A description of bioactive glass from Mo-Sci,Llc
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| Image credit: Mo=Sci, Llc |
Wednesday, 26 March 2025
Wednesday, 19 March 2025
Bubbles on Single Layer Fusing
“I'm making 3mm French Vanilla sconce covers; …
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[initially they were] fine, but now 1.5"
bubbles form during the full fuse.
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I pop the bubbles and fill the holes with
frit and refire,
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[The]… edges draw in and distort the design…
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The shelf is flat,
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I fire on Bullseye paper, and
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the 13.5 hour long firing schedule [in F] is:
200 to 1150, hold 30 minutes.
50 to 1225, hold 30 minutes.
300 to 1490, hold 30 minutes.
9999 to 990, hold 60 minutes.
100 to 750, hold 1 minute.
Does anyone know what I can do to avoid the large bubbles?
A critique of the schedule.
This is for a single sheet of 3mm glass, so the hold at 621˚C/1150˚F is unnecessary as is the slow rise to and hold at 663˚C/1225˚F, because it is a single sheet and does not need the traditional bubble squeeze.
The hold of 30 minutes at 810˚C/1490˚F is excessive.
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The temperature may be too high.
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Ten minutes at top temperature is sufficient in
most cases.
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A soak of 1 minute would be enough.
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The anneal soak at 990˚F is most probably a
misprint for 516˚C/960˚F.
·
The anneal soak is longer than the half hour
necessary, but not a bubble creating problem.
It
means the schedule could have been:
111˚C/200˚F to 796˚C/1465˚F for 5 minutes
AFAP to 516˚C/960˚F for 30 minutes
83˚C/150F˚ to 370F˚/700F˚, 0 minutes
Off
Different firing strategies are
possible.
- Reduce the time at top temperature to no more than 10 minutes.
- Reduce top temperature by 55˚C/100˚F or more and extend the soak to 20 minutes, if necessary. Peek frequently to see when the kiln work is complete.
- Fire on fibre paper covered with Thinfire to allow air out from under the glass.
These strategies can be mixed as desired,
and the reasoning for the strategies is:
- Excessive time at the top temperature allows the glass to thin as it migrates to form thicker areas/edges. This makes the glass too thin to resist the air pressure from below.
- Reducing the top temperature will increase the viscosity, so resisting the migration of the glass, and maintain the original thickness.
- Also, single layers are prone to dog boning, but there are ways of reducing it.
Ways to reduce the risk of bubbles appearing in general are:
- Reduce the time at the top temperature,
- Reduce the top temperature,
- Provide ways for the expanding air to migrate from under the glass.
Friday, 14 March 2025
Draping over steep moulds
Draping over a narrow or small supporting ridge with large areas of glass is difficult.
One solution might be just to invert the whole piece and let the glass slide down into the mould. However, there rarely is enough height in a glass kiln for deep slumps, especially with a “V” shaped mould. It has to be high enough for the edges of the glass to be supported at its edges. You could also approach this by having a first mould with a shallower angle or broader support at its centre. Drape over this first, then use the steeper mould as the second draping mould. This makes the balance less critical.
The idea of supporting the glass is the key to doing this kind of slump that seems to require an impossible balancing act, if it is to be done in one go. Place kiln washed kiln furniture at the edges of the otherwise unsupported glass. Fire the kiln, but watch until the glass begins to slump. Then reach in with a wet stick and knock the kiln furniture aside to allow the glass to continue its slump and conform to the mould shape.
The lower temperature you use to do the draping and the slower your rate of increase is, the less the glass will be less marked by the mould. Frequent brief visual inspection during the drape is vital.
Also have a look at a suggestion for the kind of firing required for this here.
Wednesday, 12 March 2025
Dog Boning in Slumps
I have done a few experiments on rectangular moulds with 3mm and 6mm thickness. I could not eliminate dog boning with larger rims, slower rates, or lower temperatures in any combination - although they did reduce the effect.
Square single layers dog boned even with increased rim width,
and reduction of slumping depth made little difference in the amount of dog
boning.
Rectangular single layers shapes persisted in dog boning on
the long side regardless of the rim dimension, and exhibited more dog boning on
the long side than in the equivalent single layer square. Two layer slumping had a decrease in dog
boning with increased rim width, but with less effect on the long side.
In general, glass slumped in rectangular moulds is more
sensitive the shape of the rectangle than the size of the rim, and very
sensitive to symmetrical placing on the mould.
The depth of the mould has less influence than the size of the rim,
especially for single layers. The wider
the rim, the less dog boning, in general terms.
Deeper moulds, higher temperatures, longer holds, narrower
rims, all increased the dog boning. I conclude slumped square glass looks
better because the dog boning is symmetrical.
My solution is to make bigger rims and cut the piece square
after slumping. This approach needs cold work to the edges, of course.
The reason rectangular slumps dog bone is because the glass at the sides is drawn into the mould more easily than the corners, because there is more glass to draw in, just as in flat dog boning.
An alternative to the cold working is to round the corners
of the rectangles to reduce the amount to draw-in. A 1cm/0.375” radius curve will reduce the extent
of the dog boning, but does not eliminate the effect.
Wednesday, 5 March 2025
Pressing glass
I have been looking for a different way than flows or melts to mix
colours and thought glass pressing might be a promising way to achieve what I
wanted.
Weight vs Temperature
I conducted some experiments attempting to thin 1.25 kg/2.75 pounds of
glass to 3-4mm. One and then two 40x40cmx15mm
thick shelves were placed on top of the glass cullet with 3mm spacers at the
corners. The glass was fired at 220ºC/396ºF to 825ºC/1517ºF and initially held
for 30 minutes, later extended to 90 minutes.
The thickness stubbornly remained between 5 and 7mm.
A few other attempts with different times and temperatures gave
inconsistent results. Perhaps the uneven
piling of cullet had an influence on the outcomes, but I was still looking for
a flow and mixing of colours different to that obtained by melts.
Other experiments were being conducted in parallel, relating to
viscosity. These indicated that glass became thinner than 6-7mm at higher
temperatures without pressing. These
experiments lead me to think there are four elements controllable by
kilnformers in pressing: size, weight, time, temperature.
The same weight of press with the
same temperature and time will make small amounts thinner than large amounts,
and this is not surprising. More time with
the same temperature, weight, and amount allows some slight decrease in
thickness.
Higher temperatures with the same
weight, and time will allow thinner pressings of the same amount of glass. Viscosity decreases with temperature, so higher
temperatures make glass easier to thin.
More weight is required get the
same thickness when pressing a greater volume of glass. Of course, more time and temperature can be
added to increase the effect of the weight.
However, the main factor in pressing large amounts of glass
is higher temperatures, which results in reducing the viscosity and the resistance to thinning.
Annealing and Cooling
An important aspect of pressing is the annealing requirements. It is sensible to anneal for a longer time
than normal for thick glass, because of the heat retention of the pressing
weights.
This image shows the stress in an 8mm/0.3” (or 5/16”) after annealing as
for 16mm/0.63” (5/8”). There is widespread
low level stress with 30mm thick pressing weight.
Indications are that extending the annealing to at least 3 times the
target thickness is a minimum annealing soak requirement. Alternatively, if it is possible to remove
some, or all, of the weight from the glass at the beginning of the anneal soak, the annealing time can be reduced.
Veiling
The stress picture above shows there is visual element too. This veiling is most apparent in clear glass, and less obvious in coloured and opalescent glass. Small volume stacks, which are pressed thin will exhibit less of the veiling.
Four factors that kilnformers can control in pressing glass to less than
6mm are weight, size, time, and temperature.
The main one is temperature.
Wednesday, 26 February 2025
Stress Analysis of Broken Glass
Will stress still show with polarised filters on cracked and broken glass?
It's not a straightforward answer.
I was looking at some broken fused float glass a few years
ago. I had always subscribed to the idea
that a fracture relieves the stress. Not always. The broken float glass had been slumped, and the pieces still showed stress. This turned out to be a compatibility problem, although
both layers were float.
The stress of inadequately annealed glass is likely to
remain visible through the filters, because inadequately annealed glass will
have stress distributed across the whole piece.
But glass that has been cooled too quickly and suffered thermal shock,
is more likely to show minimum stress because the break relieved most of it.
It is likely stress will show on the tree piece pictured because
it has not completely broken a[art. And even when it does break, it may still
show a residue of stress.
It is sensible when trying to diagnose the problem to
perform a strip test of the glasses for compatibility of the glasses concerned to
be sure what is happening. If no stress shows on the test strip, the stress showing
on the cracked piece is unlikely to be from incompatible glass, and other factors need to be considered.
Photo credit: Debi Frock-Lyons
Sunday, 23 February 2025
Rapid Ramp Rates with Soaks
I have seen
many schedules with initial rates of advance interrupted by soaks. These kinds of schedules that are written
something like this:
250°C/450°F to 200°C/482°F, soak for 10 (or 20 or 30) minutes
250°C/450°F to 500°C/933°F, soak for 10 (or 20 or 30) minutes
300°C/540°F to 595°C/1100°F, soak for 10 (or 20 or 30) minutes
300°C/540°F to 677°C/1250°F, soak for 10 (or 20 or 30) minutes
330°C/600°F to working temperature (1450°, 1500° etc.)
When I have
asked, I’m usually told that these are catch up pauses to allow all the glass
to have an even temperature. There are
occasions when that may be a good idea, but I will come to those later. For normal fusing, draping and slumping these
soaks are not needed.
To understand
why, needs a little information on the characteristics of glass. Glass is a good insulator, and therefore a poor transmitter of heat. Glass behaves better with a moderate
steady input of heat to ensure it is distributed evenly throughout the glass. To advance the temperature quickly during the
initial heat up stages where the glass is brittle risks thermal shock.
The soaks at
intervals do not protect against a too rapid increase in temperature. It is the rate of heat input that causes
thermal shock. Rapid heat inputs cause
uneven temperatures through and across the glass. When these temperatures are more than 5°C different across the glass, stress is not relieved. As
the temperature differential increases, so does the stress until the glass is
not strong enough to contain those stresses and breaks. At higher temperatures these stresses do not
exist as the glass is less viscous.
If, as is
common and illustrated in the schedule above, you advance at the same rate on
both sides of the soak, the soak really does not serve any purpose – other than
to make writing schedules more complicated.
If the glass survived the rate of heat input between the soaks, it will
survive without the soaks.
But you may
wish to be a little more careful. The same heating effect can be achieved by
slowing the rate of advance. Just consider
the time used in the soak and then slow the rate by the appropriate
amount. Take the example above using 30-minute
soaks:
250°C/450°F to 200°C/482°F, soak for 30 minutes
250°C/450°F to 500°C/933°F, soak for 30 minutes
This part of the schedule will take three hours. You can achieve the same heat work by going
at 167°C/300°F per hour to 500°C/933°F.
This will add the heat to the glass in a steady manner and the result
will be rather like the hare and tortoise.
If you have to pause periodically because you have gone too quickly, you
can reach the same end point by steady but slower input of heat without the
pauses.
But, you may
argue, “the periodic soaks on the way up have always worked for me.” As you work with thicker than 6mm glass, this
“quick heat, soak; quick heat, soak” cycle will not continue to work. Each layer insulates the lower layer from the
heat above. As the number of layers
increase, the greater the risk of thermal shock. Enough time needs to be given
for the heat to gradually penetrate from the top to the bottom layer and across
the whole area in a steady manner.
To be safest
in the initial rate of advance, you should put heat into the glass in a
moderate, controlled fashion. This means
a steady input of heat with no quick changes in temperature. How do you calculate that rate? Contrary as it may seem, start by writing out
your cooling phases of the schedule. The
cooling rate to room temperature is the safe cooling rate for the final and now
thicker piece. If that final cool rate
is 300°C/540°F, the appropriate heat up rate is one third of that or 100°C/180°F.
This “one third speed” rate of advance will allow the heat to penetrate the layers in an even
manner during the brittle phase of the glass.
This rate needs to be maintained until the upper end of the annealing
range is passed. This is normally around
55°C/100°F above the annealing point.
Then you can
begin to write the rate of advance portion of your schedule. It could be something like:
100°C/180°F to 540°C, no soak
225°C/405°F to bubble squeeze, soak
330°C/600°F to working temperature, soak 10 minutes
Proceed to cool segments
I like
simple schedules, so I normally stick to one rate of advance all the way to the
bubble squeeze. This could be at the
softening point of the glass or start at 50°C below with a one hour rise to the
softening point with a 30-minute soak there before proceeding more quickly to
the working temperature.
Exceptions.
I did say I
would come back to an exception about soaks on the first ramp rates segment of
the schedules. When the glass is
supported – usually in a drape – with a lot of the glass unsupported you do
need to have soaks. The kind of
suspension is when draping over a cylinder or doing a handkerchief drop. This is where a small portion of the glass is
supported by a point or a long line while the rest of the glass is suspended in
the air. It also occurs when supported by
steel or thick ceramic.
The soaks
are not to equalise the temperature in the glass primarily. They are to equalise the temperature between
the supports and the glass. A thick
ceramic form supporting glass takes longer to heat up than the glass. The steel of a cocktail shaker takes the heat
away from the glass as it heats faster.
The second
element in this may already be obvious. The
glass in the air on a ceramic mould can heat faster than that on the
mould. The glass on a steel mould can
heat faster over the steel than the suspended glass. Both these cases mean that you need to be
careful with the temperature rises.
Now,
according to my arguments above, you should be able to slow the rate of advance
enough to avoid breakage. However, my experience
has shown that periodic soaks in combination with gradual increases in the
rates of advance are important, because it is more successful.
An example
of my rates of advance for 6mm glass supported on a steel cylinder is:
100°C/180°F to 100°C/212°F, soak 20 minutes
125°C/225°F to 200°C/392°F, soak 20 minutes
150°C/270°F to 400°C/753°F, soak 20 minutes
200°C/360°F to draping temperature
Call me
inconsistent, but this has proved to be more effective than dramatically
slowing the rates of advance. This exception
does not apply to slumps where the glass is supported all around by the edge of
a circular or oval mould, or where it is supported at the corners of a
rectangular or square one.
In both these cases, these are about the materials holding or contained in the glass, rather than the glass itself.
Revised 23.2.25
Cordierite/Mullite vs. pizza stones or tiles
Description of the materials
Cordierite
refractory shelves are generally combined with mullite to achieve low expansion
rates. These are most often manufactured
as solid slabs, although there is an extruded version with hollow channels
along the length, given the trade name corelite.
Cordierite is magnesium, iron and aluminium in a
cyclosilicate form (or rings of tetrahedra). It is named after its
discoverer, Louis Cordier,
who identified it in 1813.
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| cordierite/mullite shelves |
Mullite is combined with cordierite in small amounts to
increase strength and reduce the amount of expansion. It does this through the
formation of needle shapes that interlock and resist thermal shock. It also
provides mechanical strength.
Mullite was first described in 1924 and named for an
occurrence on the Isle of Mull, Scotland, although it occurs elsewhere, usually in conjunction with volcanic
deposits.
Pizza Stones and Tiles
Pizza stones are a variant of
baking stones where the food is placed on (sometimes heated) stones. Baking stones are a variation on hot
stone cooking, one of the oldest cooking techniques. The stones are normally unglazed tiles of varying thicknesses. What is said of pizza stones also applies to
tiles.
Characteristics
Pizza stones
Ceramic tiles and pizza stones are essentially the same
things. Some tiles may be thinner,
especially if they are not large. In both cases, the ceramic is a poor heat
conductor and the thermal mass means care needs to be taken in rapid heating and
cooling of tiles and of baking stones. These are dry pressed which give a coarser surface texture than
cast shelves. All these ceramics are generally fired at about 1100C, so they can
withstand kiln forming temperatures.
They are adequate as small shelves, but will deform over larger areas
over time.
Cordierite-Mullite kiln shelves and furniture.
This formulation of materials has an extremely low coefficient of thermal expansion that explains the outstanding thermal shock resistance of these kiln furniture materials. They are also strong although heavy. Cordierite/mullite shelves are sintered, to allow the mullite needles to form, and fired at 1400C+, higher than tiles.
This material can be cast,
dry pressed or extruded. Cast shelves are the cheapest
of the methods and provides a smooth surface.
These are used for kilnforming glass, and low temperature ceramic
firing.
Dry pressed shelves have a
higher temperature resistance than cast. For this reason, these are often
marketed as ceramic shelves, even though the cast shelves are fine for smaller
areas. These are more expensive than the
cast shelves.
Corelite, a brand name for
extruded shelves with hollow channels, is often used where larger shelves are
required, as the weight is less than the solid cordierite. Extruded
shelves are ground smooth after forming.
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| pizza stones |
Preparation
Pizza Stones and Tiles
Due to the thermal mass of pizza stones and the material's property as a poor
heat conductor, care must be taken when firing.
Firing quickly can break the stone or tile. The stone or tile should be fired slowly to
just under the boiling point and soaked for a couple of hours to eliminate any
dampness in the material. This probably
should be done each time kiln wash is applied.
Because it is porous, a baking stone or tile will absorb any liquid applied,
including detergent. They should be cleaned with a dry brush and then plain
water if further cleaning is necessary.
Pizza stones and tiles should be checked for having straight
and level surfaces. It is not a priority for these to have flat surfaces as for
glass and ceramics shelves. If by
placing a straight edge on the surface you can see slivers of light, the shelf
needs to be smoothed. You can do this by
grinding two of the proposed shelves together with a bit of coarse grit between. This best done wet to avoid the dust getting
into the air.
Cordierite
Cordierite/mullite shelves do not need this level of
preparation, unless they have been stored outside. It is possible to kiln wash and air dry for a
few hours before placing glass on the shelf and firing. This difference is the low rate of expansion
(CoLE 19, if you are interested).
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| corelite shelves |
Corelite
The extruded corelite shelves are made with
cordierite/mullite, but are more delicate due to the hollow channels along
their length. They should be fired
slowly to just under the boiling point of water - to eliminate the moisture - then continue the slow rise to at least 260C/500F to avoid the crystobalite inversion. It should be fired to 540C with a pause
before going to the top temperature. The
shelf should be supported at 30cm intervals under the shelf to minimise
breakage. The whole surface of the shelf
should be filled rather than having just one heavy piece; again this is to
minimise breakage.
Revised 23.2.25
Flat Kiln Shelves
A question has
been asked about using tiles in addition to standard kiln shelves to fire glass
upon. Yes, you can use the unglazed
backs to fire on, assuming they are not ridged or in other ways not a regular
surface.
It is
important to have flat shelves, as ones with even small shallow depressions can
promote bubbles at higher temperatures. Tiles for walls and floors do not need
to be flat to do their intended job and so are not checked for be flatness.
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| A magnified view of a shelf surface that is not perfectly even |
You can do a
quick check for flatness, by placing a ruler on edge across the tile or shelf
to see if any light comes through underneath the ruler. The light areas are the places where the
surface is lower than the rest. A more certain way to determine flatness is to sprinkle a black powder on the shelf. Then draw a straight edge across the shelf to reveal any black areas. These are the places that the kiln has a depression.
If the depressions are few and small you can make corrections in the surface of the tile by
grinding. Put two tiles back to back and grind them
together. The initial grind will show you the high spots as they will have the
grinding marks there.
You can eliminate
these higher areas by rubbing the tiles together with a coarse grit (ca. 80) between the tiles to speed the
grinding. If you are concerned about the dust or don’t have good ventilation,
you can make a slurry of the grit by adding water. When the whole surface has
the same marks, both will be flat. To double check, sprinkle black powder on the shelf and repeat the test for flatness with a straight edge. If it is not fully flat, repeat the grinding process and checking until the tile or shelf is flat.
This sounds
time consuming and lots of effort, but you will be surprised at how quickly you
can achieve flat smooth surfaces even on larger tiles. This also works for larger kiln shelves.
Revised 23.2.25
Friday, 21 February 2025
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.
However the frequent use of organic materials - binders, plants, organic glues, etc - can degrade the protective oxide coating. After prolonged use, it is advisable to clean the kiln of all dusts and fire empty to rebuild the oxide layer.
Revised 19.2.25
Wednesday, 19 February 2025
Time and Temperature
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| credit: timeanddate.com |
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| Credit: Shutterstock |
“What are the pros and cons on turning up the max temperature slightly Vs. a longer hold time”? Lea Madsen
This is a difficult question
to answer, because there are variables such as
the temperature range,
the ramp rates, and soaks,
the forces acting upon the glass at a given temperature,
the process,
the desired outcome of the firing,
etc.
When talking about temperature vs. time, it is heat work
that we are considering. In many processes
time and temperature are interchangeable, although the temperature range is
important too. This is a brief
discussion of heat work in various processes.
Slumps
Slumping
temperature is generally in the range of 620˚C-680˚C/1150˚F -1255˚F *, which is
below the devitrification range. This
allows the exchange of time for temperature without risk, allowing more time
rather than more temperature. Higher temperatures cause more marking from
the mould since the bottom of the glass is softer than at lower ones. Lower temperatures give higher viscosity, so
the glass is stiffer, resisting marks.
Low temperature fuses
Sharp tack fusing, freeze and fuse, some pate de verre
processes, and sintering occur in the 650˚C
-720˚C /1150˚F - 1320˚F range, risking devitrification only at the upper end of this
range. Extending the time rather than
the temperature is important to maintain detail in these processes. Higher temperatures will smooth the surface, risking
loss of detail.
Rounded tack processes (720˚C – 760˚C /1320˚F - 1400˚F)
These are within the devitrification range making the
choice between time and temperature a balance of risks. In my experience, it takes about an hour for
visible devitrification to develop. This
means that you can extend the time, if the total time between the end of the bubble
squeeze and the working temperature, including the hold time, is less than an
hour. It has the advantage of a more
secure attachment between the pieces of glass, without altering the surface
much.
But if extending the soak time increases the time in the
devitrification zone to be more than an hour, it is advisable to increase the
temperature, rather than time. Devitrification
develops in the presence of air, so reducing the time in that range reduces the
risk of devitrification developing. The
glass is moving during rapid ramp rates, reducing the chance of devitrification.
Drops
This includes drapes, and other free forming processes. Kilnformers will be observing the progress of
these firings, making it easier to balance temperature and time. There are already long holds scheduled for
the processes, so it is a matter of getting the right temperature. If, after half an hour at the scheduled top
temperature, the glass has not moved much, it is time to increase the
temperature by, say 10˚C/18˚F and observe after another half hour, repeating the temperature increase if
necessary. Be aware of thinning the
glass at the shoulder by setting a high temperature. Free drops may take as much as 6 – 8 hours,
so patience and observation are important to get good results.
Full fuse
At full fuse try to
get the work done in 10 minutes to avoid complications with
devitrification. So, increasing the
temperature rather than the length of the soak seems best.
Flows
Whether frit stretching, making pattern bars, pressing, etc.,
low viscosity is important. Viscosity is
closely related to temperature, so increasing the temperature is the better
choice. Increasing time without
increasing temperature does not change viscosity much.
Casting
Extending time at top temperature seems
best for open face casting, as the temperature is already high. A slow ramp rate to that top temperature may make
adding time unnecessary, because the heat work will be increased by the slow
rise. Experience has shown that a rate
of 200˚C/360˚F is enough to avoid devitrification. With enclosed castings devitrification is not
such a risk, so time can be added without concern.
Observation
In all these processes it is advisable to observe
the progress of the firing by quick peeks to determine the effective
combination of temperature and time.
Also note that heat work is
cumulative, making for changes in profile with repeated
firings.
* The softening point of float glass is around 720°C/1328°F, so
the slumping range is about 700°C/1292° to
750°C/1382°F.
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