to temperature shock than the dense ones.  Fibre is completely unaffected by rapid changes in temperature.

Firing as fast as possible is much more likely to damage the glass you have in the kiln than the kiln itself.  It is also likely to have over runs in temperature.  The controllers compare the actual increase in temperature with that requested by the schedule.  It takes time for the controller to “learn” the rate of advance being achieved within the kiln.  On fast rises in temperature, it does not have the capacity to stop the input of energy early enough to prevent the kiln temperature rising beyond that which is programmed.  This can lead to unexpected and unexplained results (unless you think about the effects of an AFAP rate on the controller's computer).

Scheduling Relates to the Piece

My piece cracked, but I've always used this schedule and it has worked.

One schedule is not for all pieces. A number of factors affect the scheduling of a firing.  Some of them are:

Thickness

• The thicker the stack of glass, the slower the advance and anneal should be. 
•  The more layers of glass there are, the slower the rate of advance should be. 
•  The more uneven the thickness, the slower the temperature changes should be.

Angularity

• Glass with right angles or even more acute angles needs slower schedules than round or oval shapes.  

Degree of fuse

•  Laminated and tack fused pieces need much slower annealing and re-firing schedules.  

Contrasting colours

• Pieces with strongly contrasting colours of glass need slowing in heating and annealing.

Size

• To some extent the increased size will need some slowing of the schedule. Size becomes more important as you near the edge of the shelf or nearer to the sides of the kiln. Jewellery scale items can have an accelerated schedule.  

Mould base

• The size and shape of the mould will affect the speed and temperature of the scheduling.         
• The type and style of mould affect the schedule.  Drapes and especially over steel moulds require slower schedules. 

Position in the kiln

• The closer the glass is to the elements whether top or side, the slower the schedule must be.
• The less central on the shelf, the more care must be taken in scheduling.  

Type of kiln

• A kiln constructed for ceramics needs different scheduling considerations than one for fusing.  
• A kiln with side elements needs more careful firing than one with only top elements.

Peeking Without a Vent

What can I do if my kiln does not have a plug?

To understand thoroughly what is happening to your glass while firing, observation is key.  This means that an observation port is an ideal feature of any kiln.

However, many kilns are made without ventilation or observation ports.  This means that several possibilities need to be considered.

The easiest is simply to open the door or lid a small amount to make a brief observation.  This means that you have to set up the piece to be fired in such a place it can be seen from a small opening of the door/lid.  This brief opening of a small space will not normally cause any problem to the glass or kiln.  At the higher temperatures, you need to take personal safety precautions against the heat and light from the kiln.

It is possible to be more radical and drill an observation port through the metal casing and brick or fibre lining of the kiln.  This is then filled with a piece of fire brick or roll of fibre blanket.  This is sufficient to insulate the heat from the external part of the kiln.  This port should be about 50mm diameter to give a decent field of view.

A further refinement is to place a quartz viewing window in the hole you have drilled.  This viewing piece will become very hot, but not visibly red.  So, you must provide some insulating cover over the window.

But best of all, is to purchase a kiln with a viewing port in the first place.

Firing AFAP - Kiln Forming Myths 19

Firing as fast as possible harms your kiln, or at least will wear out the kiln elements.

I believe this comes from the days when ceramic kilns were commonly used.  Certainly this is still the mantra among ceramicists today.

A number of people fire their kilns as fast as they can, especially small ones, all the time.  Refractory fibre kilns are not affected at all by rapid changes in temperature. 

There might possibly be some small damage to the light weight refractory brick used in glass kilns in that the frequent expansion and contraction may cause crumbs to fall from the brick.  But this will happen anyway as the brick expands and contracts the same amount every time it is fired.  There is no definitive information on whether rapid increases in temperature have any greater effect on brick than slower increases. 

Any rapid change in temperature is unlikely to affect the kiln elements.  Attempting to bend the elements while cold is very likely to break them, as a compound is formed on the surface which makes them brittle when cold.  But this is very different from rapid changes in temperature.  As an analogy, the elements in electric fires are made of the same material and are always heated as fast as possible from cold.  They have a long life, so there should be no difference in effect on kiln elements, which are generally thicker and less exposed to drafts and rapid temperature changes once hot.

It could be said that firing as fast as possible would reduce the stress on the relays in the controller, as they will be closed for the whole of the temperature rise, with no opening and closing.  Thus, the number of firings will be increased without equally increasing the number of cycles the relays have to perform.

However rapid rises in temperature affect the kiln is secondary to how it affects the glass.  Except for small pieces, extremely rapid rises in temperature increase the likelihood of the glass breaking.  This is the more important consideration when thinking about afap firings.

All myths have an element of truth in them otherwise they would not persist.

They also persist because people listen to the “rules” rather than thinking about the principles and applying them.  It is when you understand the principles that you can successfully break the “rules”.

Baffles in Side-Fired Kilns

The object of using baffles in side fired kilns is to keep the direct radiant heat from the edges of the piece(s) being fired.  If the edges receive direct radiant heat, they increase in temperature more rapidly than the interior of the piece.  This means the edges become sticky and seal before upper layer of the interior begins to conform to the lower layer.  This seals air into the piece.

fusedglass.org

The materials and placing of the baffles is important.

Baffles can be made from almost anything that can withstand the heat of the firing.  There is an argument that light-weight materials such as fibre board, vermiculite board, or fibre paper should be used to reduce electricity costs.  Heavier pieces such as brick and kiln shelf pieces require more energy to heat them up.  They then of course, store heat that needs to be released on cooling, so slowing the cool down and increasing the risk of devitrification.

The placing of the baffles is important too.  Baffles protect the glass edges from radiant heat until the general heat of the kiln can come into effect over the whole of the piece.  This means that if the baffles are placed against the elements at shelf level, the element above can still give radiant heat to the edges.  Therefore, baffles placed near the glass are better.  They protect the edges from radiant heat at whatever level the side elements are placed.  This is more important for pieces that are further from the edge of the shelf, than those nearer the edge, as the centrally placed glass can “see” the radiant heat from the upper elements.